Click to open or close... Double-click to open or close all.

Hadron Storage Ring Requirements

General, functional and performance requirements associated with the Hadron Storage Ring of the Electron Ion Collider.

Name
WBS
Description
Updated
Status
TBD
HSR : Hadron Storage Ring Performance Requirements

G-HSR.01
6.05
The range of unpolarized ion species currently produced by the Relativistic Heavy Ion Collider (RHIC) complex shall be preserved for Electron Ion Collider (EIC) Hadron Storage Ring (HSR) operation (from deuterons to uranium) defined in the Master Parameter Table (MPT). [Document#:EIC-SEG-RSI-005]
02/13/2025
Approved
FALSE

G-HSR.02
6.05
The HSR shall deliver Protons bunches having at least a 70% polarization at full beam energy ready for collision.
02/13/2025
Approved
FALSE

G-HSR.03
6.05
The HSR shall deliver 3He bunches having at least a 70% polarization at full beam energy ready for collision.
02/13/2025
Approved
FALSE

G-HSR.04
6.05
Design of the Hadron storage ring shall allow the possibility of future operation with a polarized deuteron beam.
01/27/2025
Approved
FALSE

G-HSR.05
6.05
The HSR shall provide the capability to collide protons at beam energies of 41 GeV, and from 100 to 275 GeV.
01/27/2025
Approved
FALSE

G-HSR.06
6.05
The HSR shall provide the capability to collide 3He at beam energies of 41 GeV/nucleon, and from 100 to 183 GeV/nucleon.
02/13/2025
Approved
FALSE

G-HSR.07
6.05
The HSR shall provide the capability to collide electrons with Au ions at 41 GeV/nucleon and from 100 to 110 GeV/nucleon energies.
02/13/2025
Approved
FALSE

G-HSR.08
6.05
The HSR shall provide the capability to collide other ion species at a maximum energy equivalent to a beam rigidity Bρ value of 916.67 Tm.
02/13/2025
Approved
FALSE

G-HSR.09
6.05
The HSR shall provide the capability to vary the hadron revolution frequency to match it at different hadron energies (41 GeV/nucleon and 100 - 275 GeV/nucleon) with the revolution frequency of electron beam in the ESR.
02/13/2025
Approved
FALSE

G-HSR.10
6.05
The HSR Ion bunches shall meet the parameters specified for different species defined in MPT. [Document#:EIC-SEG-RSI-005]
02/13/2025
Approved
FALSE

G-HSR.11
6.05
The HSR shall be able to provide beams of required species for collision having the beam currents as specified in the MPT. [Document#:EIC-SEG-RSI-005]
01/27/2025
Approved
FALSE

F-HSR-INJ.10
6.05.03
The HSR Injection system transport line shall be modified to add septum magnets in the Q3-Q4 warm straight section of the HSR on 4 o’clock side of the IR4 for hadron beam transfer into the HSR beam pipe.
04/03/2025
Approved
FALSE

G-HSR.12
6.05
The HSR shall utilize a vacuum system capable of operating with peak and average beam current defined in MPT. [Document#:EIC-SEG-RSI-005]
01/27/2025
Approved
FALSE

G-HSR.13
6.05
The Relativistic Heavy Ion Collider (RHIC) lattice shall be preserved and where required modified for Electron Ion Collider (EIC) Hadron Storage Ring (HSR) operations defined in the Master Parameter Table (MPT). [Document#:EIC-SEG-RSI-005]
02/13/2025
In Process
FALSE

G-HSR.14
6.05
The HSR shall have a instrumentation system to operate for all beam species which need monitoring and will, where possible utilize the existing RHIC instrumentation system.
01/27/2025
Approved
FALSE

G-HSR.15
6.05
All HSR components and systems shall be designed and installed in line with all relevant regulatory codes and in full compliance with BNL SBMS.
01/27/2025
Approved
FALSE

G-HSR.16
6.05
The HSR uptime shall be consistent with the overall uptime requirements of the EIC.
01/27/2025
Approved
FALSE

F-HSR-INJ.09
6.05.03
The operational availability design target for the HSR Injection System shall be consistent with the operational availability target for the overall EIC as set forth in Electron-Ion Collider Global Requirements, [Document: EIC-ORG-PLN-010]
04/04/2025
Approved
FALSE

G-HSR.17
6.05
The HSR shall meet the beam parameters specified for different species at injection defined in MPT. [Document#:EIC-SEG-RSI-005]
02/13/2025
Approved
FALSE

F-HSR-INJ.01
6.05.03
The HSR injection system shall utilize the existing RHIC injector chain upstream of the RHIC-ATR D26 Dipole magnet with no modifications.
04/03/2025
In Process
FALSE

F-HSR-INJ.02
6.05.03
The HSR injection system, consisting of the transport beamline, septum magnet and injection kickers, shall be capable of transporting a maximum beam rigidity of 81.12Tm from the transport line to IR4 central area and injecting it into the HSR.
04/03/2025
Approved
FALSE

F-HSR-INJ.03
6.05.03
The HSR Injection System design shall use a warm transport line in arc 6-4 as continuation of the Injection line to transport the hadron beam to the injection system located in IR4.
01/27/2025
Approved
FALSE

F-HSR-INJ.04
6.05.03
The HSR injection transport beamline shall be able to transport polarized beam with less than 5% polarization loss.
04/03/2025
Approved
FALSE

F-HSR-INJ.05
6.05.03
The HSR injection system shall be able to inject all beam species with less than 5% beam emittance increase.
01/27/2025
Approved
FALSE

F-HSR-INJ.06
6.05.03
The HSR injection system shall be able to fill the HSR with 290 consecutive bunches without interruption.
01/27/2025
Approved
FALSE

F-HSR-INJ.07
6.05.03
The HSR injection system shall be able to fill the HSR with one(1) bunch per AGS cycle for polarized proton, two(2) bunches per AGS cycle for ion beams.
01/27/2025
Approved
FALSE

F-HSR-INJ.09
6.05.03
The operational availability design target for the HSR Injection System shall be consistent with the operational availability target for the overall EIC as set forth in Electron-Ion Collider Global Requirements, [Document: EIC-ORG-PLN-010]
04/04/2025
Approved
FALSE

F-HSR-INJ.08
6.05.03
The HSR injection system transfer line shall provide the following physical aperture:
04/03/2025
Approved
FALSE

F-HSR-INJ.10
6.05.03
The HSR Injection system transport line shall be modified to add septum magnets in the Q3-Q4 warm straight section of the HSR on 4 o’clock side of the IR4 for hadron beam transfer into the HSR beam pipe.
04/03/2025
Approved
FALSE

G-HSR.18
6.05
The HSR shall utilize an Injection system to provide the ability for single bunch transport and Injection at IR4.
01/27/2025
Approved
FALSE

F-HSR-INJ-MAG.01
6.05.03.01
Any reused existing RHIC-ATR transfer line magnets shall meet the requirements of the new approved HSR Injection line lattice.
04/03/2025
Approved
FALSE

F-HSR-INJ-MAG.02
6.05.03.01
New magnets shall only be used where any available existing magnets do not meet the requirements of the new approved HSR Injection line lattice.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.01
6.05.03.04
The HSR injection kickers shall provide a half aperture greater than 10σ for the stored beam at Collison energies.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.02
6.05.03.04
The HSR injection kickers shall provide a half aperture greater than 7σ for the stored beam at injection energies.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.03
6.05.03.04
The HSR injection kickers shall provide a half aperture greater than 6σ for the injected beam.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.04
6.05.03.04
The HSR injection kicker system shall be able to deflect the injected beam to be on axis
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.05
6.05.03.04
The HSR injection kicker system shall be installed in the straight section of the IR4 area.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.06
6.05.03.04
The HSR injection kicker system shall be capable of single-bunch on-axis injection to fill the ring with 290 bunches.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.07
6.05.03.04
The HSR injection kicker system rise time shall be short enough so that it does not step on the previous bunch.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.08
6.05.03.04
The present RHIC injection kicker system including the Lambertson magnet and current injection kicker magnets at the 5 o’clock area shall be removed.
04/03/2025
Approved
FALSE

F-HSR-INJ-PS.01
6.05.03.02
The HSR Injection System magnets shall be fed by a system of power supplies matched in voltage and maximum current to the specifications and requirements of the respective magnets
04/03/2025
Approved
FALSE

F-HSR-INJ-VAC.01
6.05.03.03
The vacuum level in the HSR transport line shall be kept at the same level as in the current RHIC-ATR line.
04/03/2025
Approved
FALSE

F-HSR-INJ-VAC.02
6.05.05.02
A ~20m section of the warm injection beamline near the HSR including the injection septum shall have a vacuum pressure of ~1E-10 torr or better, after baking .
04/03/2025
In Process
FALSE

F-HSR-INJ.01
6.05.03
The HSR injection system shall utilize the existing RHIC injector chain upstream of the RHIC-ATR D26 Dipole magnet with no modifications.
04/03/2025
In Process
FALSE

F-HSR-INJ.02
6.05.03
The HSR injection system, consisting of the transport beamline, septum magnet and injection kickers, shall be capable of transporting a maximum beam rigidity of 81.12Tm from the transport line to IR4 central area and injecting it into the HSR.
04/03/2025
Approved
FALSE

F-HSR-INJ.03
6.05.03
The HSR Injection System design shall use a warm transport line in arc 6-4 as continuation of the Injection line to transport the hadron beam to the injection system located in IR4.
01/27/2025
Approved
FALSE

F-HSR-INJ.04
6.05.03
The HSR injection transport beamline shall be able to transport polarized beam with less than 5% polarization loss.
04/03/2025
Approved
FALSE

F-HSR-INJ.05
6.05.03
The HSR injection system shall be able to inject all beam species with less than 5% beam emittance increase.
01/27/2025
Approved
FALSE

F-HSR-INJ.06
6.05.03
The HSR injection system shall be able to fill the HSR with 290 consecutive bunches without interruption.
01/27/2025
Approved
FALSE

F-HSR-INJ.07
6.05.03
The HSR injection system shall be able to fill the HSR with one(1) bunch per AGS cycle for polarized proton, two(2) bunches per AGS cycle for ion beams.
01/27/2025
Approved
FALSE

F-HSR-INJ.09
6.05.03
The operational availability design target for the HSR Injection System shall be consistent with the operational availability target for the overall EIC as set forth in Electron-Ion Collider Global Requirements, [Document: EIC-ORG-PLN-010]
04/04/2025
Approved
FALSE

F-HSR-INJ.08
6.05.03
The HSR injection system transfer line shall provide the following physical aperture:
04/03/2025
Approved
FALSE

F-HSR-INJ.10
6.05.03
The HSR Injection system transport line shall be modified to add septum magnets in the Q3-Q4 warm straight section of the HSR on 4 o’clock side of the IR4 for hadron beam transfer into the HSR beam pipe.
04/03/2025
Approved
FALSE

G-HSR.19
6.08
The HSR shall utilize an RF system capable of operating in parameters defined in MPT. [Document#:EIC-SEG-RSI-005]
01/27/2025
In Process
FALSE

G-HSR.20
6.07.02
The HSR shall have a control system which can operate the HSR consistent will the overall control of the other EIC system's and to ensure the HSR meets all the Physics requirements needed to deliver the physics goals of the EIC.
01/27/2025
Approved
FALSE

G-HSR.21
6.09
The HSR shall have a cryogenic system to cool and operate all elements which need cryogenic cooling and will, where possible utilize the existing RHIC cooling system.
01/27/2025
Approved
FALSE

G-HSR.22
The vacuum system shall be capable of operating with peak and average beam current as per the MPT. [Document#:EIC-SEG-RSI-005]
04/02/2025
In Process
FALSE

F-HSR.01
The HSR proton beam shall be ramped from injection energy to a maximum collision energy of 275 GeV.
04/02/2025
Approved
FALSE

F-HSR.02
The HSR shall be designed for changing beam optics between the injection configuration to collision configuration with beam in the machine.
04/02/2025
Approved
FALSE

F-HSR.03
The HSR beam at collision energies shall be synchronized to the revolution frequency of the electron beam.
04/02/2025
Approved
FALSE

F-HSR.04
The HSR systems shall provide the capability to operate with a radial shift, having a full range of +/-21 (mm) beam orbit in all arcs.
04/02/2025
Approved
FALSE

F-HSR.05
The HSR systems shall operate with a vertical orbit excursion having a full range of +/-2 (mm) beam orbit in all arcs.
04/02/2025
Approved
FALSE

F-HSR.06
The HSR decoupling system shall provide the capability to maintain a flat beam with the required beam size ratios.
04/02/2025
Approved
FALSE

F-HSR.07
The HSR orbit tune chromaticity correction, nonlinear correction and gamma-T jump systems, shall be provided with the same capability as in the present RHIC machine.
04/02/2025
Approved
FALSE

F-HSR.08
The HSR shall provide a dynamic aperture greater than 6σ under colliding beam conditions.
04/02/2025
Approved
FALSE

F-HSR.09
The physical aperture for the circulating hadron beam at the store energies shall be greater than 10σ in the horizontal and vertical planes.
04/02/2025
Approved
FALSE

F-HSR.10
The physical aperture for the circulating hadron beam at the injection energy shall be greater than 8σ in the horizontal and vertical planes in all locations except the beam dump beam pipe.
04/02/2025
Approved
FALSE

F-HSR.11
The physical aperture for the circulating hadron beam at the injection energy in the beam dump beam pipe shall be greater than 6σ in the horizontal and vertical planes.
04/02/2025
Approved
FALSE

F-HSR.12
The apertures of the downstream, near-IR magnets, within the IR hadron lattice, shall be large enough to transport a 4 mrad cone of neutral particles from the IP without obstruction.
04/02/2025
Approved
FALSE

F-HSR.13
The apertures of the forward side near-IR magnets, within the IR hadron lattice, shall be large enough to transport particles having a transverse momentum of up to 1.3 GeV/c with a 275GeV proton beam without obstruction.
04/02/2025
Approved
FALSE

F-HSR.14
The apertures of the forward side, near-IR magnets, within the IR hadron lattice, shall accommodate off beam-axis detectors which can detect forward scattered protons with a transverse momentum of 0.2GeV to 1.3GeV at a proton beam energy of 275GeV.
04/02/2025
Approved
FALSE

F-HSR.15
The vacuum chamber shall provide sufficient horizontal and vertical aperture to accommodate; a +/-10 sigma beam, where the vertical RMS beam size is based on the emittance of a fully coupled beam, In the arcs an additional 20 mm horizontally and 2 mm vertically shall be included to account for the radially shifted beam and orbit errors.
04/02/2025
Approved
FALSE

F-HSR.16
The HSR alignment requirements are established by dynamic aperture and polarization tracking. The HSR RMS alignment tolerances shall be such that all the beam parameters listed in the MPT [EIC Document: EIC-SEG-RSI-005] can be satisfied.
04/02/2025
Approved
FALSE

F-HSR.17
The operational availability design target for the HSR shall be consistent with the operational availability target for the overall EIC as set forth in Electron-Ion Collider Global Requirements. [Document: EIC-ORG-PLN-010]
04/02/2025
Approved
FALSE

F-HSR.18
The HSR shall deliver spin polarized ion beams with store-averaged polarization of at least 70 percent at collision.
04/02/2025
Approved
FALSE

F-HSR.19
The HSR lattice shall have features to preserve the polarization from injection to collision energies.
04/02/2025
Approved
FALSE

F-HSR.20
The HSR lattice will utlise RHIC snakes and spin rotators to control the hadron spin.
04/02/2025
Approved
FALSE

F-HSR.21
The HSR shall be capable of delivering bunches with longitudinal spins to the IP.
04/04/2025
Approved
FALSE

F-HSR.22
The HSR Lattice shall contain provisions for correctors such as horizontal and vertical dipole correctors, skew quadrupoles, octupoles, etc. as needed.
04/04/2025
Approved
FALSE

HSR-MAG : HSR Magnet (WBS 6.05.02.01)

HSR-MAG-AR_CQS(Quad) : HSR Quadrupole (AR_CQS(Corr-HV)) Magnet (WBS 6.05.02.01)

P-HSR-MAG-AR_CQS(Quad).01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_CQS(Quad) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-AR_CQS(Quad).03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Quad).10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_CQS(Sxt) : HSR Sextupole (AG-AR_CQS(Quad)) Magnet (WBS 6.05.02.01)

P-HSR-MAG-AR_CQS(Sxt).01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_CQS(Sxt) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-AR_CQS(Sxt).03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Sxt).10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_D6 : HSR Dipole (AR_D6) Magnet (WBS 6.05.02.01)

P-HSR-MAG-AR_D6.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_D6 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-AR_D6.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D6.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_D8 : HSR Dipole (AR_D8) Magnet (WBS 6.05.02.01)

P-HSR-MAG-AR_D8.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_D8 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-AR_D8.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D8.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_D9 : HSR Dipole (AR_D9) Magnet (WBS 6.05.02.01)

P-HSR-MAG-AR_D9.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_D9 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-AR_D9.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_D9.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-BXDS01A : HSR Dipole (BXDS01A) Magnet (WBS 6.05.02.01)

P-HSR-MAG-BXDS01A.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-BXDS01A EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-BXDS01A.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-BXDS01A.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-D5I : HSR Magnet D5I (WBS 6.05.02.01)

P-HSR-MAG-D5I.01.01
6.05.02.01
The Dipole shall be a 'D5I' RHIC Magnet in a 'D5I' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.01.06
6.05.02.01
The physical magnet length shall be less than or equal to 6.92 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.02.01
6.05.02.01
The magnet dipole field (B) shall be 3.45 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/s.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rref=TBD(mm) \ TBD (A).
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.02
6.05.02.01
b2=tbd, a2=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.03
6.05.02.01
b3=tbd, a3=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.04
6.05.02.01
b4=tbd, a4=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.05
6.05.02.01
b5=tbd, a5=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.06
6.05.02.01
b6=tbd, a6=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.07
6.05.02.01
b7=tbd, a7=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.08
6.05.02.01
b8=tbd, a8=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.09
6.05.02.01
b9=tbd, a9=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.03.03.10
6.05.02.01
b10=tbd, a10=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

HSR-MAG-D5I EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-D5I.03
6.05.02.01
The magnet is a Dipole(D5I) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.04
6.05.02.01
The magnet is a Dipole(D5I) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.05
6.05.02.01
The magnet is a Dipole(D5I) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-D5I.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5I.10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-D5O : HSR Magnet D5O (WBS 6.05.02.01)

P-HSR-MAG-D5O.01.01
6.05.02.01
The Dipole shall be a 'D5O' RHIC Magnet in a 'D5O' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.01.06
6.05.02.01
The physical magnet length shall be less than or equal to 8.71 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.02.01
6.05.02.01
The magnet dipole field (B) shall be 3.45 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/s.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Ref#1: Rr=80(mm), Ir=660(A) Ref#2: Rr=80(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.01
6.05.02.01
Ref#1: b1=10000,a1=0 Ref#2: b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.02
6.05.02.01
Ref#1: -0.2<b2<0.36, -1.25<a2<1.81 Ref#2: -0.18<b2<0.38, -3.02<a2<0
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.03
6.05.02.01
Ref#1: -2.39<b3<2.05, -1.2<a3<-0.86 Ref#2: -0.93<b3<2.59, -1.25<a3<-0.89
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.04
6.05.02.01
Ref#1: -0.08<b4<0.08, -0.45<a4<0.39 Ref#2: -0.07<b4<0.09, -0.77<a4<0.05
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.05
6.05.02.01
Ref#1: -0.9<b5<0.24, 0.15<a5<0.27 Ref#2: -0.44<b5<0.74, 0.14<a5<0.26
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.06
6.05.02.01
Ref#1: -0.03<b6<0.03, -0.13<a6<0.17 Ref#2: -0.07<b6<0.01, -0.22<a6<0.1
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.07
6.05.02.01
Ref#1: -0.26<b7<0, -0.12<a7<-0.08 Ref#2: 1.05<b7<1.33, -0.12<a7<-0.08
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.08
6.05.02.01
Ref#1: -0.02<b8<0, -0.06<a8<0.04 Ref#2: -0.02<b8<0, -0.06<a8<0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.09
6.05.02.01
Ref#1: 0.02<b9<0.26, 0.01<a9<0.03 Ref#2: 0<b9<0.24, 0.01<a9<0.03
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.03.03.10
6.05.02.01
Ref#1: 0<b10<0.04, 0.02<a10<0.06 Ref#2: 0<b10<0.04, 0.02<a10<0.06
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

HSR-MAG-D5O EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-D5O.03
6.05.02.01
The magnet is a Dipole(D5O) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.04
6.05.02.01
The magnet is a Dipole(D5O) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.05
6.05.02.01
The magnet is a Dipole(D5O) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-D5O.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-D5O.10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-D5O_D5I : HSR Dipole (D5O_D5I) Magnet (WBS 6.05.02.01)

P-HSR-MAG-D5O_D5I.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-D5O_D5I EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-D5O_D5I.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D5O_D5I.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-D6 : HSR Magnet D6 (WBS 6.05.02.01)

P-HSR-MAG-D6.01.01
6.05.02.01
The Dipole shall be a 'D96' RHIC Magnet in a 'D6' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.01.06
6.05.02.01
The physical magnet length shall be less than or equal to 2.95 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.02.01
6.05.02.01
The magnet dipole field (B) shall be 3.45 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/s.
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Ref#1: Rr=80(mm), Ir=660(A) Ref#2: Rr=80(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.01
6.05.02.01
Ref#1: b1=10000,a1=0 Ref#2: b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.02
6.05.02.01
Ref#1: -0.2<b2<0.36, -1.25<a2<1.81 Ref#2: -0.18<b2<0.38, -3.02<a2<0
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.03
6.05.02.01
Ref#1: -2.39<b3<2.05, -1.2<a3<-0.86 Ref#2: -0.93<b3<2.59, -1.25<a3<-0.89
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.04
6.05.02.01
Ref#1: -0.08<b4<0.08, -0.45<a4<0.39 Ref#2: -0.07<b4<0.09, -0.77<a4<0.05
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.05
6.05.02.01
Ref#1: -0.9<b5<0.24, 0.15<a5<0.27 Ref#2: -0.44<b5<0.74, 0.14<a5<0.26
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.06
6.05.02.01
Ref#1: -0.03<b6<0.03, -0.13<a6<0.17 Ref#2: -0.07<b6<0.01, -0.22<a6<0.1
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.07
6.05.02.01
Ref#1: -0.26<b7<0, -0.12<a7<-0.08 Ref#2: 1.05<b7<1.33, -0.12<a7<-0.08
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.08
6.05.02.01
Ref#1: -0.02<b8<0, -0.06<a8<0.04 Ref#2: -0.02<b8<0, -0.06<a8<0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.09
6.05.02.01
Ref#1: 0.02<b9<0.26, 0.01<a9<0.03 Ref#2: 0<b9<0.24, 0.01<a9<0.03
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.03.03.10
6.05.02.01
Ref#1: 0<b10<0.04, 0.02<a10<0.06 Ref#2: 0<b10<0.04, 0.02<a10<0.06
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

HSR-MAG-D6 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-D6.03
6.05.02.01
The magnet is a Dipole(D6) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.04
6.05.02.01
The magnet is a Dipole(D6) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.05
6.05.02.01
The magnet is a Dipole(D6) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-D6.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-D6.10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-D8 : HSR Magnet D8 (WBS 6.05.02.01)

P-HSR-MAG-D8.01.01
6.05.02.01
The Dipole shall be a 'DR8' RHIC Magnet in a 'D8' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.01.06
6.05.02.01
The physical magnet length shall be less than or equal to 9.45 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.02.01
6.05.02.01
The magnet dipole field (B) shall be 0.401 (T) 3.458 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/s.
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Ref#1: Rr=80(mm), Ir=660(A) Ref#2: Rr=80(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.01
6.05.02.01
Ref#1: b1=10000,a1=0 Ref#2: b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.02
6.05.02.01
Ref#1: -0.2<b2<0.36, -1.25<a2<1.81 Ref#2: -0.18<b2<0.38, -3.02<a2<0
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.03
6.05.02.01
Ref#1: -2.39<b3<2.05, -1.2<a3<-0.86 Ref#2: -0.93<b3<2.59, -1.25<a3<-0.89
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.04
6.05.02.01
Ref#1: -0.08<b4<0.08, -0.45<a4<0.39 Ref#2: -0.07<b4<0.09, -0.77<a4<0.05
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.05
6.05.02.01
Ref#1: -0.9<b5<0.24, 0.15<a5<0.27 Ref#2: -0.44<b5<0.74, 0.14<a5<0.26
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.06
6.05.02.01
Ref#1: -0.03<b6<0.03, -0.13<a6<0.17 Ref#2: -0.07<b6<0.01, -0.22<a6<0.1
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.07
6.05.02.01
Ref#1: -0.26<b7<0, -0.12<a7<-0.08 Ref#2: 1.05<b7<1.33, -0.12<a7<-0.08
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.08
6.05.02.01
Ref#1: -0.02<b8<0, -0.06<a8<0.04 Ref#2: -0.02<b8<0, -0.06<a8<0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.09
6.05.02.01
Ref#1: 0.02<b9<0.26, 0.01<a9<0.03 Ref#2: 0<b9<0.24, 0.01<a9<0.03
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.03.03.10
6.05.02.01
Ref#1: 0<b10<0.04, 0.02<a10<0.06 Ref#2: 0<b10<0.04, 0.02<a10<0.06
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

HSR-MAG-D8 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-D8.03
6.05.02.01
The magnet is a Dipole(D8) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.04
6.05.02.01
The magnet is a Dipole(D8) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.05
6.05.02.01
The magnet is a Dipole(D8) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-D8.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-D8.10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-D9 : HSR Magnet D9 (WBS 6.05.02.01)

P-HSR-MAG-D9.01.01
6.05.02.01
The Dipole shall be a 'D96' RHIC Magnet in a 'D9' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.01.06
6.05.02.01
The physical magnet length shall be less than or equal to 2.95 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.02.01
6.05.02.01
The magnet dipole field (B) shall be 3.45 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/s.
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Ref#1: Rr=80(mm), Ir=660(A) Ref#2: Rr=80(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.01
6.05.02.01
Ref#1: b1=10000,a1=0 Ref#2: b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.02
6.05.02.01
Ref#1: -0.2<b2<0.36, -1.25<a2<1.81 Ref#2: -0.18<b2<0.38, -3.02<a2<0
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.03
6.05.02.01
Ref#1: -2.39<b3<2.05, -1.2<a3<-0.86 Ref#2: -0.93<b3<2.59, -1.25<a3<-0.89
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.04
6.05.02.01
Ref#1: -0.08<b4<0.08, -0.45<a4<0.39 Ref#2: -0.07<b4<0.09, -0.77<a4<0.05
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.05
6.05.02.01
Ref#1: -0.9<b5<0.24, 0.15<a5<0.27 Ref#2: -0.44<b5<0.74, 0.14<a5<0.26
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.06
6.05.02.01
Ref#1: -0.03<b6<0.03, -0.13<a6<0.17 Ref#2: -0.07<b6<0.01, -0.22<a6<0.1
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.07
6.05.02.01
Ref#1: -0.26<b7<0, -0.12<a7<-0.08 Ref#2: 1.05<b7<1.33, -0.12<a7<-0.08
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.08
6.05.02.01
Ref#1: -0.02<b8<0, -0.06<a8<0.04 Ref#2: -0.02<b8<0, -0.06<a8<0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.09
6.05.02.01
Ref#1: 0.02<b9<0.26, 0.01<a9<0.03 Ref#2: 0<b9<0.24, 0.01<a9<0.03
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.03.03.10
6.05.02.01
Ref#1: 0<b10<0.04, 0.02<a10<0.06 Ref#2: 0<b10<0.04, 0.02<a10<0.06
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

HSR-MAG-D9 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-D9.03
6.05.02.01
The magnet is a Dipole(D9) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.04
6.05.02.01
The magnet is a Dipole(D9) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.05
6.05.02.01
The magnet is a Dipole(D9) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-D9.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-D9.10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-IR_Q5 : HSR IR Magnet Q5 (WBS 6.05.02.01)

P-HSR-MAG-IR_Q5.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-IR_Q5 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-IR_Q5.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q5.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-IR_Q6 : HSR IR Q6 Magnet (WBS 6.05.02.01)

P-HSR-MAG-IR_Q6.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-IR_Q6 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-IR_Q6.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q6.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-IR_Q8 : HSR IR Q8 Magnet (WBS 6.05.02.01)

P-HSR-MAG-IR_Q8.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-IR_Q8 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-IR_Q8.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q8.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-IR_Q9 : HSR IR Q9 Magnet (WBS 6.05.02.01)

P-HSR-MAG-IR_Q9.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-IR_Q9 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-IR_Q9.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_Q9.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-KA3 : HSR Dipole (KA3) Magnet (WBS 6.05.02.01)

P-HSR-MAG-KA3.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-KA3 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-KA3.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-KA3.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q1 : HSR Magnet Q1 (WBS 6.05.02.01)

P-HSR-MAG-Q1.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q1 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q1.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q1.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q2 : HSR Magnet Q2 (WBS 6.05.02.01)

P-HSR-MAG-Q2.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.02.03
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.02
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.03
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.05
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.06
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.07
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q2 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q2.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q2.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q3 : HSR Magnet Q3 (WBS 6.05.02.01)

P-HSR-MAG-Q3.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q3 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q3.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q3PR : HSR Q3PR Magnet (WBS 6.05.02.01)

P-HSR-MAG-Q3PR.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q3PR EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q3PR.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q3PR.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q4 : HSR Magnet Q4 (WBS 6.05.02.01)

P-HSR-MAG-Q4.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q4 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q4.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q4PR : HSR Q4PR Magnet (WBS 6.05.02.01)

P-HSR-MAG-Q4PR.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q4PR EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q4PR.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q4PR.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q5 : HSR Magnet Q5 (WBS 6.05.02.01)

P-HSR-MAG-Q5.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q5 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q5.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q5PR : HSR Q5PR Magnet (WBS 6.05.02.01)

P-HSR-MAG-Q5PR.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q5PR EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q5PR.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q5PR.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q6 : HSR Magnet Q6 (WBS 6.05.02.01)

P-HSR-MAG-Q6.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q6 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q6.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q6.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q7 : HSR Magnet Q7 (WBS 6.05.02.01)

P-HSR-MAG-Q7.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q7 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q7.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q7.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q8 : HSR Magnet Q8 (WBS 6.05.02.01)

P-HSR-MAG-Q8.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q8 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q8.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q8.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q9 : HSR Magnet Q9 (WBS 6.05.02.01)

P-HSR-MAG-Q9.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-Q9 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-Q9.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-Q9.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-sxt : HSR Sextupole (CQS(Sxt)) Magnet (WBS 6.05.02.01)

HSR-MAG-D8_IR02 : HSR Dipole (D8_IR02) Magnet (WBS 6.05.02.02)

P-HSR-MAG-D8_IR02.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-D8_IR02 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-D8_IR02.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR02.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-D8_IR06 : HSR Dipole (D8_IR06) Magnet (WBS 6.05.02.02)

P-HSR-MAG-D8_IR06.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-D8_IR06 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-D8_IR06.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-D8_IR06.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-H5_QS3 : HSR Quadrupole (H5_QS3) Magnet (WBS 6.05.02.02)

P-HSR-MAG-H5_QS3.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-H5_QS3 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-H5_QS3.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-H5_QS3.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-SLOWKICK_CORR : HSR Corrector (SLOWKICK_CORR) Magnet (WBS 6.05.02.02)

P-HSR-MAG-SLOWKICK_CORR.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-SLOWKICK_CORR EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-SLOWKICK_CORR.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-SLOWKICK_CORR.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_CQS(Corr

HSR-MAG-AR_CQS(Corr-H) : HSR Horizontal Corrector (AR_CQS(Corr-H)) Magnet (WBS 6.05.02.01)

P-HSR-MAG-AR_CQS(Corr-H).01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_CQS(Corr-H) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-AR_CQS(Corr-H).03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-H).10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_CQS(Corr-HV) : HSR Vertical/Horizonal Corrector (AR_CQS(Corr-HV)) Magnet (WBS 6.05.02.01)

P-HSR-MAG-AR_CQS(Corr-HV).01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_CQS(Corr-HV) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-AR_CQS(Corr-HV).03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-HV).10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_CQS(Corr-V) : HSR Vertical Corrector (AR_CQS(Corr-V)) Magnet (WBS 6.05.02.01)

P-HSR-MAG-AR_CQS(Corr-V).01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-AR_CQS(Corr-V) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-AR_CQS(Corr-V).03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-AR_CQS(Corr-V).10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-CORR_0

P-HSR-MAG-CORR_0.05m.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-CORR_0 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-CORR_0.05m.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-CORR_0.05m.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-CORR_0.5m

HSR-MAG-CQ1(Q1) : HSR Q1 Magnet(CQ1_QRI_Q1)

P-HSR-MAG-CQ1(Q1).01.01
6.05.02.01
The Quadrupole shall be a 'QRI' RHIC Magnet in a 'CQ1' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 1.44 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).01.09
6.05.02.01
The magnet pole tip radius shall be 65 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).02.02
6.05.02.01
The magnet gradient field (G) shall be 48.1 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03
6.05.02.01
The magnet is a CQ1(QRI) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=40(mm), Ir=5000A.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03.03
6.05.02.01
-0.3<b3<0.58, -0.79<a3<0.33
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03.04
6.05.02.01
-0.58<b4<0.3, -0.27<a4<0.23
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03.05
6.05.02.01
-0.23<b5<0.27, -0.37<a5<0.21
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03.06
6.05.02.01
1.56<b6<2.74, -0.86<a6<-0.62
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03.07
6.05.02.01
-0.19<b7<0.25, -0.09<a7<0.49
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03.08
6.05.02.01
-0.32<b8<0.04, -0.12<a8<0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03.09
6.05.02.01
-0.03<b9<0.07, -0.07<a9<0.03
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).03.03.10
6.05.02.01
-0.27<b10<0.07, 0.16<a10<0.2
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).04
6.05.02.01
The magnet is a CQ1(QRI) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).05
6.05.02.01
The magnet is a CQ1(QRI) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ1(Q1).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ1(Q1).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ2(LA_KickH) : HSR Q2 Magnet(CQ2_CRI_Q2)

P-HSR-MAG-CQ2(LA_KickH).01.01
6.05.02.01
The Horizontal Kicker shall be a 'CRI' RHIC Magnet in a 'CQ2' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).01.09
6.05.02.01
The magnet pole tip radius shall be 65 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).02.01
6.05.02.01
The magnet dipole field (B) shall be B at 40mm,50(A)=0.0446 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).03
6.05.02.01
The magnet is a CQ2(CRI) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=40(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).03.03.05
6.05.02.01
-120<b5<120, a5~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).03.03.06
6.05.02.01
-100<b6<100, a6~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).04
6.05.02.01
The magnet is a CQ2(CRI) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).05
6.05.02.01
The magnet is a CQ2(CRI) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickH).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickH).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ2(LA_KickV) : HSR CQ2_CRI_LA_KickH

P-HSR-MAG-CQ2(LA_KickV).01.01
6.05.02.01
The Vertical Kicker shall be a 'CRJ' RHIC Magnet in a 'CQ2' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).01.09
6.05.02.01
The magnet pole tip radius shall be 65 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).02.01
6.05.02.01
The magnet dipole field (B) shall be B at 40mm,50(A)=0.285 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).03
6.05.02.01
The magnet is a CQ2(CRJ) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=40(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).03.03.02
6.05.02.01
-30<b2<30, a2~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).03.03.05
6.05.02.01
-120<b5<120, a5~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).03.03.06
6.05.02.01
-100<b6<100, a6~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).04
6.05.02.01
The magnet is a CQ2(CRJ) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).05
6.05.02.01
The magnet is a CQ2(CRJ) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(LA_KickV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(LA_KickV).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ2(Q2)

P-HSR-MAG-CQ2(Q2).01.01
6.05.02.01
The Quadrupole shall be a 'QRK' RHIC Magnet in a 'CQ2' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 3.4 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).01.09
6.05.02.01
The magnet pole tip radius shall be 65 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).02.02
6.05.02.01
The magnet gradient field (G) shall be 47.1 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03
6.05.02.01
The magnet is a CQ2(QRK) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=40(mm), Ir=5000A.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03.03
6.05.02.01
-0.51<b3<0.35, -0.69<a3<0.33
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03.04
6.05.02.01
-1.43<b4<-1.05, -0.09<a4<0.35
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03.05
6.05.02.01
-0.14<b5<0.3, -0.23<a5<0.33
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03.06
6.05.02.01
0.15<b6<0.91, -0.36<a6<0.18
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03.07
6.05.02.01
-0.17<b7<0.21, -0.09<a7<0.35
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03.08
6.05.02.01
-0.23<b8<-0.05, -0.11<a8<0.09
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03.09
6.05.02.01
-0.05<b9<0.05, -0.06<a9<0.06
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).03.03.10
6.05.02.01
-0.44<b10<-0.3, 0.03<a10<0.07
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).04
6.05.02.01
The magnet is a CQ2(QRK) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).05
6.05.02.01
The magnet is a CQ2(QRK) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ2(Q2).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ2(Q2).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ3(LA_KickH)

P-HSR-MAG-CQ3(LA_KickH).01.01
6.05.02.01
The Horizontal Kicker shall be a 'CRL' RHIC Magnet in a 'CQ3' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).01.09
6.05.02.01
The magnet pole tip radius shall be 65 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).02.01
6.05.02.01
The magnet dipole field (B) shall be B at 40mm,50(A)=0.0446 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).03
6.05.02.01
The magnet is a CQ3(CRL) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=40(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).03.03.05
6.05.02.01
-120<b5<120, a5~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).03.03.06
6.05.02.01
-100<b6<100, a6~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).04
6.05.02.01
The magnet is a CQ3(CRL) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).05
6.05.02.01
The magnet is a CQ3(CRL) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickH).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickH).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ3(LA_KickV)

P-HSR-MAG-CQ3(LA_KickV).01.01
6.05.02.01
The Vertical Kicker shall be a 'CRM' RHIC Magnet in a 'CQ3' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).01.09
6.05.02.01
The magnet pole tip radius shall be 65 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).02.01
6.05.02.01
The magnet dipole field (B) shall be B at 40mm,50(A)=0.285 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).03
6.05.02.01
The magnet is a CQ3(CRM) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=40(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).03.03.02
6.05.02.01
-30<b2<30, a2~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).03.03.05
6.05.02.01
-120<b5<120, a5~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).03.03.06
6.05.02.01
-100<b6<100, a6~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).04
6.05.02.01
The magnet is a CQ3(CRM) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).05
6.05.02.01
The magnet is a CQ3(CRM) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_KickV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_KickV).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ3(LA_SkewQuad)

P-HSR-MAG-CQ3(LA_SkewQuad).01.01
6.05.02.01
The LA SkewQuad shall be a 'CRK' RHIC Magnet in a 'CQ3' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 65 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03
6.05.02.01
The magnet is a CQ3(CRK) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rref=TBD(mm) \ TBD (A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.02
6.05.02.01
b2=tbd, a2=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.03
6.05.02.01
b3=tbd, a3=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.04
6.05.02.01
b4=tbd, a4=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.05
6.05.02.01
b5=tbd, a5=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.06
6.05.02.01
b6=tbd, a6=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.07
6.05.02.01
b7=tbd, a7=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.08
6.05.02.01
b8=tbd, a8=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.09
6.05.02.01
b9=tbd, a9=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).03.03.10
6.05.02.01
b10=tbd, a10=tbd
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).04
6.05.02.01
The magnet is a CQ3(CRK) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).05
6.05.02.01
The magnet is a CQ3(CRK) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(LA_SkewQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ3(Q3)

P-HSR-MAG-CQ3(Q3).01.01
6.05.02.01
The Quadrupole shall be a 'QRJ' RHIC Magnet in a 'CQ3' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 2.1 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).01.09
6.05.02.01
The magnet pole tip radius shall be 65 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).02.02
6.05.02.01
The magnet gradient field (G) shall be 47.3 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03
6.05.02.01
The magnet is a CQ3(QRJ) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=40(mm), Ir=5000A.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03.03
6.05.02.01
-0.72<b3<0.74, -0.19<a3<0.99
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03.04
6.05.02.01
-0.85<b4<0.17, -0.21<a4<0.45
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03.05
6.05.02.01
-0.46<b5<0, -0.09<a5<0.21
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03.06
6.05.02.01
1.54<b6<1.8, -0.34<a6<-0.2
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03.07
6.05.02.01
-0.1<b7<0.24, -0.1<a7<0.28
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03.08
6.05.02.01
-0.13<b8<0.13, -0.08<a8<0.06
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03.09
6.05.02.01
-0.01<b9<0.11, -0.02<a9<0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).03.03.10
6.05.02.01
-0.34<b10<-0.28, 0.06<a10<0.1
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).04
6.05.02.01
The magnet is a CQ3(QRJ) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).05
6.05.02.01
The magnet is a CQ3(QRJ) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ3(Q3).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ3(Q3).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ4(KickH)

P-HSR-MAG-CQ4(KickH).01.01
6.05.02.01
The Horizontal Kicker shall be a 'CRF' RHIC Magnet in a 'CQ4' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).03
6.05.02.01
The magnet is a CQ4(CRF) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).04
6.05.02.01
The magnet is a CQ4(CRF) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).05
6.05.02.01
The magnet is a CQ4(CRF) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickH).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickH).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ4(KickV)

P-HSR-MAG-CQ4(KickV).01.01
6.05.02.01
The Vertical Kicker shall be a 'CRC' RHIC Magnet in a 'CQ4' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).03
6.05.02.01
The magnet is a CQ4(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).03.03.02
6.05.02.01
-30<b2<30, a2~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).04
6.05.02.01
The magnet is a CQ4(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).05
6.05.02.01
The magnet is a CQ4(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(KickV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(KickV).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ4(Q4)

P-HSR-MAG-CQ4(Q4).01.01
6.05.02.01
The Quadrupole shall be a 'QR4' RHIC Magnet in a 'CQ4' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 1.83 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).02.02
6.05.02.01
The magnet gradient field (G) shall be 75.5 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03
6.05.02.01
The magnet is a CQ4(QR4) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be: Ref#1: Rr=25(mm), Ir=10(A) Ref#2: Rr=25(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03.02
6.05.02.01
Ref#1: b2=10000,a2=0 Ref#2: b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03.03
6.05.02.01
Ref#1: -2.22<b3<1, -3.59<a3<-0.27 Ref#2:-1.98<b3<1.56, -3.51<a3<-0.15
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03.04
6.05.02.01
Ref#1:-2.46<b4<-0.56, -0.47<a4<1.43 Ref#2:-2<b4<0.78, -0.67<a4<1.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03.05
6.05.02.01
Ref#1:-0.35<b5<0.63, -0.42<a5<0.54 Ref#2:-1<b5<2.14, -1.66<a5<1.14
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03.06
6.05.02.01
Ref#1:1<b6<1.84, -4.05<a6<-3.47 Ref#2:5.08<b6<6.32, -4.15<a6<-3.53
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03.07
6.05.02.01
Ref#1:-0.12<b7<0.14, -0.09<a7<0.17 Ref#2:-0.08<b7<0.18, -0.08<a7<0.2
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03.08
6.05.02.01
Ref#1:-0.61<b8<-0.43, -0.1<a8<0.12 Ref#2:-0.63<b8<-0.41, -0.05<a8<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03.09
6.05.02.01
Ref#1:-0.04<b9<0.06, -0.05<a9<0.05 Ref#2:-0.08<b9<0.2, -0.07<a9<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).03.03.10
6.05.02.01
Ref#1:-1.35<b10<-1.23, 0.33<a10<0.37 Ref#2:-1.52<b10<-1.36, 0.35<a10<0.43
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).04
6.05.02.01
The magnet is a CQ4(QR4) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).05
6.05.02.01
The magnet is a CQ4(QR4) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ4(Q4T)

P-HSR-MAG-CQ4(Q4T).01.01
6.05.02.01
The Quadrupole shall be a 'QRT' RHIC Magnet in a 'CQ4' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.75 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).02.02
6.05.02.01
The magnet gradient field (G) shall be 29.4 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).03
6.05.02.01
The magnet is a CQ4(QRT) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=31(mm), Ir=25(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).03.03.03
6.05.02.01
0.01<b3<1.38, -2.35<a3<0.67
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).03.03.04
6.05.02.01
-4.56<b4<-3.4, -0.24<a4<0.16
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).03.03.05
6.05.02.01
-0.2<b5<0.14, -0.13<a5<0.26
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).03.03.06
6.05.02.01
-10.47<b6<-9.97, -0.27<a6<-0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).03.03.10
6.05.02.01
0.09<b10<-1.55, 0.03<a10<0.03
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).04
6.05.02.01
The magnet is a CQ4(QRT) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).05
6.05.02.01
The magnet is a CQ4(QRT) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(Q4T).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(Q4T).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ4(SkewQuad)

P-HSR-MAG-CQ4(SkewQuad).01.01
6.05.02.01
The SkewQuad shall be a 'CRF' RHIC Magnet in a 'CQ4' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).03
6.05.02.01
The magnet is a CQ4(CRF) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).03.03.02
6.05.02.01
b2=0,a2=10000
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).04
6.05.02.01
The magnet is a CQ4(CRF) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).05
6.05.02.01
The magnet is a CQ4(CRF) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ4(SkewQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ4(SkewQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ5(GammaTQuad)

P-HSR-MAG-CQ5(GammaTQuad).01.01
6.05.02.01
The GammaTQuad shall be a 'CRB' RHIC Magnet in a 'CQ5' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).03
6.05.02.01
The magnet is a CQ5(CRB) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).04
6.05.02.01
The magnet is a CQ5(CRB) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).05
6.05.02.01
The magnet is a CQ5(CRB) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(GammaTQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(GammaTQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ5(KickH)

P-HSR-MAG-CQ5(KickH).01.01
6.05.02.01
The Horizontal Kicker shall be a 'CRB' RHIC Magnet in a 'CQ5' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).03
6.05.02.01
The magnet is a CQ5(CRB) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).04
6.05.02.01
The magnet is a CQ5(CRB) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).05
6.05.02.01
The magnet is a CQ5(CRB) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickH).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickH).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ5(KickV)

P-HSR-MAG-CQ5(KickV).01.01
6.05.02.01
The Vertical Kicker shall be a 'CRC' RHIC Magnet in a 'CQ5' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).03
6.05.02.01
The magnet is a CQ5(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).03.03.02
6.05.02.01
-30<b2<30, a2~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).04
6.05.02.01
The magnet is a CQ5(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).05
6.05.02.01
The magnet is a CQ5(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(KickV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(KickV).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ5(Q5)

P-HSR-MAG-CQ5(Q5).01.01
6.05.02.01
The Quadrupole shall be a 'QRG' RHIC Magnet in a 'CQ5' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 1.13 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).02.02
6.05.02.01
The magnet gradient field (G) shall be 75.5 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03
6.05.02.01
The magnet is a CQ5(QRG) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be: Ref#1: Rr=25(mm), Ir=10(A) Ref#2: Rr=25(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03.02
6.05.02.01
Ref#1: b2=10000,a2=0 Ref#2: b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03.03
6.05.02.01
Ref#1: -2.22<b3<1, -3.59<a3<-0.27 Ref#2:-1.98<b3<1.56, -3.51<a3<-0.15
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03.04
6.05.02.01
Ref#1:-2.46<b4<-0.56, -0.47<a4<1.43 Ref#2:-2<b4<0.78, -0.67<a4<1.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03.05
6.05.02.01
Ref#1:-0.35<b5<0.63, -0.42<a5<0.54 Ref#2:-1<b5<2.14, -1.66<a5<1.14
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03.06
6.05.02.01
Ref#1:1<b6<1.84, -4.05<a6<-3.47 Ref#2:5.08<b6<6.32, -4.15<a6<-3.53
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03.07
6.05.02.01
Ref#1:-0.12<b7<0.14, -0.09<a7<0.17 Ref#2:-0.08<b7<0.18, -0.08<a7<0.2
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03.08
6.05.02.01
Ref#1:-0.61<b8<-0.43, -0.1<a8<0.12 Ref#2:-0.63<b8<-0.41, -0.05<a8<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03.09
6.05.02.01
Ref#1:-0.04<b9<0.06, -0.05<a9<0.05 Ref#2:-0.08<b9<0.2, -0.07<a9<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).03.03.10
6.05.02.01
Ref#1:-1.35<b10<-1.23, 0.33<a10<0.37 Ref#2:-1.52<b10<-1.36, 0.35<a10<0.43
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).04
6.05.02.01
The magnet is a CQ5(QRG) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).05
6.05.02.01
The magnet is a CQ5(QRG) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ5(Q5T)

P-HSR-MAG-CQ5(Q5T).01.01
6.05.02.01
The Trim quadrupole shall be a 'QRT' RHIC Magnet in a 'CQ5' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.75 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).02.02
6.05.02.01
The magnet gradient field (G) shall be 29.4 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).03
6.05.02.01
The magnet is a CQ5(QRT) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=31(mm), Ir=25(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).03.03.03
6.05.02.01
0.01<b3<1.38, -2.35<a3<0.67
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).03.03.04
6.05.02.01
-4.56<b4<-3.4, -0.24<a4<0.16
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).03.03.05
6.05.02.01
-0.2<b5<0.14, -0.13<a5<0.26
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).03.03.06
6.05.02.01
-10.47<b6<-9.97, -0.27<a6<-0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).03.03.10
6.05.02.01
0.09<b10<-1.55, 0.03<a10<0.03
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).04
6.05.02.01
The magnet is a CQ5(QRT) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).05
6.05.02.01
The magnet is a CQ5(QRT) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(Q5T).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(Q5T).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ5(SkewQuad)

P-HSR-MAG-CQ5(SkewQuad).01.01
6.05.02.01
The SkewQuad shall be a 'CRC' RHIC Magnet in a 'CQ5' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).03
6.05.02.01
The magnet is a CQ5(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).03.03.02
6.05.02.01
b2=0,a2=10000
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).04
6.05.02.01
The magnet is a CQ5(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).05
6.05.02.01
The magnet is a CQ5(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ5(SkewQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ5(SkewQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ6(GammaTQuad)

P-HSR-MAG-CQ6(GammaTQuad).01.01
6.05.02.01
The GammaTQuad shall be a 'CRB' RHIC Magnet in a 'CQ6' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).03
6.05.02.01
The magnet is a CQ6(CRB) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).04
6.05.02.01
The magnet is a CQ6(CRB) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).05
6.05.02.01
The magnet is a CQ6(CRB) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(GammaTQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(GammaTQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ6(KickH)

P-HSR-MAG-CQ6(KickH).01.01
6.05.02.01
The Horizontal Kicker shall be a 'CRB' RHIC Magnet in a 'CQ6' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).03
6.05.02.01
The magnet is a CQ6(CRB) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).04
6.05.02.01
The magnet is a CQ6(CRB) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).05
6.05.02.01
The magnet is a CQ6(CRB) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickH).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickH).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ6(KickV)

P-HSR-MAG-CQ6(KickV).01.01
6.05.02.01
The Vertical Kicker shall be a 'CRC' RHIC Magnet in a 'CQ6' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).03
6.05.02.01
The magnet is a CQ6(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).03.03.02
6.05.02.01
-30<b2<30, a2~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).04
6.05.02.01
The magnet is a CQ6(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).05
6.05.02.01
The magnet is a CQ6(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(KickV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(KickV).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ6(Q6)

P-HSR-MAG-CQ6(Q6).01.01
6.05.02.01
The Quadrupole shall be a 'QRG' RHIC Magnet in a 'CQ6' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 1.13 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).02.02
6.05.02.01
The magnet gradient field (G) shall be 75.5 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03
6.05.02.01
The magnet is a CQ6(QRG) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be: Ref#1: Rr=25(mm), Ir=10(A) Ref#2: Rr=25(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03.02
6.05.02.01
Ref#1: b2=10000,a2=0 Ref#2: b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03.03
6.05.02.01
Ref#1: -2.22<b3<1, -3.59<a3<-0.27 Ref#2:-1.98<b3<1.56, -3.51<a3<-0.15
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03.04
6.05.02.01
Ref#1:-2.46<b4<-0.56, -0.47<a4<1.43 Ref#2:-2<b4<0.78, -0.67<a4<1.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03.05
6.05.02.01
Ref#1:-0.35<b5<0.63, -0.42<a5<0.54 Ref#2:-1<b5<2.14, -1.66<a5<1.14
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03.06
6.05.02.01
Ref#1:1<b6<1.84, -4.05<a6<-3.47 Ref#2:5.08<b6<6.32, -4.15<a6<-3.53
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03.07
6.05.02.01
Ref#1:-0.12<b7<0.14, -0.09<a7<0.17 Ref#2:-0.08<b7<0.18, -0.08<a7<0.2
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03.08
6.05.02.01
Ref#1:-0.61<b8<-0.43, -0.1<a8<0.12 Ref#2:-0.63<b8<-0.41, -0.05<a8<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03.09
6.05.02.01
Ref#1:-0.04<b9<0.06, -0.05<a9<0.05 Ref#2:-0.08<b9<0.2, -0.07<a9<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).03.03.10
6.05.02.01
Ref#1:-1.35<b10<-1.23, 0.33<a10<0.37 Ref#2:-1.52<b10<-1.36, 0.35<a10<0.43
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).04
6.05.02.01
The magnet is a CQ6(QRG) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).05
6.05.02.01
The magnet is a CQ6(QRG) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ6(Q6T)

P-HSR-MAG-CQ6(Q6T).01.01
6.05.02.01
The Quadrupole shall be a 'QRT' RHIC Magnet in a 'CQ6' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.75 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).02.02
6.05.02.01
The magnet gradient field (G) shall be 29.4 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).03
6.05.02.01
The magnet is a CQ6(QRT) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=31(mm), Ir=25(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).03.03.03
6.05.02.01
0.01<b3<1.38, -2.35<a3<0.67
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).03.03.04
6.05.02.01
-4.56<b4<-3.4, -0.24<a4<0.16
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).03.03.05
6.05.02.01
-0.2<b5<0.14, -0.13<a5<0.26
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).03.03.06
6.05.02.01
-10.47<b6<-9.97, -0.27<a6<-0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).03.03.10
6.05.02.01
0.09<b10<-1.55, 0.03<a10<0.03
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).04
6.05.02.01
The magnet is a CQ6(QRT) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).05
6.05.02.01
The magnet is a CQ6(QRT) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(Q6T).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(Q6T).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ6(SkewQuad)

P-HSR-MAG-CQ6(SkewQuad).01.01
6.05.02.01
The SkewQuad shall be a 'CRC' RHIC Magnet in a 'CQ6' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).03
6.05.02.01
The magnet is a CQ6(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).03.03.02
6.05.02.01
b2=0,a2=10000
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).04
6.05.02.01
The magnet is a CQ6(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).05
6.05.02.01
The magnet is a CQ6(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ6(SkewQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ6(SkewQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ7(GammaTQuad)

P-HSR-MAG-CQ7(GammaTQuad).01.01
6.05.02.01
The GammaTQuad shall be a 'CRB' RHIC Magnet in a 'CQ7' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).03
6.05.02.01
The magnet is a CQ7(CRB) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).04
6.05.02.01
The magnet is a CQ7(CRB) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).05
6.05.02.01
The magnet is a CQ7(CRB) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(GammaTQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(GammaTQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ7(KickH)

P-HSR-MAG-CQ7(KickH).01.01
6.05.02.01
The Horizontal Kicker shall be a 'CRB' RHIC Magnet in a 'CQ7' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).03
6.05.02.01
The magnet is a CQ7(CRB) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).04
6.05.02.01
The magnet is a CQ7(CRB) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).05
6.05.02.01
The magnet is a CQ7(CRB) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickH).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickH).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ7(KickV)

P-HSR-MAG-CQ7(KickV).01.01
6.05.02.01
The Vertical Kicker shall be a 'CRC' RHIC Magnet in a 'CQ7' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).03
6.05.02.01
The magnet is a CQ7(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).03.03.02
6.05.02.01
-30<b2<30, a2~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).04
6.05.02.01
The magnet is a CQ7(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).05
6.05.02.01
The magnet is a CQ7(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(KickV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(KickV).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ7(Q7)

P-HSR-MAG-CQ7(Q7).01.01
6.05.02.01
The Quadrupole shall be a 'QR7' RHIC Magnet in a 'CQ7' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.95 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).02.02
6.05.02.01
The magnet gradient field (G) shall be 75.5 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03
6.05.02.01
The magnet is a CQ7(QR7) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be: Ref#1: Rr=25(mm), Ir=10(A) Ref#2: Rr=25(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03.02
6.05.02.01
Ref#1: b2=10000,a2=0 Ref#2: b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03.03
6.05.02.01
Ref#1: -2.22<b3<1, -3.59<a3<-0.27 Ref#2:-1.98<b3<1.56, -3.51<a3<-0.15
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03.04
6.05.02.01
Ref#1:-2.46<b4<-0.56, -0.47<a4<1.43 Ref#2:-2<b4<0.78, -0.67<a4<1.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03.05
6.05.02.01
Ref#1:-0.35<b5<0.63, -0.42<a5<0.54 Ref#2:-1<b5<2.14, -1.66<a5<1.14
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03.06
6.05.02.01
Ref#1:1<b6<1.84, -4.05<a6<-3.47 Ref#2:5.08<b6<6.32, -4.15<a6<-3.53
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03.07
6.05.02.01
Ref#1:-0.12<b7<0.14, -0.09<a7<0.17 Ref#2:-0.08<b7<0.18, -0.08<a7<0.2
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03.08
6.05.02.01
Ref#1:-0.61<b8<-0.43, -0.1<a8<0.12 Ref#2:-0.63<b8<-0.41, -0.05<a8<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03.09
6.05.02.01
Ref#1:-0.04<b9<0.06, -0.05<a9<0.05 Ref#2:-0.08<b9<0.2, -0.07<a9<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).03.03.10
6.05.02.01
Ref#1:-1.35<b10<-1.23, 0.33<a10<0.37 Ref#2:-1.52<b10<-1.36, 0.35<a10<0.43
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).04
6.05.02.01
The magnet is a CQ7(QR7) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).05
6.05.02.01
The magnet is a CQ7(QR7) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(Q7).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(Q7).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ7(SkewQuad)

P-HSR-MAG-CQ7(SkewQuad).01.01
6.05.02.01
The SkewQuad shall be a 'CRC' RHIC Magnet in a 'CQ7' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).03
6.05.02.01
The magnet is a CQ7(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).03.03.02
6.05.02.01
b2=0,a2=10000
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).04
6.05.02.01
The magnet is a CQ7(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).05
6.05.02.01
The magnet is a CQ7(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ7(SkewQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ7(SkewQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ8(GammaTQuad)

P-HSR-MAG-CQ8(GammaTQuad).01.01
6.05.02.01
The GammaTQuad shall be a 'CRB' RHIC Magnet in a 'CQ8' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).03
6.05.02.01
The magnet is a CQ8(CRB) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).04
6.05.02.01
The magnet is a CQ8(CRB) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).05
6.05.02.01
The magnet is a CQ8(CRB) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(GammaTQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(GammaTQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ8(KickH)

P-HSR-MAG-CQ8(KickH).01.01
6.05.02.01
The Horizontal Kicker shall be a 'CRB' RHIC Magnet in a 'CQ8' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).03
6.05.02.01
The magnet is a CQ8(CRB) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).04
6.05.02.01
The magnet is a CQ8(CRB) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).05
6.05.02.01
The magnet is a CQ8(CRB) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickH).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickH).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ8(KickV)

P-HSR-MAG-CQ8(KickV).01.01
6.05.02.01
The Vertical Kicker shall be a 'CRC' RHIC Magnet in a 'CQ8' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).03
6.05.02.01
The magnet is a CQ8(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).03.03.02
6.05.02.01
-30<b2<30, a2~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).04
6.05.02.01
The magnet is a CQ8(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).05
6.05.02.01
The magnet is a CQ8(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(KickV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(KickV).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ8(Q8)

P-HSR-MAG-CQ8(Q8).01.01
6.05.02.01
The Quadrupole shall be a 'QRG' RHIC Magnet in a 'CQ8' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 1.13 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).02.02
6.05.02.01
The magnet gradient field (G) shall be 75.5 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03
6.05.02.01
The magnet is a CQ8(QRG) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be: Ref#1: Rr=25(mm), Ir=10(A) Ref#2: Rr=25(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03.02
6.05.02.01
Ref#1: b2=10000,a2=0 Ref#2: b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03.03
6.05.02.01
Ref#1: -2.22<b3<1, -3.59<a3<-0.27 Ref#2:-1.98<b3<1.56, -3.51<a3<-0.15
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03.04
6.05.02.01
Ref#1:-2.46<b4<-0.56, -0.47<a4<1.43 Ref#2:-2<b4<0.78, -0.67<a4<1.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03.05
6.05.02.01
Ref#1:-0.35<b5<0.63, -0.42<a5<0.54 Ref#2:-1<b5<2.14, -1.66<a5<1.14
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03.06
6.05.02.01
Ref#1:1<b6<1.84, -4.05<a6<-3.47 Ref#2:5.08<b6<6.32, -4.15<a6<-3.53
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03.07
6.05.02.01
Ref#1:-0.12<b7<0.14, -0.09<a7<0.17 Ref#2:-0.08<b7<0.18, -0.08<a7<0.2
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03.08
6.05.02.01
Ref#1:-0.61<b8<-0.43, -0.1<a8<0.12 Ref#2:-0.63<b8<-0.41, -0.05<a8<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03.09
6.05.02.01
Ref#1:-0.04<b9<0.06, -0.05<a9<0.05 Ref#2:-0.08<b9<0.2, -0.07<a9<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).03.03.10
6.05.02.01
Ref#1:-1.35<b10<-1.23, 0.33<a10<0.37 Ref#2:-1.52<b10<-1.36, 0.35<a10<0.43
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).04
6.05.02.01
The magnet is a CQ8(QRG) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).05
6.05.02.01
The magnet is a CQ8(QRG) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(Q8).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(Q8).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ8(SkewQuad)

P-HSR-MAG-CQ8(SkewQuad).01.01
6.05.02.01
The SkewQuad shall be a 'CRC' RHIC Magnet in a 'CQ8' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).03
6.05.02.01
The magnet is a CQ8(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).03.03.02
6.05.02.01
b2=0,a2=10000
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).04
6.05.02.01
The magnet is a CQ8(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).05
6.05.02.01
The magnet is a CQ8(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ8(SkewQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ8(SkewQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ9(KickH)

P-HSR-MAG-CQ9(KickH).01.01
6.05.02.01
The Horizontal Kicker shall be a 'CRF' RHIC Magnet in a 'CQ9' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).03
6.05.02.01
The magnet is a CQ9(CRF) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).04
6.05.02.01
The magnet is a CQ9(CRF) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).05
6.05.02.01
The magnet is a CQ9(CRF) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickH).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickH).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ9(KickV)

P-HSR-MAG-CQ9(KickV).01.01
6.05.02.01
The Vertical Kicker shall be a 'CRC' RHIC Magnet in a 'CQ9' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).03
6.05.02.01
The magnet is a CQ9(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).03.03.02
6.05.02.01
-30<b2<30, a2~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).04
6.05.02.01
The magnet is a CQ9(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).05
6.05.02.01
The magnet is a CQ9(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(KickV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(KickV).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ9(Q9)

P-HSR-MAG-CQ9(Q9).01.01
6.05.02.01
The Quadrupole shall be a 'QRG' RHIC Magnet in a 'CQ9' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 1.13 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).02.02
6.05.02.01
The magnet gradient field (G) shall be 75.5 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03
6.05.02.01
The magnet is a CQ9(QRG) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be: Ref#1: Rr=25(mm), Ir=10(A) Ref#2: Rr=25(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03.02
6.05.02.01
Ref#1: b2=10000,a2=0 Ref#2: b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03.03
6.05.02.01
Ref#1: -2.22<b3<1, -3.59<a3<-0.27 Ref#2:-1.98<b3<1.56, -3.51<a3<-0.15
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03.04
6.05.02.01
Ref#1:-2.46<b4<-0.56, -0.47<a4<1.43 Ref#2:-2<b4<0.78, -0.67<a4<1.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03.05
6.05.02.01
Ref#1:-0.35<b5<0.63, -0.42<a5<0.54 Ref#2:-1<b5<2.14, -1.66<a5<1.14
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03.06
6.05.02.01
Ref#1:1<b6<1.84, -4.05<a6<-3.47 Ref#2:5.08<b6<6.32, -4.15<a6<-3.53
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03.07
6.05.02.01
Ref#1:-0.12<b7<0.14, -0.09<a7<0.17 Ref#2:-0.08<b7<0.18, -0.08<a7<0.2
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03.08
6.05.02.01
Ref#1:-0.61<b8<-0.43, -0.1<a8<0.12 Ref#2:-0.63<b8<-0.41, -0.05<a8<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03.09
6.05.02.01
Ref#1:-0.04<b9<0.06, -0.05<a9<0.05 Ref#2:-0.08<b9<0.2, -0.07<a9<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).03.03.10
6.05.02.01
Ref#1:-1.35<b10<-1.23, 0.33<a10<0.37 Ref#2:-1.52<b10<-1.36, 0.35<a10<0.43
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).04
6.05.02.01
The magnet is a CQ9(QRG) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).05
6.05.02.01
The magnet is a CQ9(QRG) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(Q9).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(Q9).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQ9(SkewQuad)

P-HSR-MAG-CQ9(SkewQuad).01.01
6.05.02.01
The SkewQuad shall be a 'CRC' RHIC Magnet in a 'CQ9' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).03
6.05.02.01
The magnet is a CQ9(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).03.03.02
6.05.02.01
b2=0,a2=10000
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).04
6.05.02.01
The magnet is a CQ9(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).05
6.05.02.01
The magnet is a CQ9(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQ9(SkewQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQ9(SkewQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQS(GammaTQuad)

P-HSR-MAG-CQS(GammaTQuad).01.01
6.05.02.01
The GammaTQuad shall be a 'CRB' RHIC Magnet in a 'CQS' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).03
6.05.02.01
The magnet is a CQS(CRB) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).04
6.05.02.01
The magnet is a CQS(CRB) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).05
6.05.02.01
The magnet is a CQS(CRB) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(GammaTQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(GammaTQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQS(KickH)

P-HSR-MAG-CQS(KickH).01.01
6.05.02.01
The Horizontal Kicker shall be a 'CRF' RHIC Magnet in a 'CQS' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).03
6.05.02.01
The magnet is a CQS(CRF) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).03.03.02
6.05.02.01
b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).04
6.05.02.01
The magnet is a CQS(CRF) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).05
6.05.02.01
The magnet is a CQS(CRF) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickH).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickH).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQS(KickV)

P-HSR-MAG-CQS(KickV).01.01
6.05.02.01
The Vertical Kicker shall be a 'CRC' RHIC Magnet in a 'CQS' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,52(A)=0.596 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).03
6.05.02.01
The magnet is a CQS(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).03.03.01
6.05.02.01
b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).03.03.02
6.05.02.01
-30<b2<30, a2~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).04
6.05.02.01
The magnet is a CQS(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).05
6.05.02.01
The magnet is a CQS(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(KickV).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(KickV).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQS(Q9)

P-HSR-MAG-CQS(Q9).01.01
6.05.02.01
The Quadrupole shall be a 'QRG' RHIC Magnet in a 'CQS' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 1.13 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).02.02
6.05.02.01
The magnet gradient field (G) shall be 75.5 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03
6.05.02.01
The magnet is a CQS(QRG) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be: Ref#1: Rr=25(mm), Ir=10(A) Ref#2: Rr=25(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03.02
6.05.02.01
Ref#1: b2=10000,a2=0 Ref#2: b2=10000,a2=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03.03
6.05.02.01
Ref#1: -2.22<b3<1, -3.59<a3<-0.27 Ref#2:-1.98<b3<1.56, -3.51<a3<-0.15
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03.04
6.05.02.01
Ref#1:-2.46<b4<-0.56, -0.47<a4<1.43 Ref#2:-2<b4<0.78, -0.67<a4<1.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03.05
6.05.02.01
Ref#1:-0.35<b5<0.63, -0.42<a5<0.54 Ref#2:-1<b5<2.14, -1.66<a5<1.14
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03.06
6.05.02.01
Ref#1:1<b6<1.84, -4.05<a6<-3.47 Ref#2:5.08<b6<6.32, -4.15<a6<-3.53
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03.07
6.05.02.01
Ref#1:-0.12<b7<0.14, -0.09<a7<0.17 Ref#2:-0.08<b7<0.18, -0.08<a7<0.2
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03.08
6.05.02.01
Ref#1:-0.61<b8<-0.43, -0.1<a8<0.12 Ref#2:-0.63<b8<-0.41, -0.05<a8<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03.09
6.05.02.01
Ref#1:-0.04<b9<0.06, -0.05<a9<0.05 Ref#2:-0.08<b9<0.2, -0.07<a9<0.13
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).03.03.10
6.05.02.01
Ref#1:-1.35<b10<-1.23, 0.33<a10<0.37 Ref#2:-1.52<b10<-1.36, 0.35<a10<0.43
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).04
6.05.02.01
The magnet is a CQS(QRG) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).05
6.05.02.01
The magnet is a CQS(QRG) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Q9).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Q9).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQS(SkewQuad)

P-HSR-MAG-CQS(SkewQuad).01.01
6.05.02.01
The SkewQuad shall be a 'CRC' RHIC Magnet in a 'CQS' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.5 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).02.01
6.05.02.01
The magnet dipole field (B) shall be B to 25mm,49,6(A)=0.067(T).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).03
6.05.02.01
The magnet is a CQS(CRC) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=25(mm), Ir=~50(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).03.03.01
6.05.02.01
-30<b1<30, a1~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).03.03.02
6.05.02.01
b2=0,a2=10000
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).03.03.03
6.05.02.01
-70<b3<70, a3~0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).03.03.04
6.05.02.01
-100<b4<100, -70<a4<70
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).04
6.05.02.01
The magnet is a CQS(CRC) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).05
6.05.02.01
The magnet is a CQS(CRC) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SkewQuad).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SkewQuad).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-CQS(SXT)

P-HSR-MAG-CQS(SXT).01.01
6.05.02.01
The Sextupole shall be a 'SRE' RHIC Magnet in a 'CQS' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Sxt).01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(SXT).01.06
6.05.02.01
The physical magnet length shall be less than or equal to 0.75 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Sxt).01.07
6.05.02.01
The magnet model length shall be TBD m.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).01.08
6.05.02.01
The magnet slot length shall be TBD m.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(SXT).01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Sxt).01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(SXT).02.02
6.05.02.01
The magnet gradient field (G) shall be 1150 (T/m).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/m^2.s.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Sxt).02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(SXT).03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=31(mm), Ir=25(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Sxt).03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(SXT).03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Sxt).03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(SXT).03.03.03
6.05.02.01
b3=10000,a3=0
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).03.03.04
6.05.02.01
-1.41<b3<0.87, -2.88<a3<2.76
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).03.03.05
6.05.02.01
-5.95<b4<-3.21, -1.31<a4<1.03
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).03.03.06
6.05.02.01
0.03<b5<0.45, -0.86<a5<1.16
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).03.03.07
6.05.02.01
-3.22<b6<-2.12, -0.66<a6<0.42
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Sxt).03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(SXT).03.03.09
6.05.02.01
-90.49<b8<-90.11, -0.43<a8<-0.19
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(Sxt).03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(Sxt).04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(SXT).06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SXT).06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SXT).07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(Sxt).07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
04/02/2025
Not Applicable
FALSE

P-HSR-MAG-CQS(SXT).08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SXT).08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SXT).08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

HSR-MAG-CQS(SXT) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-CQS(SXT).03
6.05.02.01
The magnet is a CQS(SRE) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).04
6.05.02.01
The magnet is a CQS(SRE) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).05
6.05.02.01
The magnet is a CQS(SRE) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-CQS(SXT).07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SXT).08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SXT).09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-CQS(SXT).10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-DCSEPT

P-HSR-MAG-DCSEPT.01.01
6.05.03.01
The magnet shall be a single function DC Septum vertical Dipole field.
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 3.98 (m)
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.01.10
6.05.03.01
The Septum thickness shall be ~3.9 (mm) and be able to accommodate the transferline beampipe.
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-MAG-DCSEPT.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-MAG-DCSEPT.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Reviewed
FALSE

P-HSR-MAG-DCSEPT.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Reviewed
FALSE

P-HSR-MAG-DCSEPT.02.01
6.05.03.01
The Integrated Dipole Field B shall provide a deflection angle of at least ~43.44(mrad) (B~1.03T).With a peak field in the magnet is held below 1T.
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.02.03
6.05.03.01
The septum ramp rate shall be able to accommodate two(2) bunch per AGS cycle seperated by 100 ms.
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/24/2025
Not Applicable
FALSE

P-HSR-MAG-DCSEPT.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.01
6.05.03.01
b1 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.02
6.05.03.01
b2 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.03
6.05.03.01
b3 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.04
6.05.03.01
b4 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.05
6.05.03.01
b5 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.06
6.05.03.01
b6 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.07
6.05.03.01
b7 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.08
6.05.03.01
b8 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.09
6.05.03.01
b9 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.10
6.05.03.01
b10 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.11
6.05.03.01
b11 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.12
6.05.03.01
b12 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.13
6.05.03.01
b13 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.14
6.05.03.01
b14 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.15
6.05.03.01
b15 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.03.03.16
6.05.03.01
b16 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.04.00
6.05.03.01
The magnet shall be designed to meet the following cross talk requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-MAG-DCSEPT.04.01
6.05.03.01
The Cross talk from the DC septum on the HSR circulating beam shall be less than 1x10-4, with respect to the main HSR circulating field.
02/24/2025
Approved
FALSE

P-HSR-MAG-DCSEPT.05.00
6.05.03.01
The magnet shall be desuigned to meet the following external fringe field constraints
02/17/2025
Not Applicable
FALSE

P-HSR-MAG-DCSEPT.05.01
6.05.03.01
The magnet shall have a stray field of no more than TBD gauss at a radial distance of TBD(m) from the magnet axis.
02/24/2025
Reviewed
FALSE

P-HSR-MAG-DCSEPT.05.02
6.05.03.01
The magnet shall have a stray field of no more than TBD gauss at a axialdistance of TBD(m) from the magnet axis.
02/24/2025
Reviewed
FALSE

HSR-MAG-DRG

P-HSR-MAG-DRG.01.01
6.05.02.01
The Dipole shall be a 'DRG' RHIC Magnet in a 'Dipole' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.01.06
6.05.02.01
The physical magnet length shall be less than or equal to 9.45 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.01.09
6.05.02.01
The magnet pole tip radius shall be 40 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.02.01
6.05.02.01
The magnet dipole field (B) shall be 0.401 (T) 3.458 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.02.03
6.05.02.01
The magnet ramp rate shall be 0.042 T/s.
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03
6.05.02.01
The magnet is a Dipole(DRG) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Ref#1: Rr=80(mm), Ir=660(A) Ref#2: Rr=80(mm), Ir=5000(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.01
6.05.02.01
Ref#1: b1=10000,a1=0 Ref#2: b1=10000,a1=0
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.02
6.05.02.01
Ref#1: -0.2<b2<0.36, -1.25<a2<1.81 Ref#2: -0.18<b2<0.38, -3.02<a2<0
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.03
6.05.02.01
Ref#1: -2.39<b3<2.05, -1.2<a3<-0.86 Ref#2: -0.93<b3<2.59, -1.25<a3<-0.89
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.04
6.05.02.01
Ref#1: -0.08<b4<0.08, -0.45<a4<0.39 Ref#2: -0.07<b4<0.09, -0.77<a4<0.05
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.05
6.05.02.01
Ref#1: -0.9<b5<0.24, 0.15<a5<0.27 Ref#2: -0.44<b5<0.74, 0.14<a5<0.26
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.06
6.05.02.01
Ref#1: -0.03<b6<0.03, -0.13<a6<0.17 Ref#2: -0.07<b6<0.01, -0.22<a6<0.1
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.07
6.05.02.01
Ref#1: -0.26<b7<0, -0.12<a7<-0.08 Ref#2: 1.05<b7<1.33, -0.12<a7<-0.08
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.08
6.05.02.01
Ref#1: -0.02<b8<0, -0.06<a8<0.04 Ref#2: -0.02<b8<0, -0.06<a8<0.04
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.09
6.05.02.01
Ref#1: 0.02<b9<0.26, 0.01<a9<0.03 Ref#2: 0<b9<0.24, 0.01<a9<0.03
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.03.03.10
6.05.02.01
Ref#1: 0<b10<0.04, 0.02<a10<0.06 Ref#2: 0<b10<0.04, 0.02<a10<0.06
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.04
6.05.02.01
The magnet is a Dipole(DRG) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.05
6.05.02.01
The magnet is a Dipole(DRG) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-DRG.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-DRG.10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-INDSEPT

P-HSR-MAG-INDSEPT.01.01
6.05.03.01
The magnet shall be a single function Induction Septum vertical Dipole field.
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 1.5 (m)
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.01.10
6.05.03.01
The Septum thickness shall be ~14 (mm) and be able to accommodate the transferline beampipe.
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-MAG-INDSEPT.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-MAG-INDSEPT.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Reviewed
FALSE

P-HSR-MAG-INDSEPT.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Reviewed
FALSE

P-HSR-MAG-INDSEPT.02.01
6.05.03.01
The Integrated Dipole Field B shall provide a deflection angle of at ~12.2 (mrad) (B~1.48T).With a peak field in the magnet is held below 1T.
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.02.03
6.05.03.01
The septum ramp rate shall be able to accommodate two(2) bunch per AGS cycle seperated by 100 ms.
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/24/2025
Not Applicable
FALSE

P-HSR-MAG-INDSEPT.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.04.00
6.05.03.01
The magnet shall be designed to meet the following cross talk requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-MAG-INDSEPT.04.01
6.05.03.01
The Cross talk from the DC septum on the HSR circulating beam shall be less than 1x10-4, with respect to the main HSR circulating field.
02/24/2025
Approved
FALSE

P-HSR-MAG-INDSEPT.05.00
6.05.03.01
The magnet shall be desuigned to meet the following external fringe field constraints
02/17/2025
Not Applicable
FALSE

P-HSR-MAG-INDSEPT.05.01
6.05.03.01
The magnet shall have a stray field of no more than TBD gauss at a radial distance of TBD(m) from the magnet axis.
02/24/2025
Reviewed
FALSE

P-HSR-MAG-INDSEPT.05.02
6.05.03.01
The magnet shall have a stray field of no more than TBD gauss at a axialdistance of TBD(m) from the magnet axis.
02/24/2025
Reviewed
FALSE

HSR-MAG-IR_VKICKER_0

P-HSR-MAG-IR_VKICKER_0.025.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

HSR-MAG-IR_VKICKER_0 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MAG-IR_VKICKER_0.025.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-IR_VKICKER_0.025.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

HSR-MAG-IR_VKICKER_0.25

HSR-MAG-SNAKE

P-HSR-MAG-SNAKE.01.01
6.05.02.01
The Solenoid shall be a 'HLX' RHIC Magnet in a 'Snake' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.01.06
6.05.02.01
The physical magnet length shall be less than or equal to 10.4 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.01.09
6.05.02.01
The magnet pole tip radius shall be 50 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.02.01
6.05.02.01
The magnet dipole field (B) shall be 4 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.03
6.05.02.01
The magnet is a HLX(Snake) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=31(mm), Ir=329(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.03.03.02
6.05.02.01
-25<B2<+25
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.03.03.04
6.05.02.01
-3<B4<+3
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.04
6.05.02.01
The magnet is a HLX(Snake) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.05
6.05.02.01
The magnet is a HLX(Snake) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-SNAKE.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-SNAKE.10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-SpinRotator

P-HSR-MAG-SpinRotator.01.01
6.05.02.01
The Solenoid shall be a 'HLX' RHIC Magnet in a 'Spin Rotator' RHIC Magnet Assembly.
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.01.06
6.05.02.01
The physical magnet length shall be less than or equal to 10.4 (m).
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.01.09
6.05.02.01
The magnet pole tip radius shall be 50 (mm).
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.02.01
6.05.02.01
The magnet dipole field (B) shall be 4 (T).
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.03
6.05.02.01
The magnet is a HLX(Spin Rotator) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be Rr=31(mm), Ir=329(A).
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.03.03
6.05.02.01
The magnet bore field transfer function and field homogeneity values are maintained in the BNL magnet repository. Provided is the summary of harmonic multipole content.
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.03.03.02
6.05.02.01
-25<B2<+25
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.03.03.04
6.05.02.01
-3<B4<+3
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.04
6.05.02.01
The magnet is a HLX(Spin Rotator) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.05
6.05.02.01
The magnet is a HLX(Spin Rotator) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at 4.6 (K) and the corresponding saturated vapor pressure.
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and 4.6 (K).
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and 4.6 (K), and vapor cooling flow of TBD g/s from TBD K to TBD K
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/19/2025
In Process
FALSE

P-HSR-MAG-SpinRotator.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at 4.6 K.
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/19/2025
Approved
FALSE

P-HSR-MAG-SpinRotator.10
6.05.02.01
The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
02/19/2025
Approved
FALSE

HSR-MAG-TQQ1

P-HSR-MAG-TQQ1.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ1.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-TQQ2

P-HSR-MAG-TQQ2.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ2.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-MAG-TQQ3

P-HSR-MAG-TQQ3.01.01
6.05.02.01
The HSR magnet shall operate with TBD functions with a TBD field type and TBD direction/rotation.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.02
6.05.02.01
The magnet shall require air trim coils capable of trimming the field +- TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.03
6.05.02.01
The magnet shall require current taps for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.04
6.05.02.01
The magnet shall require shunt(s) for operation TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.05
6.05.02.01
The magnet shall be design is TBD to have a splitable pole.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.06
6.05.02.01
The physical magnet length shall be < TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.07
6.05.02.01
The magnet model length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.08
6.05.02.01
The magnet slot length shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.09
6.05.02.01
The magnet pole tip radius shall be TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.10
6.05.02.01
The minimal magnet bore gap and width shall be TBD and TBD m.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.01.11
6.05.02.01
The magnet shall be designed to fit within a TBD envelope.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.02.01
6.05.02.01
The magnet integrated dipole field (B) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.02.02
6.05.02.01
The magnet integrated gradient field (G) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.02.03
6.05.02.01
The magnet ramp rate shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.02.04
6.05.02.01
The magnet good field aperture, dAx, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.02.05
6.05.02.01
The magnet good field aperture, dAy, shall be TBD mm.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.02.06
6.05.02.01
The magnet to magnet variability shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.02.07
6.05.02.01
The magnetic field position and alignment within the magnet shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be TBD mm and TBD A.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be TBD.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03
6.05.02.01
The magnet bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.01
6.05.02.01
b1 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.02
6.05.02.01
b2 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.03
6.05.02.01
b3 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.04
6.05.02.01
b4 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.05
6.05.02.01
b5 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.06
6.05.02.01
b6 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.07
6.05.02.01
b7 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.08
6.05.02.01
b8 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.09
6.05.02.01
b9 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.10
6.05.02.01
b10 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.11
6.05.02.01
b11 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.12
6.05.02.01
b12 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.13
6.05.02.01
b13 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.14
6.05.02.01
b14 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.15
6.05.02.01
b15 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.03.03.16
6.05.02.01
b16 = TBD (10^-4) for the magnet bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04
6.05.02.01
The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.01
6.05.02.01
The magnet harmonic reference radius (Rr) and current (Ir) shall be constrained to TBD mm and TBD A in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.02
6.05.02.01
The magnet field at the reference radius (Bref) shall be constrained to TBD in order to minimize crosstalk.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03
6.05.02.01
The magnet crosstalk bore field shall have a field homogeneity of better than TBD dB/B and meet the following harmonic multipole content.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.01
6.05.02.01
b1 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.02
6.05.02.01
b2 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.03
6.05.02.01
b3 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.04
6.05.02.01
b4 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.05
6.05.02.01
b5 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.06
6.05.02.01
b6 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.07
6.05.02.01
b7 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.08
6.05.02.01
b8 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.09
6.05.02.01
b9 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.10
6.05.02.01
b10 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.11
6.05.02.01
b11 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.12
6.05.02.01
b12 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.13
6.05.02.01
b13 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.14
6.05.02.01
b14 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.15
6.05.02.01
b15 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.04.03.16
6.05.02.01
b16 = TBD (10^-4) for magnet crosstalk bore field homogeneity.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.05
6.05.02.01
The magnet shall not be designed to constrain the external fringe field.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.06
6.05.02.01
The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.06.01
6.05.02.01
The magnet shall be designed to be cooled and sustain operations at nominal operating conditions with a superfluid helium (HeII) Bath. The Bath will operate with a pressurized magnet volume at TBD bar. The sub-atmospheric side of the heat exchanger will operate at TBD K and the corresponding saturated vapor pressure.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.06.02
6.05.02.01
The magnet current leads shall be designed to be cooled and sustain operations at nominal operating conditions of helium (HeII) bath at TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.06.03
6.05.02.01
The magnet shall be capable of removing a maximum total heat load of TBD W while maintaining nominal operating conditions under TBD bar and TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.06.04
6.05.02.01
The magnet current leads cooling shall be capable of removing a maximum total heat load of TBD W at the cold end while maintaining nominal operating conditions under TBD bar and TBD K, and vapor cooling flow of TBD g/s from TBD K to TBD K
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.06.05
6.05.02.01
The maximum differential internal pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.06.06
6.05.02.01
The maximum atmospheric external pressure from the helium volume to the vacuum in the magnet structure shall be TBD bar.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.06.07
6.05.02.01
The magnet shall be designed to remove the heat from the coil through a pressurized heat exchanger for all operational modes.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.06.08
6.05.02.01
The magnet shall be designed to handle a controlled cooldown with minimum of a TBD K axial gradient.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.07
6.05.02.01
The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.07.01
6.05.02.01
The magnet shall be able to survive the thermal dynamics during cooldown and following a quench without degradation in its performance.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.07.02
6.05.02.01
After a thermal cycle to room temperature, the magnet SHOULD attain the nominal operating current with no quenches and SHALL attain the nominal operating current with no more than 3 quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.07.03
6.05.02.01
The magnet shall be designed to attain the design field with no more than 20 training quenches.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.08
6.05.02.01
All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.08.01
6.05.02.01
The magnet coils and quench protection heaters shall pass a Hi-Pot test at nominal operating conditions corresponding to Vtest = (2xPeak Voltage +500 Volts).
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.08.02
6.05.02.01
The magnet shall be delivered with three redundant (3x2) quench detection voltage taps located on each magnet lead and at the electrical midpoint of the magnet circuit; and two (2) voltage taps for each internal splice. Each voltage tap used for critical quench detection shall have a redundant voltage tap.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.08.03
6.05.02.01
All SC magnet Splice resistances within the coil module or to the coil module SHALL be less than 1.0 nΩ at TBD K.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.09
6.05.02.01
The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
02/18/2025
Not Applicable
FALSE

P-HSR-MAG-TQQ3.10
6.05.02.01
The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
02/18/2025
Not Applicable
FALSE

HSR-PS : HSR Magnet Power Supply (WBS 6.05.02.02)

HSR-PS-(Q5,Q6,Q8,Q9) : HSR Quadrupole (Q5,Q6,Q8,Q9) Power Supply (WBS 6.05.02.01)

HSR-PS-(Q5,Q6,Q8,Q9)_IR : HSR Quadrupole ((Q5,Q6,Q8,Q9)_IR) Power Supply (WBS 6.05.02.01)

HSR-PS-CORR_0 : HSR Corrector (CORR_0) Power Supply (WBS 6.05.02.01)

HSR-PS-CORR_0 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-CORR_0.05m.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.05m.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.05m.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.05m.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.05m.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.05m.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.05m.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.05m.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CORR_0.5m.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-D8_IR02 : HSR Dipole (D8_IR02) Power Supply (WBS 6.05.02.01)

HSR-PS-D8_IR02 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-D8_IR02.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR02.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-D8_IR06 : HSR Dipole (D8_IR06) Power Supply (WBS 6.05.02.01)

HSR-PS-D8_IR06 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-D8_IR06.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8_IR06.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-H5_QS3 : HSR Quadrupole (H5_QS3) Power Supply (WBS 6.05.02.01)

HSR-PS-H5_QS3 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-H5_QS3.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-H5_QS3.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q3PR/Q4PR/Q5PR : HSR Quadrupole (Q3PR/Q4PR/Q5PR) Power Supply (WBS 6.05.02.01)

HSR-PS-SLOWKICK_CORR : HSR Corrector (SLOWKICK_CORR) Power Supply (WBS 6.05.02.01)

HSR-PS-SLOWKICK_CORR EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-SLOWKICK_CORR.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-SLOWKICK_CORR.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-TRIMQUAD(Q1,Q2,Q3) : HSR Quadrupole (Q1,Q2,Q3) Power Supply (WBS 6.05.02.01)

HSR-PS-AR_CQS(Quad) : HSR Quadrupole (AR_CQS(Corr-HV)) Power Supply (WBS 6.05.02.02)

HSR-PS-AR_CQS(Quad) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-AR_CQS(Quad).01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Quad).47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-AR_CQS(Sxt) : HSR Sextupole (PS-AR_CQS(Quad)) Power Supply (WBS 6.05.02.02)

HSR-PS-AR_CQS(Sxt) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-AR_CQS(Sxt).01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Sxt).47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-AR_D6 : HSR Dipole (AR_D6) Power Supply (WBS 6.05.02.02)

HSR-PS-AR_D6 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-AR_D6.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D6.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-AR_D8 : HSR Dipole (AR_D8) Power Supply (WBS 6.05.02.02)

HSR-PS-AR_D8 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-AR_D8.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D8.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-AR_D9 : HSR Dipole (AR_D9) Power Supply (WBS 6.05.02.02)

HSR-PS-AR_D9 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-AR_D9.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_D9.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-B1PR : HSR Dipole (B1PR) Power Supply (WBS 6.05.02.02)

HSR-PS-B1PR EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-B1PR.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-B1PR.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-BXDS01A : HSR Dipole (BXDS01A) Power Supply (WBS 6.05.02.02)

HSR-PS-BXDS01A EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-BXDS01A.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-BXDS01A.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-CORR : HSR Magnet Power Supply CORR (WBS 6.05.02.02)

HSR-PS-CQS(Sxt) : HSR Sextupole (CQS(Sxt)) Power Supply (WBS 6.05.02.02)

HSR-PS-CQS(Sxt) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-CQS(Sxt).01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-CQS(Sxt).47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-D0 : HSR Magnet Power Supply D0 (WBS 6.05.02.02)

HSR-PS-D5I : HSR Magnet Power Supply D5I (WBS 6.05.02.02)

HSR-PS-D5I EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-D5I.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5I.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5I.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5I.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5I.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5I.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5I.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5I.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5I.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5I.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5I.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-D5O : HSR Magnet Power Supply D5O (WBS 6.05.02.02)

HSR-PS-D5O EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-D5O.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.35
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.36
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.37
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.38
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.39
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.40
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.41
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.42
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.43
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.44
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.45
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.46
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O.47
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-D5O_D5I : HSR Dipole (D5O_D5I) Power Supply (WBS 6.05.02.02)

HSR-PS-D5O_D5I EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-D5O_D5I.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D5O_D5I.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-D6 : HSR Magnet Power Supply D6 (WBS 6.05.02.02)

HSR-PS-D6 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-D6.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D6.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D6.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D6.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D6.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D6.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D6.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D6.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D6.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D6.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D6.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-D8 : HSR Magnet Power Supply D8 (WBS 6.05.02.02)

HSR-PS-D8 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-D8.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D8.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D8.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-D9 : HSR Magnet Power Supply D9 (WBS 6.05.02.02)

HSR-PS-D9 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-D9.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D9.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D9.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D9.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D9.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D9.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D9.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D9.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D9.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-D9.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-D9.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-DSW : HSR Magnet Power Supply DSW (WBS 6.05.02.02)

HSR-PS-DX : HSR Magnet Power Supply DX (WBS 6.05.02.02)

HSR-PS-HKICK : HSR Magnet Power Supply HKICK (WBS 6.05.02.02)

HSR-PS-IR_Q5 : HSR IR Q5 Power Supply (WBS 6.05.02.02)

HSR-PS-IR_Q5 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-IR_Q5.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q5.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-IR_Q6 : HSR IR Q6 Power Supply (WBS 6.05.02.02)

HSR-PS-IR_Q6 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-IR_Q6.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q6.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-IR_Q8 : HSR IR Q8 Power Supply (WBS 6.05.02.02)

HSR-PS-IR_Q8 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-IR_Q8.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q8.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-IR_Q9 : HSR IR Q9 Power Supply (WBS 6.05.02.02)

HSR-PS-IR_Q9 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-IR_Q9.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_Q9.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-IR_VKICKER_0 : HSR Corrector (IR_VKICKER_0) Power Supply (WBS 6.05.02.02)

HSR-PS-IR_VKICKER_0 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-IR_VKICKER_0.25.1
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.2
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.3
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.4
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.6
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.7
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.8
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.9
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-IR_VKICKER_0.25.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-KA3 : HSR Dipole (KA3) Power Supply (WBS 6.05.02.02)

HSR-PS-KA3 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-KA3.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-KA3.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-KA3.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-KA3.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-KA3.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-KA3.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-KA3.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-KA3.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-KA3.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-KA3.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-KA3.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q : HSR Magnet Power Supply Q (WBS 6.05.02.02)

HSR-PS-Q1 : HSR Magnet Power Supply Q1 (WBS 6.05.02.02)

HSR-PS-Q1 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q1.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q1.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q1.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q1.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q1.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q1.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q1.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q1.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q1.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q1.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q1.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q2 : HSR Magnet Power Supply Q2 (WBS 6.05.02.02)

HSR-PS-Q2 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q2.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q2.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q2.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q2.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q2.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q2.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q2.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q2.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q2.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q2.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q2.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q3 : HSR Magnet Power Supply Q3 (WBS 6.05.02.02)

HSR-PS-Q3 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q3.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q3PR : HSR Q3PR Power Supply (WBS 6.05.02.02)

HSR-PS-Q3PR EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q3PR.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q3PR.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q4 : HSR Magnet Power Supply Q4 (WBS 6.05.02.02)

HSR-PS-Q4 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q4.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q4PR : HSR Q4PR Power Supply (WBS 6.05.02.02)

HSR-PS-Q4PR EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q4PR.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q4PR.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q5 : HSR Magnet Power Supply Q5 (WBS 6.05.02.02)

HSR-PS-Q5 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q5.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q5PR : HSR Q5PR Power Supply (WBS 6.05.02.02)

HSR-PS-Q5PR EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q5PR.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q5PR.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q6 : HSR Magnet Power Supply Q6 (WBS 6.05.02.02)

HSR-PS-Q7 : HSR Magnet Power Supply Q7 (WBS 6.05.02.02)

HSR-PS-Q7 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q7.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q7.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q7.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q7.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q7.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q7.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q7.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q7.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q7.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q7.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q7.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q8 : HSR Magnet Power Supply Q8 (WBS 6.05.02.02)

HSR-PS-Q8 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q8.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q8.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q8.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q8.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q8.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q8.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q8.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q8.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q8.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q8.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q8.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-Q9 : HSR Magnet Power Supply Q9 (WBS 6.05.02.02)

HSR-PS-Q9 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-Q9.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q9.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q9.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q9.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q9.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q9.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q9.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q9.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q9.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-Q9.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-Q9.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-QT : HSR Magnet Power Supply QT (WBS 6.05.02.02)

HSR-PS-QW : HSR Magnet Power Supply QW (WBS 6.05.02.02)

HSR-PS-SEXT : HSR Magnet Power Supply SEXT (WBS 6.05.02.02)

HSR-PS-SNAKE : HSR Magnet Power Supply SNAKE (WBS 6.05.02.02)

P-HSR-PS-SNAKE.1
6.05.02.02
The magnet model being powered by the power supply is snake.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SNAKE.2
6.05.02.02
The snake power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-SNAKE.3
6.05.02.02
The snake power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 15 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SNAKE.4
6.05.02.02
The snake power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SNAKE.5
6.05.02.02
The snake power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SNAKE.6
6.05.02.02
The snake power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.7
6.05.02.02
The snake power supply shall provide a minimal current setpoint resolution of 12 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SNAKE.8
6.05.02.02
The snake power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.9
6.05.02.02
The snake power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.10
6.05.02.02
The snake power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.11
6.05.02.02
The snake power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.12
6.05.02.02
The snake power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.13
6.05.02.02
The snake power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.14
6.05.02.02
The snake power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.15
6.05.02.02
The snake power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-SNAKE.16
6.05.02.02
The snake power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-SNAKE.17
6.05.02.02
The snake power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.18
6.05.02.02
The snake power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-SNAKE.19
6.05.02.02
The snake power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SNAKE.20
6.05.02.02
The snake power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-SPINR : HSR Magnet Power Supply SPINR (WBS 6.05.02.02)

HSR-PS-TQ1 : HSR TQ1 Power Supply (WBS 6.05.02.02)

HSR-PS-TQ2 : HSR TQ2 Power Supply (WBS 6.05.02.02)

HSR-PS-TQ3 : HSR TQ3 Power Supply (WBS 6.05.02.02)

HSR-PS-VKICK : HSR Magnet Power Supply VKICK (WBS 6.05.02.02)

HSR-PS-WARM_DX1 : HSR Dipole (WARM_DX1) Power Supply (WBS 6.05.02.02)

HSR-PS-WARM_DX1 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-WARM_DX1.01
6.06.02.03
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.02
6.06.02.03
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.03
6.06.02.03
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.04
6.06.02.03
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.5
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.06
6.06.02.03
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.07
6.06.02.03
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.08
6.06.02.03
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.09
6.06.02.03
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.10
6.06.02.03
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.11
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.12
6.06.02.03
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.13
6.06.02.03
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.14
6.06.02.03
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.15
6.06.02.03
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.16
6.06.02.03
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.17
6.06.02.03
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.18
6.06.02.03
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.19
6.06.02.03
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.20
6.06.02.03
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.21
6.06.02.03
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.22
6.06.02.03
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.23
6.06.02.03
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.24
6.06.02.03
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.25
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.26
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.27
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.28
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.29
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.30
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.31
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.32
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.33
6.06.02.03
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.34
6.06.02.03
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.35
6.06.02.03
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.36
6.06.02.03
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.37
6.06.02.03
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.38
6.06.02.03
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.39
6.06.02.03
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.40
6.06.02.03
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.41
6.06.02.03
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.42
6.06.02.03
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.43
6.06.02.03
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.44
6.06.02.03
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.45
6.06.02.03
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.46
6.06.02.03
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX1.47
6.06.02.03
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-WARM_DX2 : HSR Dipole (WARM_DX2) Power Supply (WBS 6.05.02.02)

HSR-PS-WARM_DX2 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-WARM_DX2.01
6.06.02.03
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.02
6.06.02.03
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.03
6.06.02.03
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.04
6.06.02.03
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.5
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.06
6.06.02.03
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.07
6.06.02.03
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.08
6.06.02.03
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.09
6.06.02.03
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.10
6.06.02.03
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.11
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.12
6.06.02.03
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.13
6.06.02.03
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.14
6.06.02.03
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.15
6.06.02.03
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.16
6.06.02.03
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.17
6.06.02.03
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.18
6.06.02.03
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.19
6.06.02.03
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.20
6.06.02.03
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.21
6.06.02.03
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.22
6.06.02.03
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.23
6.06.02.03
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.24
6.06.02.03
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.25
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.26
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.27
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.28
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.29
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.30
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.31
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.32
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.33
6.06.02.03
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.34
6.06.02.03
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.35
6.06.02.03
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.36
6.06.02.03
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.37
6.06.02.03
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.38
6.06.02.03
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.39
6.06.02.03
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.40
6.06.02.03
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.41
6.06.02.03
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.42
6.06.02.03
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.43
6.06.02.03
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.44
6.06.02.03
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.45
6.06.02.03
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.46
6.06.02.03
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_DX2.47
6.06.02.03
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-WARM_QUAD : HSR Quadrupole (WARM_QUAD) Power Supply (WBS 6.05.02.02)

HSR-PS-WARM_QUAD EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-WARM_QUAD.01
6.06.02.03
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.02
6.06.02.03
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.03
6.06.02.03
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.04
6.06.02.03
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.5
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.06
6.06.02.03
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.07
6.06.02.03
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.08
6.06.02.03
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.09
6.06.02.03
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.10
6.06.02.03
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.11
6.06.02.03
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.12
6.06.02.03
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.13
6.06.02.03
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.14
6.06.02.03
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.15
6.06.02.03
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.16
6.06.02.03
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.17
6.06.02.03
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.18
6.06.02.03
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.19
6.06.02.03
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.20
6.06.02.03
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.21
6.06.02.03
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.22
6.06.02.03
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.23
6.06.02.03
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.24
6.06.02.03
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.25
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.26
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.27
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.28
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.29
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.30
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.31
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.32
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.33
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.34
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.35
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.36
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.37
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.38
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.39
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.40
6.06.02.03
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.41
6.06.02.03
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.42
6.06.02.03
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.43
6.06.02.03
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.44
6.06.02.03
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.45
6.06.02.03
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.46
6.06.02.03
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-WARM_QUAD.47
6.06.02.03
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-AR_CQS(Corr

HSR-PS-AR_CQS(Corr-H) : HSR Horizontal Corrector (AR_CQS(Corr-H)) Power Supply (WBS 6.05.02.02)

HSR-PS-AR_CQS(Corr-H) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-AR_CQS(Corr-H).01
6.05.02.02
The number of Independent functions on the magnets being powered shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).02
6.05.02.02
The maximum magnet string resistance to be powered shall be TBD ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).08
6.05.02.02
The minimum current the PS must operate at shall be TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).11
6.05.02.02
The PS AC waveshape required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).12
6.05.02.02
The peak waveshape di/dt during ramping shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).13
6.05.02.02
The full power bandwidth required shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-H).47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-AR_CQS(Corr-HV) : HSR Vertical/Horizonal Corrector (AR_CQS(Corr-HV)) Power Supply (WBS 6.05.02.02)

HSR-PS-AR_CQS(Corr-HV) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-AR_CQS(Corr-HV).01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-HV).47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-AR_CQS(Corr-V) : HSR Vertical Corrector (AR_CQS(Corr-V)) Power Supply (WBS 6.05.02.02)

HSR-PS-AR_CQS(Corr-V) EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-AR_CQS(Corr-V).01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).33
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).34
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).35
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).36
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).37
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).38
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).39
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).40
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).41
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).42
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).43
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).44
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).45
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).46
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-AR_CQS(Corr-V).47
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

HSR-PS-BIP150

P-HSR-PS-BIP150.1
6.05.02.02
The magnet model being powered by the power supply is bip150.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP150.2
6.05.02.02
The bip150 power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP150.3
6.05.02.02
The bip150 power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 15 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP150.4
6.05.02.02
The bip150 power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP150.5
6.05.02.02
The bip150 power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP150.6
6.05.02.02
The bip150 power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.7
6.05.02.02
The bip150 power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP150.8
6.05.02.02
The bip150 power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.9
6.05.02.02
The bip150 power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.10
6.05.02.02
The bip150 power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.11
6.05.02.02
The bip150 power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.12
6.05.02.02
The bip150 power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.13
6.05.02.02
The bip150 power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.14
6.05.02.02
The bip150 power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.15
6.05.02.02
The bip150 power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP150.16
6.05.02.02
The bip150 power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP150.17
6.05.02.02
The bip150 power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.18
6.05.02.02
The bip150 power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP150.19
6.05.02.02
The bip150 power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP150.20
6.05.02.02
The bip150 power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-BIP300

P-HSR-PS-BIP300.1
6.05.02.02
The magnet model being powered by the power supply is bip300.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP300.2
6.05.02.02
The bip300 power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP300.3
6.05.02.02
The bip300 power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 15 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP300.4
6.05.02.02
The bip300 power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP300.5
6.05.02.02
The bip300 power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP300.6
6.05.02.02
The bip300 power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.7
6.05.02.02
The bip300 power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP300.8
6.05.02.02
The bip300 power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.9
6.05.02.02
The bip300 power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.10
6.05.02.02
The bip300 power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.11
6.05.02.02
The bip300 power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.12
6.05.02.02
The bip300 power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.13
6.05.02.02
The bip300 power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.14
6.05.02.02
The bip300 power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.15
6.05.02.02
The bip300 power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP300.16
6.05.02.02
The bip300 power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP300.17
6.05.02.02
The bip300 power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.18
6.05.02.02
The bip300 power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-BIP300.19
6.05.02.02
The bip300 power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-BIP300.20
6.05.02.02
The bip300 power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-DIPOLE

P-HSR-PS-DIPOLE.1
6.05.02.02
The magnet model being powered by the power supply is dipole.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DIPOLE.2
6.05.02.02
The dipole power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-DIPOLE.3
6.05.02.02
The dipole power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 20 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DIPOLE.4
6.05.02.02
The dipole power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DIPOLE.5
6.05.02.02
The dipole power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DIPOLE.6
6.05.02.02
The dipole power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.7
6.05.02.02
The dipole power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DIPOLE.8
6.05.02.02
The dipole power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.9
6.05.02.02
The dipole power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.10
6.05.02.02
The dipole power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.11
6.05.02.02
The dipole power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.12
6.05.02.02
The dipole power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.13
6.05.02.02
The dipole power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.14
6.05.02.02
The dipole power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.15
6.05.02.02
The dipole power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-DIPOLE.16
6.05.02.02
The dipole power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-DIPOLE.17
6.05.02.02
The dipole power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.18
6.05.02.02
The dipole power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-DIPOLE.19
6.05.02.02
The dipole power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DIPOLE.20
6.05.02.02
The dipole power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-DMAIN

P-HSR-PS-DMAIN.1
6.05.02.02
The magnet model being powered by the power supply is dmain.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DMAIN.2
6.05.02.02
The dmain power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-DMAIN.3
6.05.02.02
The dmain power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 400 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DMAIN.4
6.05.02.02
The dmain power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DMAIN.5
6.05.02.02
The dmain power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DMAIN.6
6.05.02.02
The dmain power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.7
6.05.02.02
The dmain power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DMAIN.8
6.05.02.02
The dmain power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.9
6.05.02.02
The dmain power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.10
6.05.02.02
The dmain power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.11
6.05.02.02
The dmain power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.12
6.05.02.02
The dmain power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.13
6.05.02.02
The dmain power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.14
6.05.02.02
The dmain power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.15
6.05.02.02
The dmain power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-DMAIN.16
6.05.02.02
The dmain power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-DMAIN.17
6.05.02.02
The dmain power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.18
6.05.02.02
The dmain power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-DMAIN.19
6.05.02.02
The dmain power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-DMAIN.20
6.05.02.02
The dmain power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-GAMMAT

P-HSR-PS-GAMMAT.1
6.05.02.02
The magnet model being powered by the power supply is gammat.
03/25/2025
Reviewed
FALSE

P-HSR-PS-GAMMAT.2
6.05.02.02
The gammat power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-GAMMAT.3
6.05.02.02
The gammat power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 20 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-GAMMAT.4
6.05.02.02
The gammat power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-GAMMAT.5
6.05.02.02
The gammat power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-GAMMAT.6
6.05.02.02
The gammat power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.7
6.05.02.02
The gammat power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-GAMMAT.8
6.05.02.02
The gammat power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.9
6.05.02.02
The gammat power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.10
6.05.02.02
The gammat power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.11
6.05.02.02
The gammat power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.12
6.05.02.02
The gammat power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.13
6.05.02.02
The gammat power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.14
6.05.02.02
The gammat power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.15
6.05.02.02
The gammat power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-GAMMAT.16
6.05.02.02
The gammat power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-GAMMAT.17
6.05.02.02
The gammat power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.18
6.05.02.02
The gammat power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-GAMMAT.19
6.05.02.02
The gammat power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-GAMMAT.20
6.05.02.02
The gammat power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-NONLINEAR

P-HSR-PS-NONLINEAR.1
6.05.02.02
The magnet model being powered by the power supply is nonlinear.
03/25/2025
Reviewed
FALSE

P-HSR-PS-NONLINEAR.2
6.05.02.02
The nonlinear power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-NONLINEAR.3
6.05.02.02
The nonlinear power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 20 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-NONLINEAR.4
6.05.02.02
The nonlinear power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-NONLINEAR.5
6.05.02.02
The nonlinear power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-NONLINEAR.6
6.05.02.02
The nonlinear power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.7
6.05.02.02
The nonlinear power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-NONLINEAR.8
6.05.02.02
The nonlinear power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.9
6.05.02.02
The nonlinear power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.10
6.05.02.02
The nonlinear power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.11
6.05.02.02
The nonlinear power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.12
6.05.02.02
The nonlinear power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.13
6.05.02.02
The nonlinear power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.14
6.05.02.02
The nonlinear power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.15
6.05.02.02
The nonlinear power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-NONLINEAR.16
6.05.02.02
The nonlinear power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-NONLINEAR.17
6.05.02.02
The nonlinear power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.18
6.05.02.02
The nonlinear power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-NONLINEAR.19
6.05.02.02
The nonlinear power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-NONLINEAR.20
6.05.02.02
The nonlinear power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-OCTUPOLE

P-HSR-PS-OCTUPOLE.1
6.05.02.02
The magnet model being powered by the power supply is octupole.
03/25/2025
Reviewed
FALSE

P-HSR-PS-OCTUPOLE.2
6.05.02.02
The octupole power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-OCTUPOLE.3
6.05.02.02
The octupole power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 20 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-OCTUPOLE.4
6.05.02.02
The octupole power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-OCTUPOLE.5
6.05.02.02
The octupole power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-OCTUPOLE.6
6.05.02.02
The octupole power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.7
6.05.02.02
The octupole power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-OCTUPOLE.8
6.05.02.02
The octupole power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.9
6.05.02.02
The octupole power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.10
6.05.02.02
The octupole power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.11
6.05.02.02
The octupole power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.12
6.05.02.02
The octupole power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.13
6.05.02.02
The octupole power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.14
6.05.02.02
The octupole power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.15
6.05.02.02
The octupole power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-OCTUPOLE.16
6.05.02.02
The octupole power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-OCTUPOLE.17
6.05.02.02
The octupole power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.18
6.05.02.02
The octupole power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-OCTUPOLE.19
6.05.02.02
The octupole power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-OCTUPOLE.20
6.05.02.02
The octupole power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-QMAIN

P-HSR-PS-QMAIN.1
6.05.02.02
The magnet model being powered by the power supply is qmain.
03/25/2025
Reviewed
FALSE

P-HSR-PS-QMAIN.2
6.05.02.02
The qmain power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-QMAIN.3
6.05.02.02
The qmain power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 90 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-QMAIN.4
6.05.02.02
The qmain power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-QMAIN.5
6.05.02.02
The qmain power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-QMAIN.6
6.05.02.02
The qmain power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.7
6.05.02.02
The qmain power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-QMAIN.8
6.05.02.02
The qmain power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.9
6.05.02.02
The qmain power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.10
6.05.02.02
The qmain power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.11
6.05.02.02
The qmain power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.12
6.05.02.02
The qmain power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.13
6.05.02.02
The qmain power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.14
6.05.02.02
The qmain power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.15
6.05.02.02
The qmain power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-QMAIN.16
6.05.02.02
The qmain power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-QMAIN.17
6.05.02.02
The qmain power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.18
6.05.02.02
The qmain power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-QMAIN.19
6.05.02.02
The qmain power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-QMAIN.20
6.05.02.02
The qmain power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-ROT

P-HSR-PS-ROT.1
6.05.02.02
The magnet model being powered by the power supply is rot.
03/25/2025
Reviewed
FALSE

P-HSR-PS-ROT.2
6.05.02.02
The rot power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-ROT.3
6.05.02.02
The rot power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 15 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-ROT.4
6.05.02.02
The rot power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-ROT.5
6.05.02.02
The rot power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-ROT.6
6.05.02.02
The rot power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.7
6.05.02.02
The rot power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-ROT.8
6.05.02.02
The rot power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.9
6.05.02.02
The rot power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.10
6.05.02.02
The rot power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.11
6.05.02.02
The rot power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.12
6.05.02.02
The rot power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.13
6.05.02.02
The rot power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.14
6.05.02.02
The rot power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.15
6.05.02.02
The rot power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-ROT.16
6.05.02.02
The rot power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-ROT.17
6.05.02.02
The rot power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.18
6.05.02.02
The rot power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-ROT.19
6.05.02.02
The rot power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-ROT.20
6.05.02.02
The rot power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-SEXUPOLE

P-HSR-PS-SEXUPOLE.1
6.05.02.02
The magnet model being powered by the power supply is sextupole.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SEXUPOLE.2
6.05.02.02
The sextupole power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-SEXUPOLE.3
6.05.02.02
The sextupole power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 100 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SEXUPOLE.4
6.05.02.02
The sextupole power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SEXUPOLE.5
6.05.02.02
The sextupole power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SEXUPOLE.6
6.05.02.02
The sextupole power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.7
6.05.02.02
The sextupole power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SEXUPOLE.8
6.05.02.02
The sextupole power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.9
6.05.02.02
The sextupole power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.10
6.05.02.02
The sextupole power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.11
6.05.02.02
The sextupole power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.12
6.05.02.02
The sextupole power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.13
6.05.02.02
The sextupole power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.14
6.05.02.02
The sextupole power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.15
6.05.02.02
The sextupole power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-SEXUPOLE.16
6.05.02.02
The sextupole power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-SEXUPOLE.17
6.05.02.02
The sextupole power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.18
6.05.02.02
The sextupole power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-SEXUPOLE.19
6.05.02.02
The sextupole power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SEXUPOLE.20
6.05.02.02
The sextupole power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-SKEWQUAD

P-HSR-PS-SKEWQUAD.1
6.05.02.02
The magnet model being powered by the power supply is skewquad.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SKEWQUAD.2
6.05.02.02
The skewquad power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-SKEWQUAD.3
6.05.02.02
The skewquad power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 20 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SKEWQUAD.4
6.05.02.02
The skewquad power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SKEWQUAD.5
6.05.02.02
The skewquad power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SKEWQUAD.6
6.05.02.02
The skewquad power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.7
6.05.02.02
The skewquad power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SKEWQUAD.8
6.05.02.02
The skewquad power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.9
6.05.02.02
The skewquad power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.10
6.05.02.02
The skewquad power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.11
6.05.02.02
The skewquad power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.12
6.05.02.02
The skewquad power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.13
6.05.02.02
The skewquad power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.14
6.05.02.02
The skewquad power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.15
6.05.02.02
The skewquad power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-SKEWQUAD.16
6.05.02.02
The skewquad power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-SKEWQUAD.17
6.05.02.02
The skewquad power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.18
6.05.02.02
The skewquad power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-SKEWQUAD.19
6.05.02.02
The skewquad power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-SKEWQUAD.20
6.05.02.02
The skewquad power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-TQQ1

HSR-PS-TQQ1 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-TQQ1.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ1.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-TQQ2

HSR-PS-TQQ2 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-TQQ2.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ2.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-TQQ3

HSR-PS-TQQ3 EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-PS-TQQ3.01
6.05.02.02
The number of Independent functions on the magnets being powered shall be -
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.02
6.05.02.02
The maximum magnet string resistance to be powered shall be RHIC ohm
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.03
6.05.02.02
The maximum magnet string inductance to be powered shall be RHIC H
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.04
6.05.02.02
The magnets being powered shall be saturated RHIC Y/N
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.5
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.06
6.05.02.02
The voltage to ground of the magnet being powered shall be RHIC V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.07
6.05.02.02
The nominal current of the magnets being powered shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.08
6.05.02.02
The minimum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.09
6.05.02.02
The maximum current the PS must operate at shall be RHIC A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.10
6.05.02.02
The PS current type shall be DC (DC or AC)
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.11
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.12
6.05.02.02
The peak waveshape di/dt during ramping shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.13
6.05.02.02
The full power bandwidth required shall be RHIC
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.14
6.05.02.02
The ppm of full scale current (peak to peak) shall be TBD %
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.15
6.05.02.02
The time period for specified stability shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.16
6.05.02.02
The short term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.17
6.05.02.02
The long term stability shall be TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.18
6.05.02.02
The current setpoint resolution (min size in bits) shall be TBD bits
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.19
6.05.02.02
The synchronization required between PS's shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.20
6.05.02.02
The synchronization timing of synchronization shall be TBD s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.21
6.05.02.02
The max allowable current ripple (peak to peak) TBD A
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.22
6.05.02.02
The max current ripple frequency range (Hz) TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.23
6.05.02.02
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.24
6.05.02.02
The max voltage ripple (peak to peak) shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.25
6.05.02.02
An NMR shall be required to measure the field TBD A/s
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.26
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.27
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.28
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.29
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.30
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.31
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.32
6.05.02.02
< blank >
01/28/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.33
6.05.02.02
The current required to be shunted through the magnet shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.34
6.05.02.02
The magnet turns ratio shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.35
6.05.02.02
The terminal voltage shall be TBD V
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.36
6.05.02.02
The design shall have thermal switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.37
6.05.02.02
The thermal switch connection numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.38
6.05.02.02
The design shall have water flow switches TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.39
6.05.02.02
The water flow switch connections numbers shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.40
6.05.02.02
The design shall have access controls interlocks TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.41
6.05.02.02
The main terminals lug details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.42
6.05.02.02
The lead end indications shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.43
6.05.02.02
The lugs details for thermal switch and water switches shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.44
6.05.02.02
The lug details for the auxiliary windings shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.45
6.05.02.02
The A/B terminal labeling details shall be TBD Draw id
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.46
6.05.02.02
The magnet drawing with terminations details shall be TBD
03/25/2025
Not Applicable
FALSE

P-HSR-PS-TQQ3.47
6.05.02.02
The magnet polarity connections shall be TBD
03/25/2025
Not Applicable
FALSE

HSR-PS-TUNI300

P-HSR-PS-TUNI300.1
6.05.02.02
The magnet model being powered by the power supply is tuni300.
03/25/2025
Reviewed
FALSE

P-HSR-PS-TUNI300.2
6.05.02.02
The tuni300 power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-TUNI300.3
6.05.02.02
The tuni300 power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 22 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-TUNI300.4
6.05.02.02
The tuni300 power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-TUNI300.5
6.05.02.02
The tuni300 power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-TUNI300.6
6.05.02.02
The tuni300 power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.7
6.05.02.02
The tuni300 power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-TUNI300.8
6.05.02.02
The tuni300 power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.9
6.05.02.02
The tuni300 power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.10
6.05.02.02
The tuni300 power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.11
6.05.02.02
The tuni300 power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.12
6.05.02.02
The tuni300 power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.13
6.05.02.02
The tuni300 power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.14
6.05.02.02
The tuni300 power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.15
6.05.02.02
The tuni300 power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-TUNI300.16
6.05.02.02
The tuni300 power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-TUNI300.17
6.05.02.02
The tuni300 power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.18
6.05.02.02
The tuni300 power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-TUNI300.19
6.05.02.02
The tuni300 power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-TUNI300.20
6.05.02.02
The tuni300 power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-UNI200

P-HSR-PS-UNI200.1
6.05.02.02
The magnet model being powered by the power supply is uni200.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI200.2
6.05.02.02
The uni200 power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI200.3
6.05.02.02
The uni200 power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 15 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI200.4
6.05.02.02
The uni200 power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI200.5
6.05.02.02
The uni200 power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI200.6
6.05.02.02
The uni200 power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.7
6.05.02.02
The uni200 power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI200.8
6.05.02.02
The uni200 power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.9
6.05.02.02
The uni200 power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.10
6.05.02.02
The uni200 power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.11
6.05.02.02
The uni200 power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.12
6.05.02.02
The uni200 power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.13
6.05.02.02
The uni200 power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.14
6.05.02.02
The uni200 power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.15
6.05.02.02
The uni200 power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI200.16
6.05.02.02
The uni200 power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI200.17
6.05.02.02
The uni200 power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.18
6.05.02.02
The uni200 power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI200.19
6.05.02.02
The uni200 power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI200.20
6.05.02.02
The uni200 power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-UNI2000

P-HSR-PS-UNI2000.1
6.05.02.02
The magnet model being powered by the power supply is uni2000.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI2000.2
6.05.02.02
The uni2000 power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI2000.3
6.05.02.02
The uni2000 power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 20 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI2000.4
6.05.02.02
The uni2000 power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI2000.5
6.05.02.02
The uni2000 power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI2000.6
6.05.02.02
The uni2000 power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.7
6.05.02.02
The uni2000 power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI2000.8
6.05.02.02
The uni2000 power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.9
6.05.02.02
The uni2000 power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.10
6.05.02.02
The uni2000 power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.11
6.05.02.02
The uni2000 power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.12
6.05.02.02
The uni2000 power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.13
6.05.02.02
The uni2000 power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.14
6.05.02.02
The uni2000 power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.15
6.05.02.02
The uni2000 power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI2000.16
6.05.02.02
The uni2000 power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI2000.17
6.05.02.02
The uni2000 power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.18
6.05.02.02
The uni2000 power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI2000.19
6.05.02.02
The uni2000 power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI2000.20
6.05.02.02
The uni2000 power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-UNI300

P-HSR-PS-UNI300.1
6.05.02.02
The magnet model being powered by the power supply is uni300.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI300.2
6.05.02.02
The uni300 power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI300.3
6.05.02.02
The uni300 power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 15 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI300.4
6.05.02.02
The uni300 power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI300.5
6.05.02.02
The uni300 power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI300.6
6.05.02.02
The uni300 power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.7
6.05.02.02
The uni300 power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI300.8
6.05.02.02
The uni300 power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.9
6.05.02.02
The uni300 power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.10
6.05.02.02
The uni300 power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.11
6.05.02.02
The uni300 power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.12
6.05.02.02
The uni300 power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.13
6.05.02.02
The uni300 power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.14
6.05.02.02
The uni300 power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.15
6.05.02.02
The uni300 power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI300.16
6.05.02.02
The uni300 power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI300.17
6.05.02.02
The uni300 power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.18
6.05.02.02
The uni300 power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI300.19
6.05.02.02
The uni300 power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI300.20
6.05.02.02
The uni300 power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-UNI450

P-HSR-PS-UNI450.1
6.05.02.02
The magnet model being powered by the power supply is uni450.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI450.2
6.05.02.02
The uni450 power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI450.3
6.05.02.02
The uni450 power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 15 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI450.4
6.05.02.02
The uni450 power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI450.5
6.05.02.02
The uni450 power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI450.6
6.05.02.02
The uni450 power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.7
6.05.02.02
The uni450 power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI450.8
6.05.02.02
The uni450 power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.9
6.05.02.02
The uni450 power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.10
6.05.02.02
The uni450 power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.11
6.05.02.02
The uni450 power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.12
6.05.02.02
The uni450 power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.13
6.05.02.02
The uni450 power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.14
6.05.02.02
The uni450 power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.15
6.05.02.02
The uni450 power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI450.16
6.05.02.02
The uni450 power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI450.17
6.05.02.02
The uni450 power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.18
6.05.02.02
The uni450 power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI450.19
6.05.02.02
The uni450 power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI450.20
6.05.02.02
The uni450 power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-PS-UNI600

P-HSR-PS-UNI600.1
6.05.02.02
The magnet model being powered by the power supply is uni600.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI600.2
6.05.02.02
The uni600 power supply shall meet all requirements to deliver the magnet operational parameters defined in the Collider-Accelerator Department RHIC Configuration Manual. [Document:RHIC Configuration Manual,Nov.2006]
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI600.3
6.05.02.02
The uni600 power supply during operation shall include a ground fault protection system to limit the maximum voltage of the magnet-to-ground to less than 20 V.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI600.4
6.05.02.02
The uni600 power supply shall provide a slow ramped current.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI600.5
6.05.02.02
The uni600 power supply shall maintain a full-scale current stability of <10 ppm (RMS) over multiple hours.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI600.6
6.05.02.02
The uni600 power supply shall maintain a long-term stability (1 second to 10 hours) of TBD A/s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.7
6.05.02.02
The uni600 power supply shall provide a minimal current setpoint resolution of 16 bits.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI600.8
6.05.02.02
The uni600 power supply synchronization required between power supplies shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.9
6.05.02.02
The uni600 power supply synchronization timing of synchronization shall be TBD s.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.10
6.05.02.02
The uni600 power supply shall limit current ripple (RMS) to TBD ppm of full-scale current in the 0–1 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.11
6.05.02.02
The uni600 power supply shall limit current ripple (RMS) to TBD ppm of full scale current greater than 1kHz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.12
6.05.02.02
The uni600 power supply shall limit ripple to TBD ppm in the 1 kHz–8 kHz range.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.13
6.05.02.02
The uni600 power supply shall limit ripple in the 8 kHz–40 kHz range per the specified TBD chart.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.14
6.05.02.02
The uni600 power supply shall avoid ripple at resonant frequencies of TBD Hz.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.15
6.05.02.02
The uni600 power supply quench detection voltage tap configuration shall meet the parameters found in [voltage tap data.url].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI600.16
6.05.02.02
The uni600 power supply quench detection threshold levels shall meet the parameters found in [Thresholds.pdf].
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI600.17
6.05.02.02
The uni600 power supply peak di/dt without inducing a quench shall be TBD A/S.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.18
6.05.02.02
The uni600 power supply quench heater power rating shall be TBD W.
03/25/2025
In Process
FALSE

P-HSR-PS-UNI600.19
6.05.02.02
The uni600 power supply design shall have warm up heaters.
03/25/2025
Reviewed
FALSE

P-HSR-PS-UNI600.20
6.05.02.02
The uni600 power supply warmup heater power rating shall be warm up heater diagrams.url W.
03/25/2025
Reviewed
FALSE

HSR-VAC : HSR Vacuum System (WBS 6.05.02.03)

HSR-VAC-ARC : HSR Vacuum Arc Section (WBS 6.05.02.03)

HSR-VAC-STRAIGHT : HSR Vacuum Straight Section (WBS 6.05.02.03)

HSR-VAC-SCREENS : HSR Vacuum Beam Screen (WBS 6.05.04.01)

P-HSR-VAC-SCREENS.01
6.05.04.01
The inner layer of copper shall have a RRR greater than 50 after installation.
03/13/2025
Approved
FALSE

P-HSR-VAC-SCREENS.02
6.05.04.01
The innermost surface of the beam screen shall have a secondary electron yield (SEY) below 1.02 at the arc CQS after conditioning.
01/27/2025
Approved
FALSE

P-HSR-VAC-SCREENS.03
6.05.04.01
The innermost surface of the beam screen shall have a secondary electron yield (SEY) below 1.08 at the arc Dipoles after conditioning.
01/27/2025
Approved
FALSE

P-HSR-VAC-SCREENS.04
6.05.04.01
The overall beam screen impedance shall be less than the impedance budget as provided by accelerator physics.
01/27/2025
Approved
FALSE

P-HSR-VAC-SCREENS.05
6.05.04.01
The beam screen shall be designed to have a maximum operating temperature less than 10 (K).
03/20/2025
Approved
FALSE

P-HSR-VAC-SCREENS.06
6.05.04.01
The arc and insertion region beam screens will be designed to fit through a 68 (mm) aperture.
03/20/2025
Approved
FALSE

P-HSR-VAC-SCREENS.07
6.05.04.01
The vertical beam aperture for the arc section beam screens shall be greater than 47.5 (mm).
03/20/2025
Reviewed
FALSE

P-HSR-VAC-SCREENS.08
6.05.04.01
The horizontal beam aperture for the arc section beam screens shall be greater than 62.5 (mm).
03/20/2025
Reviewed
FALSE

P-HSR-VAC-SCREENS.09
6.05.04.01
The center shift of the horizontal beam screen aperture shall not exceed 2.5 (mm) when installed in to the dipole due to the magnet sagitta.
03/20/2025
Approved
FALSE

P-HSR-VAC-SCREENS.10
6.05.04.01
No more than 2 (mm) of stainless steel shall be exposed to the beam in order to accommodate the longitudinal weld seam.
03/20/2025
Approved
FALSE

P-HSR-VAC-SCREENS.11
6.05.04.01
The beam screen profile will be closed using a full penetration laser weld. The maximum weld protrusion on the inside of the profile shall be less than 0.2 (mm).
03/20/2025
Approved
FALSE

P-HSR-VAC-SCREENS.12
6.05.04.01
The beam screen shall be capable of conforming to the arc dipole sagitta without damage. (ref. RHIC drawing number 12010005).
01/27/2025
Approved
FALSE

P-HSR-VAC-SCREENS.13
6.05.04.01
The triplet beam screens shall be designed to fit through a TBD aperture.
03/17/2025
In Process
FALSE

P-HSR-VAC-SCREENS.14
6.05.04.01
The minimum vertical aperture for the triplet beam screens shall be greater than 90 (mm).
03/20/2025
Reviewed
FALSE

P-HSR-VAC-SCREENS.15
6.05.04.01
The minimum horizontal aperture for the triplet beam screens shall be greater than 105 (mm).
03/20/2025
Reviewed
FALSE

P-HSR-VAC-SCREENS.16
6.05.04.01
The magnetic permeability of the beam screen at 300 (K) @ 500 (Oe) magnetization shall be less than 1.005.
03/20/2025
Approved
FALSE

P-HSR-VAC-SCREENS.17
6.05.04.01
The magnetic permeability of the beam screen at 4 K @ 500 Oe magnetization shall be less than 1.02.
03/17/2025
Approved
FALSE

P-HSR-VAC-SCREENS.18
6.05.04.01
The eddy current induced effects of the beam screens inside of the gamma-transition jump quadrupoles on the same power supply shall be matched within TBD percent.
01/27/2025
In Process
FALSE

P-HSR-VAC-SCREENS.19
6.05.04.01
The beam screens and connected vacuum components shall be designed to allow degassing up to a temperature of 80 K.
01/27/2025
Approved
FALSE

P-HSR-VAC-SCREENS.20
6.05.04.01
After installation the ends of adjacent beam screens shall be aligned within 1 degree of the orbit plane.
03/13/2025
Approved
FALSE

P-HSR-VAC-SCREENS.21
6.05.04.01
All beam screen cooling tube welds shall be external to the beam vacuum space (UHV).
01/27/2025
Approved
FALSE

HSR-VAC-INTC : HSR Vacuum RF Finger Bellows (WBS 6.05.04.02)

P-HSR-VAC-INTC.01
6.05.04.02
The interconnect module shall be designed to accommodate a range of motion from -10 (mm) to 40 (mm) about the nominal install length.
03/20/2025
In Process
FALSE

P-HSR-VAC-INTC.02
6.05.04.02
The RF bridge shall be designed to allow a 3 (mm) maximum radial offset from the nominal installed position while maintaining electrical contact.
03/20/2025
In Process
FALSE

P-HSR-VAC-INTC.03
6.05.04.02
The contact force between the RF fingers and the sleeve shall be greater than 1 (N/mm) in order to maintain good electrical contact and minimize beam induced heating and impedance.
03/20/2025
In Process
FALSE

P-HSR-VAC-INTC.04
6.05.04.02
The maximum allowable installed radial offset of the installed interconnect module shall be less than 1 (mm) end to end.
03/20/2025
In Process
FALSE

P-HSR-VAC-INTC.05
6.05.04.02
The maximum allowable twist of the installed RF bellows shall be 1 degree end-to-end.
03/20/2025
In Process
FALSE

P-HSR-VAC-INTC.06
6.05.04.02
The moveable extraction flange bellows shall be designed to allow for 5.5 (mm) extension and 0.5 (mm) additional compression from the installed connection to accommodate the differential thermal growth between the magnet cold bore and the beam screen.
03/17/2025
In Process
FALSE

P-HSR-VAC-INTC.07
6.05.04.02
The moveable extraction flange assembly shall be designed to withstand a maximum torque of 70,000 (N-mm) due to magnet quench.
03/17/2025
In Process
FALSE

P-HSR-VAC-INTC.08
6.05.04.02
All copper surfaces with direct exposure to the beam in the interconnect module shall have a minimum RRR value of 10.
02/27/2025
In Process
FALSE

P-HSR-VAC-INTC.09
6.05.04.02
The interconnect module shall be designed to have a maximum operating temperature less than 40 (K).
03/20/2025
In Process
FALSE

P-HSR-VAC-INTC.10
6.05.04.02
The innermost surface of the interconnect module shall have a secondary electron yield (SEY) below 1.1 after conditioning.
02/27/2025
In Process
FALSE

P-HSR-VAC-INTC.11
6.05.04.02
The relative magnetic permeability of the interconnect module at 4 (K) @ 500 (Oe) magnetization shall be less than 1.8
03/20/2025
In Process
FALSE

P-HSR-VAC-INTC.12
6.05.04.02
The horizontal and vertical aperture of the interconnect module shall match the adjoining beam screens.
02/27/2025
In Process
FALSE

P-HSR-VAC-INTC.13
6.05.04.02
The BPM mounting side of the interconnect module shall have machined survey fiducials to survey and record the BPM position after installation.
03/17/2025
In Process
FALSE

P-HSR-VAC-INTC.14
6.05.04.02
The interconnect module shall not interfere with pre existing RHIC components.
02/27/2025
In Process
FALSE

P-HSR-VAC-INTC.15
6.05.04.02
The interconnect module design shall include an RF connection to the beam screen.
03/17/2025
In Process
FALSE

P-HSR-VAC-INTC.16
6.05.04.02
The interconnect module design shall have provisions for mounting BPMs or replace existing RHIC stripline BPMs.
03/17/2025
In Process
FALSE

P-HSR-VAC-INTC.18
6.05.04.02
The interconnect module design shall ensure the required vacuum level is achieved for all beam parameters defined in the Master Parameter Table. [Document#:EIS-SEG-RSI-005]
03/20/2025
In Process
FALSE

P-HSR-VAC-INTC.20
6.05.04.02
The interconnect module design and installation shall minimize or eliminate adding particulates to the hadron ring.
03/17/2025
In Process
FALSE

P-HSR-VAC-INTC.21
6.05.04.02
The cooling system shall be capable of removing the thermal load generated by resistive beam heating and electron cloud.
02/27/2025
In Process
FALSE

P-HSR-VAC-INTC.22
6.05.04.02
The interconnect module design shall ensure adequate electrical, mechanical, and thermal contact to applicable adjacent components.
02/27/2025
In Process
FALSE

P-HSR-VAC-INTC.23
6.05.04.02
The internal profile of the interconnect module shall be chosen to minimize the beam impedance as much as possible.
03/17/2025
In Process
FALSE

HSR-VAC-INTC-RF : HSR Vacuum Bellows RF Fingers (WBS 6.05.04.02)

HSR-VAC-BELL

HSR-VAC-BS

F-HSR-VAC-BS.01
The beam screen design shall ensure adequate vacuum level & stability for all beam parameters in the MPT [Document#:EIC-SEG-RSI-005].
04/03/2025
Approved
FALSE

F-HSR-VAC-BS.02
The screens shall reduce the average combined heat load on cryogenic system from resistive beam heating and electron cloud to 0.5 W/m or less, including the worst case of radially shifted orbit.
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.03
The cooling system shall be capable of removing the thermal load generated by resistive beam heating and electron cloud.
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.04
All beam screens shall be actively cooled to operate below 10K
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.05
The RF finger bellows shall operate at a temperature required to minimize beam heating effects.
04/03/2025
Approved
FALSE

F-HSR-VAC-BS.06
Beam screens shall not be required for the cold beam pipe of the hadron injection beamline at the 5 O'clock blue arc.
04/03/2025
In Process
FALSE

F-HSR-VAC-BS.07
Beam screens shall be designed to fit into the HSR round cold beam pipes in all seven HSR arcs.
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.08
Beam screens shall be designed to fit into the cold mass interconnect.
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.09
The impedance of the screen design, including the screen with RF finger bellows at the cold mass interconnects shall not exceed the the global impedance budget which has been defined by approved by beam physics .
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.10
The beam screens shall be designed to be mechanically resistant to eddy-current forces resulting from a magnet quench.
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.11
The beam screen design shall be compatible with the transition-crossing jump function.
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.12
The beam screen fabrication and installation shall be conducted such that the installation process minimizes or eliminates adding particulates to the hadron ring.
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.13
All beam screens shall be designed to be removable without negative impact to any HSR components.
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.14
The innermost surface of the RF finger bellows shall suppress electron secondary emission yield (SEY).
04/02/2025
Approved
FALSE

F-HSR-VAC-BS.15
The RF finger bellows shall not interfere with the existing process and magnet bus lines (anti-squirm can)
04/02/2025
Approved
FALSE

HSR-VAC-CRYOMOD

P-HSR-VAC-CRYOMOD.01
6.05.04.04
The heat load from the ACBS components to the cold bore during the 80 (K) degassing shall be less than 60 (W) per cooling zone.
03/20/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.02
6.05.04.04
The ACBS and extraction piping shall meet the B31.3 cryogenic process piping requirements given the following criteria for pressure, temperature and stress as identified in requirements P-HSR-VAC-CRYOMOD.02.0X.
04/10/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.02.01
6.05.04.04
The Max Allowable External Working Pressure (MAEWP) shall be 1 (atm) external at 322 (K).
04/09/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.02.02
6.05.04.04
The Minimum Design Metal Temperature (MDMT) shall be 4 (K) at 18.8 (bar).
04/09/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.02.03
6.05.04.04
The Max Allowable Working Pressure (MAWP) shall be 18.8 (bar) at 322 (K).
04/09/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.02.04
6.05.04.04
The ACBS Heater Piping Pressure and Flexibility (HPPF) shall be 18.8 (bar).
04/09/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.03
6.05.04.04
All ACBS piping shall be pressure tested to 110% design pressure of 20.7 (bar) at 300 (K).
04/01/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.04
6.05.04.04
The ACBS heater shall be capable of providing sufficient power to achieve the required 80 (K) degassing temperature.
04/01/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.05
6.05.04.04
The ACBS cooling circuit control valve shall be able to regulate the coolant flow between 0 and 2.5 (grams/sec).
04/01/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.06
6.05.04.04
The ACBS cooling and heater circuit must be compatible with the existing RHIC cryogenic system.
04/01/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.07
6.05.04.04
The ACBS and extraction piping shall meet the B31.3 cryogenic process piping requirements given the following criteria for fatigue as identified in requirement P-HSR-VAC-CRYOMOD.07.0X..
04/10/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.07.01
6.05.04.04
The thermal fatigue load shall be 120 cycles consisting of 4 cycles per year over 30 years.
04/09/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.07.02
6.05.04.04
The pressure fatigue load shall be 3,000 cycles at normal operating pressure of 4 (atm) consisting of 100 cycles per year over 30 years.
04/09/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.07.03
6.05.04.04
The design fatigue load (pressure test and quenches) shall be 240 cycles at 18.6 (atm) consisting of 8 cycles per year over 30 years.
04/09/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.08
6.05.04.04
The tubing supports shall be properly placed to keep resonance modes greater than 15 (Hz).
04/09/2025
Reviewed
FALSE

P-HSR-VAC-CRYOMOD.09
6.05.04.04
The ACBS cryogenic piping and component welds shall be helium leaked checked to less than 2 x 10-10 std cc (He/sec)
04/01/2025
Reviewed
FALSE

HSR-VAC-CYROMOD : HSR Vacuum RF Cyrostat Modifications

HSR-INJ : HSR Hadron Ring Injection System (WBS 6.05.03)

F-HSR-INJ.08.01
6.05.03
The HSR injection line magnets excluding the induction septum shall provide a half physical aperture greater than 6σ for the injected beam.
04/03/2025
Approved
FALSE

F-HSR-INJ.08.02
6.05.03
The HSR induction septum shall provide a half physical aperture greater than 5σ for the injected beam.
04/03/2025
Approved
FALSE

F-HSR-INJ.08.03
6.05.03
The HSR induction septum shall provide a half physical aperture greater than 6σ for the circulating beam.
04/03/2025
Approved
FALSE

HSR-INJ EXTERNALS
Requirements who's parents are in other sub-systems.

F-HSR-INJ.01
6.05.03
The HSR injection system shall utilize the existing RHIC injector chain upstream of the RHIC-ATR D26 Dipole magnet with no modifications.
04/03/2025
In Process
FALSE

F-HSR-INJ.02
6.05.03
The HSR injection system, consisting of the transport beamline, septum magnet and injection kickers, shall be capable of transporting a maximum beam rigidity of 81.12Tm from the transport line to IR4 central area and injecting it into the HSR.
04/03/2025
Approved
FALSE

F-HSR-INJ.03
6.05.03
The HSR Injection System design shall use a warm transport line in arc 6-4 as continuation of the Injection line to transport the hadron beam to the injection system located in IR4.
01/27/2025
Approved
FALSE

F-HSR-INJ.04
6.05.03
The HSR injection transport beamline shall be able to transport polarized beam with less than 5% polarization loss.
04/03/2025
Approved
FALSE

F-HSR-INJ.05
6.05.03
The HSR injection system shall be able to inject all beam species with less than 5% beam emittance increase.
01/27/2025
Approved
FALSE

F-HSR-INJ.06
6.05.03
The HSR injection system shall be able to fill the HSR with 290 consecutive bunches without interruption.
01/27/2025
Approved
FALSE

F-HSR-INJ.07
6.05.03
The HSR injection system shall be able to fill the HSR with one(1) bunch per AGS cycle for polarized proton, two(2) bunches per AGS cycle for ion beams.
01/27/2025
Approved
FALSE

F-HSR-INJ.08
6.05.03
The HSR injection system transfer line shall provide the following physical aperture:
04/03/2025
Approved
FALSE

F-HSR-INJ.09
6.05.03
The operational availability design target for the HSR Injection System shall be consistent with the operational availability target for the overall EIC as set forth in Electron-Ion Collider Global Requirements, [Document: EIC-ORG-PLN-010]
04/04/2025
Approved
FALSE

F-HSR-INJ.10
6.05.03
The HSR Injection system transport line shall be modified to add septum magnets in the Q3-Q4 warm straight section of the HSR on 4 o’clock side of the IR4 for hadron beam transfer into the HSR beam pipe.
04/03/2025
Approved
FALSE

HSR-INJ-MAG : HSR Hadron Ring Injection Magnets (WBS 6.05.03.01)

HSR-INJ-MAG-CH : HSR Injector Magnet DVERT_1 (WBS 6.05.03.01)

P-HSR-INJ-MAG-CH.01.01
6.05.03.01
The magnet shall be a single function Horizontal Dipole corrector with a Vertical field direction.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation , Not needed?.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.01.06
6.05.03.01
The physical magnet length shall be shall be shall be TBD(m)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CH.01.10
6.05.03.01
The magnet bore gap and width shall be TBD(mm)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CH.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CH.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CH.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-CH.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CH.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CH.02.01
6.05.03.01
The Integrated Dipole Field B Shall be =TBD (T.m)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CH.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-CH.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.01
6.05.03.01
b1 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.02
6.05.03.01
b2 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.03
6.05.03.01
b3 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.04
6.05.03.01
b4 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.05
6.05.03.01
b5 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.06
6.05.03.01
b6 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.07
6.05.03.01
b7 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.08
6.05.03.01
b8 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.09
6.05.03.01
b9 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.10
6.05.03.01
b10 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.11
6.05.03.01
b11 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.12
6.05.03.01
b12 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.13
6.05.03.01
b13 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.14
6.05.03.01
b14 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.15
6.05.03.01
b15 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CH.03.03.16
6.05.03.01
b16 <(+\-)10
02/24/2025
Approved
FALSE

HSR-INJ-MAG-CV : HSR Injector Magnet Ver Corr (WBS 6.05.03.01)

P-HSR-INJ-MAG-CV.01.01
6.05.03.01
The magnet shall be a single function Vertical Dipole corrector with a Horizontal field direction.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation , Not needed?.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.01.06
6.05.03.01
The physical magnet length shall be shall be shall be TBD(m)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CV.01.10
6.05.03.01
The magnet bore gap and width shall be TBD(mm)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CV.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CV.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CV.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-CV.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CV.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CV.02.01
6.05.03.01
The Integrated Dipole Field B Shall be =TBD (T.m)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-CV.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-CV.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.01
6.05.03.01
b1 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.02
6.05.03.01
b2 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.03
6.05.03.01
b3 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.04
6.05.03.01
b4 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.05
6.05.03.01
b5 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.06
6.05.03.01
b6 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.07
6.05.03.01
b7 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.08
6.05.03.01
b8 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.09
6.05.03.01
b9 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.10
6.05.03.01
b10 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.11
6.05.03.01
b11 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.12
6.05.03.01
b12 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.13
6.05.03.01
b13 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.14
6.05.03.01
b14 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.15
6.05.03.01
b15 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-CV.03.03.16
6.05.03.01
b16 <(+\-)10
02/24/2025
Approved
FALSE

HSR-INJ-MAG-D1 : HSR Injector Magnet D1 (WBS 6.05.03.01)

P-HSR-INJ-MAG-D1.01.01
6.05.03.01
The magnet shall be a single function Dipole with a vertical field direction.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation , Not needed?.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 2.95(m)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.01.10
6.05.03.01
The magnet bore gap and width shall be TBD(mm)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D1.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D1.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D1.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-D1.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D1.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D1.02.01
6.05.03.01
The Integrated Dipole Field B Shall be =3.21(T.m)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-D1.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.01
6.05.03.01
b1 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.02
6.05.03.01
b2 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.03
6.05.03.01
b3 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.04
6.05.03.01
b4 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.05
6.05.03.01
b5 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.06
6.05.03.01
b6 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.07
6.05.03.01
b7 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.08
6.05.03.01
b8 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.09
6.05.03.01
b9 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.10
6.05.03.01
b10 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.11
6.05.03.01
b11 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.12
6.05.03.01
b12 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.13
6.05.03.01
b13 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.14
6.05.03.01
b14 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.15
6.05.03.01
b15 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D1.03.03.16
6.05.03.01
b16 <(+\-)10
02/24/2025
Approved
FALSE

HSR-INJ-MAG-D2 : HSR Injector Magnet D2 (WBS 6.05.03.01)

P-HSR-INJ-MAG-D2.01.01
6.05.03.01
The magnet shall be a single function Dipole with a vertical field direction.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation , Not needed?.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 3.66(m)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.01.10
6.05.03.01
The magnet bore gap and width shall be TBD(mm)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D2.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D2.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D2.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-D2.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.02.01
6.05.03.01
The Integrated Dipole Field B Shall be =3.95(T.m)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-D2.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.01
6.05.03.01
b1 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.02
6.05.03.01
b2 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.03
6.05.03.01
b3 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.04
6.05.03.01
b4 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.05
6.05.03.01
b5 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.06
6.05.03.01
b6 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.07
6.05.03.01
b7 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.08
6.05.03.01
b8 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.09
6.05.03.01
b9 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.10
6.05.03.01
b10 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.11
6.05.03.01
b11 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.12
6.05.03.01
b12 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.13
6.05.03.01
b13 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.14
6.05.03.01
b14 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.15
6.05.03.01
b15 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D2.03.03.16
6.05.03.01
b16 <(+\-)10
02/24/2025
Approved
FALSE

HSR-INJ-MAG-D3 : HSR Injector Magnet D3 (WBS 6.05.03.01)

P-HSR-INJ-MAG-D3.01.01
6.05.03.01
The magnet shall be a single function Dipole with a Horizontal field direction.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation , Not needed?.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 1.(m)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.01.10
6.05.03.01
The magnet bore gap and width shall be TBD(mm)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D3.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D3.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D3.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-D3.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D3.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.02.01
6.05.03.01
The Integrated Dipole Field B Shall be =0.16(T.m)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-D3.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.01
6.05.03.01
b1 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.02
6.05.03.01
b2 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.03
6.05.03.01
b3 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.04
6.05.03.01
b4 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.05
6.05.03.01
b5 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.06
6.05.03.01
b6 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.07
6.05.03.01
b7 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.08
6.05.03.01
b8 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.09
6.05.03.01
b9 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.10
6.05.03.01
b10 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.11
6.05.03.01
b11 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.12
6.05.03.01
b12 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.13
6.05.03.01
b13 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.14
6.05.03.01
b14 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.15
6.05.03.01
b15 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D3.03.03.16
6.05.03.01
b16 <(+\-)10
02/24/2025
Approved
FALSE

HSR-INJ-MAG-D4 : HSR Injector Magnet D4 (WBS 6.05.03.01)

P-HSR-INJ-MAG-D4.01.01
6.05.03.01
The magnet shall be a single function Dipole with a Vertical field direction.
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation , Not needed?.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 2(m)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.01.10
6.05.03.01
The magnet bore gap and width shall be TBD(mm)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D4.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D4.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D4.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-D4.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D4.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-D4.02.01
6.05.03.01
The Integrated Dipole Field B Shall be =2.47(T.m)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-D4.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.01
6.05.03.01
b1 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.02
6.05.03.01
b2 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.03
6.05.03.01
b3 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.04
6.05.03.01
b4 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.05
6.05.03.01
b5 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.06
6.05.03.01
b6 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.07
6.05.03.01
b7 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.08
6.05.03.01
b8 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.09
6.05.03.01
b9 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.10
6.05.03.01
b10 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.11
6.05.03.01
b11 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.12
6.05.03.01
b12 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.13
6.05.03.01
b13 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.14
6.05.03.01
b14 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.15
6.05.03.01
b15 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-D4.03.03.16
6.05.03.01
b16 <(+\-)10
02/24/2025
Approved
FALSE

HSR-INJ-MAG-DCSEPT : HSR Injector Magnet DC Septum (WBS 6.05.03.01)

HSR-INJ-MAG-INDSEPT : HSR Injector Magnet Induction Septum (WBS 6.05.03.01)

HSR-INJ-MAG-Q1 : HSR Injector Magnet Q2 (WBS 6.05.03.01)

P-HSR-INJ-MAG-Q1.01.01
6.05.03.01
The magnet shall be a single function Quadrupole with a normal field direction.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q1.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation , Not needed?.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q1.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 0.6(m)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.01.09
6.05.03.01
The magnet pole tip radius shall be 40(mm)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-Q1.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q1.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q1.02.02
6.05.03.01
The Integrated Gradient Field G Shall be =27.46(T)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q1.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X=+/-50 (um) Displacement in Y=+/-50 (um) Displacement in Z=+/-50 (um)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q1.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5 (mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q1.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-Q1.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is 25mm
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.02
6.05.03.01
The field quality shall be measured at the maximum field value (Current 412A)
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03
6.05.03.01
The magnet shall have the following Multipole content
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.01
6.05.03.01
-
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.02
6.05.03.01
b2 = 10000
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.03
6.05.03.01
b3 < (+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.04
6.05.03.01
-0.45 < b4 < 0.25
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.05
6.05.03.01
b5 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.06
6.05.03.01
b6 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.07
6.05.03.01
b7 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.08
6.05.03.01
b8 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.09
6.05.03.01
b9 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.10
6.05.03.01
b10 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.11
6.05.03.01
b11 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.12
6.05.03.01
b12 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.13
6.05.03.01
b13 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.14
6.05.03.01
b14 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.15
6.05.03.01
b15 <(+/-)1
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q1.03.03.16
6.05.03.01
b16 <(+/-)1
03/06/2025
Reviewed
FALSE

HSR-INJ-MAG-Q2 : HSR Injector Magnet Q2 (WBS 6.05.03.01)

P-HSR-INJ-MAG-Q2.01.01
6.05.03.01
The magnet shall be a single function Quadrupole with a normal field direction.
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q2.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation , Not needed?.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 0.73(m)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.01.09
6.05.03.01
The magnet pole tip radius shall be TBD(mm)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q2.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q2.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q2.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-Q2.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.02.02
6.05.03.01
The Integrated Gradient Field G Shall be =16.77(T)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-Q2.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.01
6.05.03.01
b1 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.02
6.05.03.01
b2 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.03
6.05.03.01
b3 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.04
6.05.03.01
b4 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.05
6.05.03.01
b5 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.06
6.05.03.01
b6 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.07
6.05.03.01
b7 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.08
6.05.03.01
b8 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.09
6.05.03.01
b9 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.10
6.05.03.01
b10 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.11
6.05.03.01
b11 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.12
6.05.03.01
b12 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.13
6.05.03.01
b13 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.14
6.05.03.01
b14 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.15
6.05.03.01
b15 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q2.03.03.16
6.05.03.01
b16 <(+\-)10
02/24/2025
Approved
FALSE

HSR-INJ-MAG-Q3 : HSR Injector Magnet Q3 (WBS 6.05.03.01)

P-HSR-INJ-MAG-Q3.01.01
6.05.03.01
The magnet shall be a single function Quadrupole with a normal field direction.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation , Not needed?.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 0.74(m)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.01.09
6.05.03.01
The magnet pole tip radius shall be TBD(mm)
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q3.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/06/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q3.01.11.01
6.05.03.01
Defines the magnet requirements to fit within an envelope volume. (Add Cylinder, Box dimensions) TBD
02/24/2025
Reviewed
FALSE

P-HSR-INJ-MAG-Q3.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-Q3.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.02.02
6.05.03.01
The Integrated Gradient Field G Shall be =30.25(T)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/06/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-Q3.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured is
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.01
6.05.03.01
b1 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.02
6.05.03.01
b2 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.03
6.05.03.01
b3 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.04
6.05.03.01
b4 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.05
6.05.03.01
b5 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.06
6.05.03.01
b6 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.07
6.05.03.01
b7 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.08
6.05.03.01
b8 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.09
6.05.03.01
b9 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.10
6.05.03.01
b10 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.11
6.05.03.01
b11 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.12
6.05.03.01
b12 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.13
6.05.03.01
b13 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.14
6.05.03.01
b14 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.15
6.05.03.01
b15 <(+\-)10
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-Q3.03.03.16
6.05.03.01
b16 <(+\-)10
02/24/2025
Approved
FALSE

HSR-INJ-MAG-QD1 : HSR Injector Magnet QD1 (WBS 6.05.03.01)

P-HSR-INJ-MAG-QD1.01.01
6.05.03.01
The magnet shall be a combined function magnet with a Normal Quadrupole field and a vertical Dipole field.
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-QD1.01.05
6.05.03.01
The magnet shall be designed to have a splitable pole for Vacuum beam pipe installation, Is this needed? TBD.
03/05/2025
In Process
FALSE

P-HSR-INJ-MAG-QD1.01.06
6.05.03.01
The physical magnet length shall be shall be shall be 3.66(m)
03/05/2025
Approved
FALSE

P-HSR-INJ-MAG-QD1.01.10
6.05.03.01
The magnet bore gap shall have a A nominal gap of 32(mm) in the centre of the magnet pole ranging from 29(m) at the inner Radius to 39(mm) at the outer radius. A pole width of 160(mm)
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.01.11.00
6.05.03.01
The magnet shall be designed to fit within the following constraints:
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.01.11.01
6.05.03.01
Defines the magnet requirements to fit within the following rectangular volume: dx<594(mm) dy<340(mm) dz<3997(mm) (Z is along the beam axis)
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.01.11.02.00
6.05.03.01
The final magnet assembly position and alignment values with respect to the nominal beam position and axis shall be within the following limits: (Note: Z is along the beam axis)
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-QD1.01.11.02.01
6.05.03.01
The magnet install center displacment (wrt the nominal magnet center position) Displacment in dX=+/-150(um) Displacment in dY=+/-150(um) Displacment in dZ= +/-150(um)
03/05/2025
Approved
FALSE

P-HSR-INJ-MAG-QD1.01.11.02.02
6.05.03.01
Magnet install rotational alignment (wrt the nominal beam Axis) Rotational about X=+/-0.5 (mRad) Rotational about Y=+/-0.5 (mRad) Rotational about Z=+/-0.5 (mRad)
03/05/2025
Approved
FALSE

P-HSR-INJ-MAG-QD1.02.01
6.05.03.01
The Integrated Dipole Field B Shall be =1.83(T.m)
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.02.02
6.05.03.01
The Integrated Gradient Field G Shall be =5.33(T)
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.02.07.01.00
6.05.03.01
The field alignment within the magnet, position and alignment values shall be within the following tolerance limits: (Note: Z is along the beam axis)
02/24/2025
Approved
FALSE

P-HSR-INJ-MAG-QD1.02.07.01.01
6.05.03.01
Field center displacement (wrt the physical magnet center) Displacement in X= +/-150 (um) Displacement in Y= +/-150 (um) Displacement in Z= +/-150 (um)
03/05/2025
Approved
FALSE

P-HSR-INJ-MAG-QD1.02.07.01.02
6.05.03.01
Field rotational alignment (wrt to the physical magnets primary axis X,Y,Z) Rotational about X=+/-0.5(mrad) Rotational about Y=+/-0.5(mrad) Rotational about Z=+/-0.5(mrad)
03/05/2025
Approved
FALSE

P-HSR-INJ-MAG-QD1.03.00
6.05.03.01
The magnet shall be designed to meet the following field quality\multipole requirements.
02/17/2025
Not Applicable
FALSE

P-HSR-INJ-MAG-QD1.03.01
6.05.03.01
The harmonic reference radius at which the field quality shall be measured is 50(mm)
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.02
6.05.03.01
The field (Bref) or design energy for which the field quality shall be measured at is 1.55(T)
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03
6.05.03.01
The magnet shall have the following Multipole content or dB/B within the specified measurement volumes
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.01
6.05.03.01
b1 <(+\-)2
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.02
6.05.03.01
b2 <(+\-)30
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.03
6.05.03.01
b3 <(+\-)0.3
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.04
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.05
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.06
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.07
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.08
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.09
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.10
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.11
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.12
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.13
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.14
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.15
6.05.03.01
-
03/05/2025
Reviewed
FALSE

P-HSR-INJ-MAG-QD1.03.03.16
6.05.03.01
-
03/05/2025
Reviewed
FALSE

HSR-INJ-PS : HSR Hadron Ring Injection Power Supplys (WBS 6.05.03.02)

HSR-INJ-PS-CH : HSR Injector Power supply Hor Corr (WBS 6.05.03.02)

P-HSR-INJ-PS-CH.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.11
6.05.03.02
The PS AC waveshape required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.13
6.05.03.02
The full power bandwidth required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.15
6.05.03.02
The time period for specified stability shall be TBD s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.16
6.05.03.02
The short term stability shall be TBD A/s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CH.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.34
6.05.03.02
The magnet turns ratio shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.35
6.05.03.02
The terminal voltage shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CH.36
6.05.03.02
The design shall have thermal switches TBD
02/17/2025
In Process
FALSE

HSR-INJ-PS-CV : HSR Injector Power supply Vert Corr (WBS 6.05.03.02)

P-HSR-INJ-PS-CV.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.11
6.05.03.02
The PS AC waveshape required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.13
6.05.03.02
The full power bandwidth required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.15
6.05.03.02
The time period for specified stability shall be TBD s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.16
6.05.03.02
The short term stability shall be TBD A/s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-CV.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.34
6.05.03.02
The magnet turns ratio shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.35
6.05.03.02
The terminal voltage shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-CV.36
6.05.03.02
The design shall have thermal switches TBD
02/17/2025
In Process
FALSE

HSR-INJ-PS-D1 : HSR Injector Power supply D1 (WBS 6.05.03.02)

P-HSR-INJ-PS-D1.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.11
6.05.03.02
The PS AC waveshape required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.13
6.05.03.02
The full power bandwidth required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.15
6.05.03.02
The time period for specified stability shall be TBD s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.16
6.05.03.02
The short term stability shall be TBD A/s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D1.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.34
6.05.03.02
The magnet turns ratio shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.35
6.05.03.02
The terminal voltage shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D1.36
6.05.03.02
The design shall have thermal switches TBD
01/27/2025
In Process
FALSE

HSR-INJ-PS-D2 : HSR Injector Power supply D2 (WBS 6.05.03.02)

P-HSR-INJ-PS-D2.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.11
6.05.03.02
The PS AC waveshape required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.13
6.05.03.02
The full power bandwidth required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.15
6.05.03.02
The time period for specified stability shall be TBD s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.16
6.05.03.02
The short term stability shall be TBD A/s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D2.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.34
6.05.03.02
The magnet turns ratio shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.35
6.05.03.02
The terminal voltage shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D2.36
6.05.03.02
The design shall have thermal switches TBD
01/27/2025
In Process
FALSE

HSR-INJ-PS-D3 : HSR Injector Power supply D3 (WBS 6.05.03.02)

P-HSR-INJ-PS-D3.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.11
6.05.03.02
The PS AC waveshape required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.13
6.05.03.02
The full power bandwidth required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.15
6.05.03.02
The time period for specified stability shall be TBD s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.16
6.05.03.02
The short term stability shall be TBD A/s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D3.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.34
6.05.03.02
The magnet turns ratio shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.35
6.05.03.02
The terminal voltage shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D3.36
6.05.03.02
The design shall have thermal switches TBD
01/27/2025
In Process
FALSE

HSR-INJ-PS-D4 : HSR Injector Power supply D4 (WBS 6.05.03.02)

P-HSR-INJ-PS-D4.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.11
6.05.03.02
The PS AC waveshape required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.13
6.05.03.02
The full power bandwidth required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.15
6.05.03.02
The time period for specified stability shall be TBD s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.16
6.05.03.02
The short term stability shall be TBD A/s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-D4.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.34
6.05.03.02
The magnet turns ratio shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.35
6.05.03.02
The terminal voltage shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-D4.36
6.05.03.02
The design shall have thermal switches TBD
01/27/2025
In Process
FALSE

HSR-INJ-PS-DCSEPT : HSR Injector Power supply DC Septum (WBS 6.05.03.02)

P-HSR-INJ-PS-DCSEPT.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.11
6.05.03.02
The PS AC waveshape required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.13
6.05.03.02
The full power bandwidth required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.15
6.05.03.02
The time period for specified stability shall be TBD s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.16
6.05.03.02
The short term stability shall be TBD A/s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.34
6.05.03.02
The magnet turns ratio shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.35
6.05.03.02
The terminal voltage shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-DCSEPT.36
6.05.03.02
The design shall have thermal switches TBD
02/17/2025
In Process
FALSE

HSR-INJ-PS-INDSEPT : HSR Injector Power supply IND Septum (WBS 6.05.03.02)

P-HSR-INJ-PS-INDSEPT.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.11
6.05.03.02
The PS AC waveshape required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.13
6.05.03.02
The full power bandwidth required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.15
6.05.03.02
The time period for specified stability shall be TBD s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.16
6.05.03.02
The short term stability shall be TBD A/s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.34
6.05.03.02
The magnet turns ratio shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.35
6.05.03.02
The terminal voltage shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-INDSEPT.36
6.05.03.02
The design shall have thermal switches TBD
02/17/2025
In Process
FALSE

HSR-INJ-PS-Q1 : HSR Injector Power supply Q1 (WBS 6.05.03.02)

P-HSR-INJ-PS-Q1.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.11
6.05.03.02
The PS AC waveshape required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.13
6.05.03.02
The full power bandwidth required shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.15
6.05.03.02
The time period for specified stability shall be TBD s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.16
6.05.03.02
The short term stability shall be TBD A/s
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.34
6.05.03.02
The magnet turns ratio shall be TBD
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.35
6.05.03.02
The terminal voltage shall be TBD V
01/27/2025
In Process
FALSE

P-HSR-INJ-PS-Q1.36
6.05.03.02
The design shall have thermal switches TBD
01/27/2025
In Process
FALSE

HSR-INJ-PS-Q2 : HSR Injector Power supply Q2 (WBS 6.05.03.02)

P-HSR-INJ-PS-Q2.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.11
6.05.03.02
The PS AC waveshape required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.13
6.05.03.02
The full power bandwidth required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.15
6.05.03.02
The time period for specified stability shall be TBD s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.16
6.05.03.02
The short term stability shall be TBD A/s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.34
6.05.03.02
The magnet turns ratio shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.35
6.05.03.02
The terminal voltage shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q2.36
6.05.03.02
The design shall have thermal switches TBD
02/17/2025
In Process
FALSE

HSR-INJ-PS-Q3 : HSR Injector Power supply Q3 (WBS 6.05.03.02)

P-HSR-INJ-PS-Q3.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.11
6.05.03.02
The PS AC waveshape required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.13
6.05.03.02
The full power bandwidth required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.15
6.05.03.02
The time period for specified stability shall be TBD s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.16
6.05.03.02
The short term stability shall be TBD A/s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.34
6.05.03.02
The magnet turns ratio shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.35
6.05.03.02
The terminal voltage shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-Q3.36
6.05.03.02
The design shall have thermal switches TBD
02/17/2025
In Process
FALSE

HSR-INJ-PS-QD1 : HSR Injector Power supply QD1 (WBS 6.05.03.02)

P-HSR-INJ-PS-QD1.1
6.05.03.02
The number of Independent functions on the magnets being powered shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.2
6.05.03.02
The maximum magnet string resistance to be powered shall be TBD ohm
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.3
6.05.03.02
The maximum magnet string inductance to be powered shall be TBD H
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.6
6.05.03.02
The voltage to ground of the magnet being powered shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.11
6.05.03.02
The PS AC waveshape required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.13
6.05.03.02
The full power bandwidth required shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.15
6.05.03.02
The time period for specified stability shall be TBD s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.16
6.05.03.02
The short term stability shall be TBD A/s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.17
6.05.03.03
The long term stability shall be TBD A/s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.27
6.05.03.13
The threshold levels shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.33
6.05.03.02
The current required to be shunted through the magnet shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.34
6.05.03.02
The magnet turns ratio shall be TBD
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.35
6.05.03.02
The terminal voltage shall be TBD V
02/17/2025
In Process
FALSE

P-HSR-INJ-PS-QD1.36
6.05.03.02
The design shall have thermal switches TBD
02/17/2025
In Process
FALSE

HSR-INJ-PPD : HSR Hadron Ring Injection Pulsed Power Devices System (WBS 6.05.03.04)

HSR-INJ-PPD-MAG_SL_KICK : HSR Injector Pulsed power Stripline kicker (WBS 6.05.03.02)

P-HSR-INJ-PPD-MAG_SL_KICK.1
6.05.03.04
The kicker location shall be in the HSR IR4 straight section.
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.2
6.05.03.04
The kickers shall fit within the given slot width of TBD (m)
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.3
6.05.03.04
The kickers shall fit within the given slot length of 20 (m). (this includes the bellows length)
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.4
6.05.03.04
The kickers shall fit within the given slot heignt of TBD (m)
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.5
6.05.03.04
The number of kickers shall be 16
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.6
6.05.03.04
The kicker striplines shall maintain a minimum horizontal half aperture of TBD (cm)
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.7
6.05.03.04
The rise time shall be <9 (nS)
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.8
6.05.03.04
The fall time shall be less than <1 us
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.9
6.05.03.04
The flat top time shall be longer than 2x the transit time(~6nS) in addition to the pulse width(~25nS) through the kicker, so a flat top of longer than ~35nS is required.
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.10
6.05.03.04
The flat top repeatability shall be (+/-) 1 %
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.11
6.05.03.04
The uniformity of the flattop shall be (+/-) 1 %
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.12
6.05.03.04
The total deflecting angle for all kickers shall be 0.61 (mRad)
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.13
6.05.03.04
The burst mode rep rate spec shall be 2 pulses sepearted by 200mS every 5(S)
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.14
6.05.03.04
The maximum kicker voltage shall be +/-22000 (Volts), 44000V across both kickers.
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.15
6.05.03.04
The Kicker characteristic impedance shall 50(ohms)
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.16
6.05.03.04
The kicker shall be air cooled
03/03/2025
In Process
FALSE

P-HSR-INJ-PPD-MAG_SL_KICK.17
6.05.03.04
The jitter of the rise time between the positive and negative voltage shall be less than 2(nS)
03/03/2025
In Process
FALSE

HSR-INJ-PPD-PS_SL_KICK : HSR Injector Pulsed power Power Supply Stripline kicke (WBS 6.05.03.02)

HSR-INJ-PPD-PS_SLINE_KICK

P-HSR-INJ-PPD-PS_SLINE_KICK.1
6.05.03.02
The number of Independent functions on the stripline kickers being powered shall be TBD
03/06/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.2
6.05.03.02
The maximum strip line kicker string resistance to be powered shall be TBD ohm
03/06/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.3
6.05.03.02
The maximum strip line kicker string Inductance\Capitance to be powered shall be TBD (H\F)
03/06/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.4
6.05.03.02
The magnets being powered shall be saturated TBD Y/N
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.6
6.05.03.02
The voltage to ground of the strip line kicker being powered shall be TBD V
03/06/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.7
6.05.03.02
The nominal current of the magnets being powered shall be TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.8
6.05.03.02
The minmum current the PS must operate at shall be TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.9
6.05.03.02
The maximum current the PS must operate at shall be TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.10
6.05.03.02
The PS current type DC or AC shall be TBD DC\AC
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.11
6.05.03.02
The PS AC waveshape required shall be TBD
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.12
6.05.03.02
The peak waveshape di/dt during ramping shall be TBD
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.13
6.05.03.02
The full power bandwidth required shall be TBD
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.14
6.05.03.02
The ppm of full scale current (peak to peak) shall be TBD %
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.15
6.05.03.02
The time period for specified stability shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.16
6.05.03.02
The short term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.17
6.05.03.03
The long term stability shall be TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.18
6.05.03.04
The current setpoint resolution (min size in bits) shall be TBD bits
02/17/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.19
6.05.03.05
The synchronization required between PS's shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.20
6.05.03.06
The synchronization timing of synchronization shall be TBD s
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.21
6.05.03.07
The max allowable current ripple (peak to peak) TBD A
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.22
6.05.03.08
The max current ripple frequency range (Hz) TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.23
6.05.03.09
WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.24
6.05.03.10
The max voltage ripple (peak to peak) shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.25
6.05.03.11
An NMR shall be required to measure the field TBD A/s
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.26
6.05.03.12
The voltage tap configuration shall be TBD -
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.27
6.05.03.13
The threshold levels shall be TBD V
02/24/2025
In Process
FALSE

P-HSR-INJ-PPD-PS_SLINE_KICK.35
6.05.03.02
The terminal voltage shall be TBD V
02/24/2025
In Process
FALSE

HSR-INJ-VAC : HSR Hadron Ring Injection Vacuum System (WBS 6.05.03.04)

HSR-INJ-INST : HSR Hadron Ring Injection Instrumentation System (WBS 6.05.05.02)

F-HSR-INJ-INST.01
6.05.05.02
The HSR injection line shall have Beam instrumentation to monitor the following beam parameters: beam orbit, beam current, beam transverse sizes, beam loss rate.
04/04/2025
Approved
FALSE

F-HSR-INJ-INST.02
6.05.05.02
Beam instrumentation shall be capable of providing operational data in the injection configuration for all the species and energies given in MPT. [Document: EIC-SEG-RSI-005]
04/04/2025
Approved
FALSE

F-HSR-INJ-INST.03
6.05.05.02
The new warm transfer line from the RHIC-ATR to the HSR shall re-use existing BPMs with the same requirements as the existing RHIC-ATR BPMs.
04/04/2025
Approved
FALSE

F-HSR-INJ-INST.04
6.05.05.02
The new warm transfer line from the RHIC-ATR to the HSR shall use HSR BPM electronics for the Injection line BPMs.
04/04/2025
Approved
FALSE

F-HSR-INJ-INST.05
6.05.05.02
The new warm transfer line from the RHIC-ATR to the HSR shall re-use the existing Phosphor screen beam profile monitors with the same requirements as existing in the RHIC-ATR Phosphor screen beam profile monitors.
04/04/2025
Approved
FALSE

F-HSR-INJ-INST.06
6.05.05.02
The new warm transfer line from the RHIC-ATR to the HSR shall re-use the existing Current transformers with the same requirements as existing in the RHIC-ATR Current transformers.
04/04/2025
Approved
FALSE

F-HSR-INJ-INST.07
6.05.05.02
The new warm transfer line from the RHIC-ATR to the HSR shall re-use the existing Beam loss monitors with the same requirements as existing in the RHIC-ATR Beam loss monitors.
04/04/2025
Approved
FALSE

F-HSR-INJ-INST.08
6.05.05.02
The new warm transfer line from the RHIC-ATR to the HSR shall have strategically placed chipmunks for radiation control.
04/04/2025
Approved
FALSE

HSR-INJ-INST-BC : HSR ATR Instrumentation Beam Charge Monitor (WBS 6.05.05.02)

HSR-INJ-INST-BLM : HSR ATR Instrumentation Beam Loss Monitors (WBS 6.05.05.02)

HSR-INJ-INST-BPM : HSR ATR Instrumentation Beam Position Monitor (WBS 6.05.05.02)

HSR-INJ-INST-PM : HSR ATR Instrumentation Profile Monitor (WBS 6.05.05.02)

HSR-INJ-INST-DCCT : Injection Direct Current Current Transformer Instrumentation

HSR-INJ-INST-DMP : Injection Damping Instrumentation

HSR-INJ-INST-PSBPM : Injection Phosphor Screen Beam Profile Monitoring Instrumentation

HSR-INJ-CONT : HSR Hadron Ring Injection Controls System (WBS 6.07.02)

HSR-INJ-CNTRL

HSR-INJ-DUMP

HSR-INJ-PP : Pulsed Power

HSR-INJ-PP EXTERNALS
Requirements who's parents are in other sub-systems.

F-HSR-INJ-PP.01
6.05.03.04
The HSR injection kickers shall provide a half aperture greater than 10σ for the stored beam at Collison energies.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.02
6.05.03.04
The HSR injection kickers shall provide a half aperture greater than 7σ for the stored beam at injection energies.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.03
6.05.03.04
The HSR injection kickers shall provide a half aperture greater than 6σ for the injected beam.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.04
6.05.03.04
The HSR injection kicker system shall be able to deflect the injected beam to be on axis
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.05
6.05.03.04
The HSR injection kicker system shall be installed in the straight section of the IR4 area.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.06
6.05.03.04
The HSR injection kicker system shall be capable of single-bunch on-axis injection to fill the ring with 290 bunches.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.07
6.05.03.04
The HSR injection kicker system rise time shall be short enough so that it does not step on the previous bunch.
04/03/2025
Approved
FALSE

F-HSR-INJ-PP.08
6.05.03.04
The present RHIC injection kicker system including the Lambertson magnet and current injection kicker magnets at the 5 o’clock area shall be removed.
04/03/2025
Approved
FALSE

HSR-INST : HSR Instrumentation System (WBS 6.05.05)

HSR-INST-BPM : HSR Instrumentation Beam Position Monitor System (WBS 6.05.05.01)

HSR-INST-BPM-CRYO_CABLES : HSR Instrumentation Cryogenic Cables (WBS 6.05.05.01)

HSR-INST-BPM-CRYO_PU : HSR Instrumentation Cryogenic Beam Position Monitor Pick-ups (WBS 6.05.05.01)

P-HSR-INST-BPM-CRYO_PU.01
6.05.05.01
Existing RHIC stripline BPMs shall be shielded as they will no longer be needed in the HSR.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.02
6.05.05.01
New BPMs shall be placed in available locations as close as possible to the existing RHIC stripline BPMs.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.03
6.05.05.01
New BPMs shall be placed in new, additional locations in the straight sections approved by physics.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.04
6.05.05.01
New BPMs shall be able to operate at cold temperatures (~4.2 K) with minimal load on the cryogenic system.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.05
6.05.05.01
The new and existing BPMs shall compatibly interface with the new coated sleeves that are being added to the HSR cold vacuum pipe.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.06
6.05.05.01
All BPMs shall be dual plane (refer to TCCB)
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.07
6.05.05.01
The BPM electrical center vertical position alignment with respect to the quadrupole magnetic center shall have an absolute misalignment within +/-0.3 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.08
6.05.05.01
The BPM electrical center vertical position alignment with respect to the quadrupole magnetic center shall be known to a certainty within +/-0.300 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.09
6.05.05.01
The BPM electrical center horizontal position alignment with respect to the quadrupole magnetic center shall have an absolute misalignment within +/-0.6 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.10
6.05.05.01
The BPM electrical center horizontal position alignment with respect to the quadrupole magnetic center shall be known to a certainty within +/-0.600 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.11
6.05.05.01
At injection and ramp and before radial shift, the BPMs at all quads shall fulfill resolution requirements over the horizontal & vertical beam position range with respect to quad center of +/-5 mm.
02/13/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.12
6.05.05.01
At store and after radial shift, the BPMs at the arc focusing quads shall fulfill resolution requirements over the horizontal beam position range with respect to quad center of +/- 23 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.13
6.05.05.01
At store and after radial shift, the BPMs at the arc defocusing quads shall fulfill resolution requirements over the horizontal beam position range with respect to quad center of +/-12 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.14
6.05.05.01
At store and after radial shift, the BPMs at all quads shall fulfill resolution over the vertical beam position range wrt to quad center of +/-2 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-CRYO_PU.15
6.05.05.01
All BPMs shall be able to measure a pilot bunch of not less than 5nC.
01/27/2025
Approved
FALSE

HSR-INST-BPM-ELEC : HSR Instrumentation Beam Position Monitoring Electronics (WBS 6.05.05.01)

P-HSR-INST-BPM-ELEC.01
6.05.05.01
At injection/ramp beam parameters, the BPM electronics for the cryogenic pick-ups located in the HSR arcs (defined in this case as from-Q5-to-Q5) shall fulfill all performance requirements over the horizontal & vertical position range of +/- 5 mm.
02/13/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.02
6.05.05.01
At store beam parameters, the BPM electronics for the cryogenic pick-ups located in the HSR arcs (defined in this case as from-Q5-to-Q5) shall fulfill all performance requirements over the horizontal position range of +\- 23 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.03
6.05.05.01
At store beam parameters, the BPM electronics for the cryogenic pick-ups located in the HSR arcs (defined in this case as from-Q5-to-Q5) shall fulfill all performance requirements over the vertical position range of +\- 2 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.04
6.05.05.01
For all beam operational modes, the BPM electronics for the warm pick-ups shall fullfill all performance requirements over the horizontal & vertical beam position range of +\- 5 mm.
02/13/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.05
6.05.05.01
The BPM electronics shall have the capability to provide a measurement of a single bunch when there is a single bunch in the machine, else bunch-by-bunch measurements are not required.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.06
6.05.05.01
For 5 nC bunches at injection parameters, the BPM electronics resolution when measuring one turn orbit shall not be larger than 2 mm RMS.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.07
6.05.05.01
For 5 nC bunches at injection parameters, the BPM electronics resolution when measuring the averaged orbit over a 1 second period shall not be larger than 200 µm RMS.
02/13/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.08
6.05.05.01
For bunch charge of 5 nC and above, during spliting and bunch compression at collision energies, the BPM electronics resolution when measuring the average orbit over a 1 second period shall not be larger than 100 µm RMS
02/13/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.09
6.05.05.01
For bunch charge of 5 nC and above, post spliting and bunch compression at collision energies, the BPM electronics resolution when measuring the average orbit over a 1 second period shall not be larger than 20µm RMS
02/13/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.10
6.05.05.01
For a 44 nC bunch at injection parameters, the BPM electronics resolution when measuring one turn orbit shall not be larger than 0.2 mm RMS.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.11
6.05.05.01
For 44 nC bunch at acceleration ramp parameters, the BPM electronics resolution when measuring the averaged orbit over a 1 second period shall not be larger than 20 µm RMS.
02/13/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.12
6.05.05.01
The BPM electronics shall be capable of delivering an array of at least 1024 consecutive single-turn position measurements at a rate of 1 Hz.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.13
6.05.05.01
The BPM electronics shall be capable of delivering average orbit measurements at a continuous rate of 1 Hz.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.14
6.05.05.01
The BPM electronics shall distribute data from a subset of BPMs (Inc. Q1 & Q3) to operate the fast orbit feedback system at rate of 10 kHz.
02/13/2025
Reviewed
FALSE

P-HSR-INST-BPM-ELEC.15
6.05.05.01
The BPM electronics shall log data from a subset of BPM's (Inc. Q1 & Q3) for the fast orbit feedback system and deliver data at a rate of 1kHz.
02/13/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.16
6.05.05.01
The BPM electronics shall be able to provide average orbit measurements to a slow orbit feedback system with a data delivery rate of at least 1 Hz.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-ELEC.17
6.05.05.01
The maximum allowable BPM electronics measurement drift due to thermal variations (0.5hrs) shall be < 100 µm.
02/13/2025
Approved
FALSE

HSR-INST-BPM-SNAKE&SPINR_PU : HSR Instrumentation Cryogenic Snake & Rotator Beam Position Monitor Pick-ups (WBS 6.05.05.01)

P-HSR-INST-BPM-SNAKE&SPINR_PU.01
6.05.05.01
Existing RHIC stripline BPMs in center of Snakes and Rotators shall be replaced with new button BPMs.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-SNAKE&SPINR_PU.02
6.05.05.01
The BPMs shall be able to operate at cold temperatures (~4.2K) with a heat load less than the budgeted heat load from the cryogenic system.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-SNAKE&SPINR_PU.03
6.05.05.01
The BPMs shall compatibly interface with the new coated cold vacuum pipe of Snake and Rotators.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-SNAKE&SPINR_PU.04
6.05.05.01
The BPMs shall be able to measure both horizontal and vertical beam positions.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-SNAKE&SPINR_PU.05
6.05.05.01
The BPM mechanical centers shall be aligned relative to the magnetic centers of nearby helical magnets within at least 0.5 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-SNAKE&SPINR_PU.06
6.05.05.01
At injection, the BPMs shall fulfill the resolution requirements over the horizontal beam position range of +/-10 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-SNAKE&SPINR_PU.07
6.05.05.01
At injection, the BPMs shall fulfill the resolution requirements over the vertical beam position range of +/-30 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-SNAKE&SPINR_PU.08
6.05.05.01
At store, the BPMs shall fulfill the resolution requirements over the horizontal beam position range of +/-15 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-SNAKE&SPINR_PU.09
6.05.05.01
At store, the BPMs shall fulfill the resolution requirements of the vertical beam position over a range of +/-10 mm.
01/27/2025
Approved
FALSE

HSR-INST-BPM-WARM_PU : HSR Instrumentation Warm Beam Position Monitor Pick-ups (WBS 6.05.05.01)

P-HSR-INST-BPM-WARM_PU.01
6.05.05.01
New warm BPMs shall be added on both sides of the triplets to replace the Q1 and Q3 BPMs.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.02
6.05.05.01
New warm BPMs shall be added in IR4 injection area for adequate measurement of both injected and circulating beam.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.03
6.05.05.01
New warm BPMs shall be added in IR2 cooling section for reliable alignment of hadron and electron beam.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.04
6.05.05.01
The Q1 and Q3 cryogenic BPM pickups shall be shielded by beam screens for the triplets.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.05
6.05.05.01
All warm BPMs shall provide position measurements in both planes.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.06
6.05.05.01
The warm BPM mechanical center vertical position alignment with respect to the nearby beam element center shall be within the following range +/-2 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.07
6.05.05.01
The warm BPM mechanical center vertical position alignment with respect to the nearby beam element center shall be measured with a precision of +/- 0.1 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.08
6.05.05.01
The warm BPM mechanical center horizontal position alignment with respect to the nearby beam element center shall be within the following range +/- 2mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.09
6.05.05.01
The warm BPM mechanical center horizontal position alignment with respect to the nearby beam element center shall be measured with a precision of +/- 0.1 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.10
6.05.05.01
The relative shift induced by cryogenic cooling between BPM mechanical centers and the quadrupole centers shall not exceed 0.2 mm.
01/27/2025
Approved
FALSE

P-HSR-INST-BPM-WARM_PU.11
6.05.05.01
For all beam operational modes, the warm BPMs shall fulfill all performance requirements over the horizontal & vertical beam position range of +/- 5 mm.
02/13/2025
Approved
FALSE

HSR-INST-BBLM : HSR Instrumentation Bunch-by-Bunch Loss Monitors (WBS 6.05.05.03)

HSR-INST-BBTM : HSR Instrumentation Base-band Tune Meter System (WBS 6.05.05.03)

HSR-INST-BLM : HSR Instrumentation Beam Loss Monitors (WBS 6.05.05.03)

HSR-INST-DCCT : HSR Instrumentation Current and Charge Monitor (WBS 6.05.05.03)

F-HSR-INST-DCCT.01
The DCCT shall be capable of operating in four main EIC parameter configurations (highest average current, highest peak current, ramp configuration and injection configuration) in the HSR. Refer to the MPT [Document#:EIC-SEG-RSI-005].
04/04/2025
Approved
FALSE

P-HSR-INST-DCCT.01
6.05.05.03
The DCCT shall have an average current measurement resolution of <5 µA
02/13/2025
In Process
FALSE

P-HSR-INST-DCCT.02
6.05.05.03
The DCCT shall be located at tbd
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.03
6.05.05.03
The DCCT shall have a measurement drift tolerance (thermal effects) of ≤10-3 units?
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.04
6.05.05.03
The DCCT shall have the ability to measure the average beam current over a range of 0.390 to 1 mA
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.05
6.05.05.03
The DCCT system shall have a self calibration system
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.06
6.05.05.03
The DCCT system shall provide measurements with absolute accuracy of better than 0.2 %
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.07
6.05.05.03
The measured average current shall be provided to users at a rate of 10 Hz with an RMS noise of less than 0.1 %
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.08
6.05.05.03
The measured average current shall be archived at a rate of 1 Hz
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.09
6.05.05.03
The DCCT sensor shall be radiation resistant
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.10
6.05.05.03
The DCCT shall be able to operate in the temperature range 15-35 °C
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.11
6.05.05.03
The DCCT sensor shall be able to operate in a field of less than <.01 Gauss
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.12
6.05.05.03
The impedance of DCCT sensor shall be approved by beam physics
01/27/2025
In Process
FALSE

P-HSR-INST-DCCT.13
6.05.05.03
The DCCT shall be capable of measuring the beam lifetime
01/27/2025
In Process
FALSE

HSR-INST-FBSYS : HSR Instrumentation Global Orbit Feedback System (WBS 6.05.05.03)

HSR-INST-GAPCL : HSR Instrumentation Gap Cleaner (WBS 6.05.05.03)

HSR-INST-HTPU : HSR Instrumentation Head-tail Pick-up (WBS 6.05.05.03)

HSR-INST-INJDAMP : HSR Instrumentation Injection Damper (WBS 6.05.05.03)

HSR-INST-LBBD : HSR Instrumentation Longitudinal Bunch-by-Bunch Damper (WBS 6.05.05.03)

HSR-INST-LPM : HSR Instrumentation Longitudinal Profile Monitors (WBS 6.05.05.03)

HSR-INST-SLK : HSR Instrumentation Stripline Kicker (WBS 6.05.05.03)

HSR-INST-TBBD : HSR Instrumentation Transverse Bunch-by-Bunch Damper (WBS 6.05.05.03)

HSR-INST-TMK : HSR Instrumentation Horizontal and Vertical Tune Meter Kicker (WBS 6.05.05.03)

HSR-INST-TPM : HSR Instrumentation Transverse Profile Monitors (WBS 6.05.05.03)

F-HSR-INST-TPM.01
Transverse profiles monitors shall be strategically placed in the HSR warm sections to monitor the horizontal and vertical beam profiles with sufficient precision.
04/04/2025
Approved
FALSE

P-HSR-INST-TPM.01
6.05.05.03
The transverse profile monitors shall have the capability to produce profiles of an individual proton bunch over a bunch charge range from 5 to 44 nC.
01/27/2025
Reviewed
FALSE

P-HSR-INST-TPM.02
6.05.05.03
The transverse profile monitors shall have the capability to measure profiles of bunch trains separated by 1/3 of the HSR circumference.
01/27/2025
Reviewed
FALSE

P-HSR-INST-TPM.03
6.05.05.03
The transverse profile monitors shall provide continuous measurements with an intervals at least 30 s
01/27/2025
Reviewed
FALSE

P-HSR-INST-TPM.04
6.05.05.03
The transverse profile monitors shall have the capability to measure turn-by-turn profiles of a single bunch of protons for at least 100 turns
01/27/2025
Reviewed
FALSE

P-HSR-INST-TPM.05
6.05.05.03
For horizontal plane profile measurement from 44nC bunches to 5nC bunches, the transverse profile monitors shall have a respective resolution range of 0.5 to 1.5 mm
01/27/2025
Reviewed
FALSE

P-HSR-INST-TPM.06
6.05.05.03
For vertical plane profile measurement from 44nC bunches to 5nC bunches, the transverse profile monitors shall have a respective resolution range of 0.15 to 0.5 mm
01/27/2025
Reviewed
FALSE

P-HSR-INST-TPM.07
6.05.05.03
The horizontal transverse profile monitor, transverse measurement range shall be +/- 12 mm
01/27/2025
Reviewed
FALSE

P-HSR-INST-TPM.08
6.05.05.03
The vertical transverse profile monitor, transverse measurement range shall be +/- 12 mm
01/27/2025
Reviewed
FALSE

HSR-INST-DAMP

HSR-INST-GC

HSR-INST-HFSKOTTY

HSR-INST-LFSKOTTY

HSR-INST-TM

HSR-MPS : HSR Machine Protection System (WBS 6.06.03.01)

HSR-MPS-ABORT_BUMP : HSR Machine Protection System Bump (WBS 6.06.03.01)

HSR-MPS-ABORT_BUMP EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MPS-ABORT_BUMP.01
6.06.03.01
The location (Section) shall be tbd
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.02
6.06.03.01
The dimension in W shall be tbd (ft)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.03
6.06.03.01
The dimension in L shall be tbd (ft)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.04
6.06.03.01
The dimension in H shall be tbd (ft)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.05
6.06.03.01
The num magnets shall be tbd
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.06
6.06.03.01
The mag gap shall be tbd (cm)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.07
6.06.03.01
The rise time shall be tbd
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.08
6.06.03.01
The fall time shall be tbd
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.09
6.06.03.01
The flat top time shall be tbd (sq ft)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.10
6.06.03.01
The waveshape shall be tbd (sq ft)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.11
6.06.03.01
The flat top repeatability shall be tbd (sec)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.12
6.06.03.01
The uniformity of the flattop shall be tbd (sec)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.13
6.06.03.01
The deflecting Angle shall be tbd (sec)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.14
6.06.03.01
The rep rate spec shall be tbd
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.15
6.06.03.01
The output voltage Spec shall be tbd (Hz)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.16
6.06.03.01
The output current spec shall be tbd (Volts)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.17
6.06.03.01
The inductance with cable shall be tbd (Amps)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_BUMP.18
6.06.03.01
The cooling type shall be tbd
01/27/2025
In Process
FALSE

HSR-MPS-ABORT_KICK : HSR Machine Protection System Kicker (WBS 6.06.03.01)

HSR-MPS-ABORT_KICK EXTERNALS
Requirements who's parents are in other sub-systems.

P-HSR-MPS-ABORT_KICK.01
6.06.03.01
The number of kickers shall be 5
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.02
6.06.03.01
The Rise time shall be 900 ns
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.03
6.06.03.01
The Fall time shall be NA sec
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.04
6.06.03.01
The flat top time shall be 13 us
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.05
6.06.03.01
The waveshape shall be trap
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.06
6.06.03.01
The painting shall be horizontal
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.07
6.06.03.01
The maximum field shall be TBD T
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.08
6.06.03.01
The total deflection shall be TBD mrad
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.09
6.06.03.01
The maximum current shall be 20 kA
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.10
6.06.03.01
The maximum voltage shall be 33.3 kV
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.11
6.06.03.01
The inductance with cable shall be TBD (uH)
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.12
6.06.03.01
The Max rep rate shall be 1 pulse per minut
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.13
6.06.03.01
The flat top repeatability shall be +10 / -20 %
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.14
6.06.03.01
The flatness of flat top/pulse form shall be 0.45 mod
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.15
6.06.03.01
Beam abort kicker tbd
01/27/2025
In Process
FALSE

P-HSR-MPS-ABORT_KICK.16
6.06.03.01
The cooling type shall be water
01/27/2025
In Process
FALSE

HSR-MPS-DUMP_BLK : HSR Machine Protection System Dump Block (WBS 6.06.03.01)

HSR-MPS-ABORT

F-HSR-MPS-ABORT.01
The HSR shall contain an beam abort system to dump the beam.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.02
The HSR beam abort system shall consist of a set of kickers and a beam dump
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.03
The HSR beam abort system shall be located in the tunnel between Q3 and Q4 at 9 o'clock side of the IR10 straight section.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.04
The HSR beam abort system shall re-use a RHIC beam dump to safely absorb the energy of the stored beam in a controlled fashion.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.05
The HSR beam abort system shall receive its trigger from the HSR machine protection system.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.06
The HSR beam dump shall be capable of absorbing the entire HSR proton beam (275 GeV, 1160 bunches, 11 nC each, 3.2 MJ stored energy) as well the entire Au ion beam (110 GeV/u, 290 bunches, 25 nC each, 2 MJ stored snergy)) without sustaining permanent damage
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.07
The HSR beam dump shall be capable of absorbing the entire HSR full energy beam (proton or Au ion) every 3 hours.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.08
The HSR beam dump system must ensure reliable protection from quenches, caused by secondary particles, of Q4 SC magnet downstrean of the beam dump.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.09
Radiation shielding shall be provided as part of the HSR beam dump assembly such that the radiation on the outer surface of the beam dump does not exceed TBD after TBD beam aborts at full intensity.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.10
The HSR abort kickers shall be installed downstream of Q3 magnet at 9 o'clock side of the IR10 straight section.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.11
The rise time of the HSR abort kicker system shall not exceed 1 usec.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.12
The HSR abort kicker pulse shall remain at or near its peak value for a duration of at least 13 usec.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.13
The HSR abort kicker pulse amplitude shall be sufficiently large to deflect the beam safely into the beam dump.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.14
The rising edge of the HSR abort kicker pulse shall be synchronized with the abort gap in the HSR bunch train, such that all bunches receive a kick sufficient to deflect them into the beam dump.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.15
The number of HSR abort kicker modules shall be chosen such that the required total detection angle is provided efficiently.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.16
The design of the HSR abort kickers must be consistent with the impedance budget requirements of the HSR.
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.17
The HSR abort kicker power supply scheme shall be desing in a way to eliminate a possibility of kicker module sporadic firing (pre-fire).
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.18
The HSR horizontal half aperture for the circulating beam at the location of the beam dump shall correspond to at least 6 horizontal RMS beam sizes, based on the Au injection emittances defined in the Master Parameter Table (MPT). [Document#: EIC-SEG-RSI-005]
04/02/2025
Approved
FALSE

F-HSR-MPS-ABORT.19
The HSR vertical half aperture for the circulating beam at the location of the beam dump shall correspond to at least 6 vertical RMS beam sizes, based on the Au injection emittances defined in the Master Parameter Table (MPT). [Document#: EIC-SEG-RSI-005]
04/02/2025
Approved
FALSE

HSR-COLL : HSR Momentum Collimator System (WBS 6.06.03.02)

F-HSR-COLL.01
A set of collimation systems (horizontal, vertical and momentum) shall be included in the HSR to control detector background and provide protection to the HSR magnets.
04/03/2025
Approved
FALSE

F-HSR-COLL.02
The HSR collimation system shall be flexible enough to operate with the full range of HSR species at all energy ranges defined in the MPT.
04/02/2025
Approved
FALSE

F-HSR-COLL.03
The HSR shall have a collimation system capable of ensuring a sufficiently low background at the detector.
04/02/2025
Approved
FALSE

F-HSR-COLL.04
The HSR shall have a collimation system capable of protecting all machine elements in case of failure.
04/02/2025
Approved
FALSE

F-HSR-COLL.05
All HSR collimator stations shall be double-sided.
04/02/2025
Approved
FALSE

F-HSR-COLL.06
The HSR Collimators shall be placed at accelerator locations suitable for background reduction in all operating energy ranges.
04/03/2025
Approved
FALSE

F-HSR-COLL.07
The HSR Collimator jaws shall be independently and remotely movable over a range of 60 (mm).
04/03/2025
Approved
FALSE

F-HSR-COLL.08
The HSR Collimator jaw material shall be chosen such that the collimator jaw can absorb 275 GeV protons and 110 GeV Au ions without sustaining permanent damage.
04/03/2025
Approved
FALSE

F-HSR-COLL.09
All HSR collimator stations shall be equipped with appropriate beam loss monitors to protect the collimator jaws from excessive beam losses by aborting the beam via the Machine Protection System (MPS).
04/02/2025
Approved
FALSE

F-HSR-COLL.10
The HSR collimator jaws shall be wide enough to still be effective in the presence of beam orbit errors of 10 (mm).
04/03/2025
Approved
FALSE

F-HSR-COLL.11
The HSR collimation stations shall be designed such as to minimize their beam impedance.
04/02/2025
Approved
FALSE

F-HSR-COLL.12
The HSR collimation stations shall be designed for operation in a vacuum system with pressure in 5xE-10 (Torr) or less.
04/03/2025
Approved
FALSE

F-HSR-COLL.13
The total number of HSR collimators shall be minimized in order to keep their contribution to the accelerator impedance at a minimum.
04/02/2025
Approved
FALSE

HSR-COLL-1ST_SECDRY : HSR Momentum First Set of Secondary Collimators (WBS 6.06.03.02)

P-HSR-COLL-1ST_SECDRY.01
6.06.03.02
The HSR secondary vertical collimator shall be placed at Sector 12
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.02
6.06.03.02
The HSR secondary horizontal collimator shall be placed at Sector 12
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.03
6.06.03.02
The vertical aperture shall range from 2 to 25 mm
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.04
6.06.03.02
vertical stepsize (resolution) 10 um
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.05
6.06.03.02
The horizontal aperture shall range from 12.5 to 45 mm
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.06
6.06.03.02
The horizontal stepsize (resolution) shall be 10 um
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.07
6.06.03.02
The secondary HSR collimators shall have dual jaws.
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.08
6.06.03.02
The aperture shall be centered on the beam axis.
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.09
6.06.03.02
The duty cycle shall be steady state.
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.10
6.06.03.02
The tapered jaw slope shall be 1\10
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.11
6.06.03.02
The jaw tip length shall be 50 cm
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.12
6.06.03.02
The jaw material shall be C
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.13
6.06.03.02
The total length shall be tbd cm
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.14
6.06.03.02
The beam energy deposition shall be tbd W
01/27/2025
In Process
FALSE

P-HSR-COLL-1ST_SECDRY.15
6.06.03.02
The beam failure energy deposition shall be tbd J
01/27/2025
In Process
FALSE

HSR-COLL-2ND_SECDRY : HSR Momentum Second Set of Secondary Collimators (WBS 6.06.03.02)

P-HSR-COLL-2ND_SECDRY.01
6.06.03.02
The HSR secondary vertical collimator shall be placed at Sector 11
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.02
6.06.03.02
The HSR secondary horizontal collimator shall be placed at Sector 11
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.03
6.06.03.02
The vertical aperture shall range from 4 to 50 mm
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.04
6.06.03.02
The vertical stepsize (resolution) shall be 10 um
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.05
6.06.03.02
The horizontal aperture shall range from 8 to 30 mm
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.06
6.06.03.02
The horizontal stepsize (resolution) shall be 10 um
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.07
6.06.03.02
The secondary HSR collimators shall have dual jaws.
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.08
6.06.03.02
The aperture shall be centered on the beam axis.
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.09
6.06.03.02
The duty cycle shall be steady state.
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.10
6.06.03.02
The tapered jaw slope shall be 1\10
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.11
6.06.03.02
The jaw tip length shall be 50 cm
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.12
6.06.03.02
The jaw material shall be C
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.13
6.06.03.02
The total length shall be tbd cm
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.14
6.06.03.02
The beam energy deposition shall be tbd W
01/27/2025
In Process
FALSE

P-HSR-COLL-2ND_SECDRY.15
6.06.03.02
The beam failure energy deposition shall be tbd J
01/27/2025
In Process
FALSE

HSR-COLL-ABS : HSR Momentum Injection Absorbers (WBS 6.06.03.02)

HSR-COLL-MOM : HSR Momentum Collimator (WBS 6.06.03.02)

P-HSR-COLL-MOM.01
6.06.03.02
The HSR momentum collimator shall be horizontal.
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.02
6.06.03.02
The horizontal aperture shall have a half gap of 40 mm
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.03
6.06.03.02
The horizontal aperture shall cover a range of gap sizes min=TBD to a max=TBD mm
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.04
6.06.03.02
The horizontal stepsize (resolution) shall be 10 um
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.05
6.06.03.02
The HSR momentum collimator shall have dual jaws.
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.06
6.06.03.02
The aperture shall be centered on the beam axis.
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.07
6.06.03.02
The beam energy deposition shall be tbd W
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.08
6.06.03.02
The beam energy deposition shall be continuous
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.09
6.06.03.02
The impedance shall be less than the Impedance budget of tbd kV/pc
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.10
6.06.03.02
The tapered jaw slope shall be tbd
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.11
6.06.03.02
The beam failure energy deposition shall be 1 J
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.12
6.06.03.02
The failure thermal duty cycle shall be intermittent.
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.13
6.06.03.02
The jaw tip length shall be 100 cm
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.14
6.06.03.02
The jaw taper shall be 1\10
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.15
6.06.03.02
The jaw material shall be tbd
01/27/2025
In Process
FALSE

P-HSR-COLL-MOM.16
6.06.03.02
The total length shall be tbd cm
01/27/2025
In Process
FALSE

HSR-COLL-PRIM : HSR Momentum Primary Collimators (WBS 6.06.03.02)

P-HSR-COLL-PRIM.01
6.06.03.02
The HSR primary vertical collimator shall be placed at Sector 12
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.02
6.06.03.02
The HSR primary horizontal collimator shall be placed at Sector 12
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.03
6.06.03.02
The vertical aperture shall range from 0.9 to 20 mm
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.04
6.06.03.02
The vertical stepsize (resolution) shall be 10 um
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.05
6.06.03.02
The horizontal aperture shall range from 7 to 28 mm
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.06
6.06.03.02
The horizontal stepsize (resolution) shall be 10 um
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.07
6.06.03.02
The aperture shall be centered on the beam axis.
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.08
6.06.03.02
The duty cycle shall be steady state.
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.09
6.06.03.02
The energy deposition from synchrotron radiation shall be negligible.
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.10
6.06.03.02
The tapered jaw slope shall be 1\10
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.11
6.06.03.02
The jaw tip length shall be 50 cm
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.12
6.06.03.02
The jaw material shall be CU
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.13
6.06.03.02
The total length shall be tbd cm
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.14
6.06.03.02
The beam energy deposition shall be tbd W
01/27/2025
In Process
FALSE

P-HSR-COLL-PRIM.15
6.06.03.02
The beam failure energy deposition shall be tbd J
01/27/2025
In Process
FALSE

HSR-CONT : HSR Controls System (WBS 6.07.02)

HSR-CONT-FEEDBACK : HSR Controls System Feedback (WBS 6.07.02)

HSR-CONT-SPIN : HSR Controls System Spin Pattern (WBS 6.07.02)

HSR-RF : HSR RF System (WBS 6.08)

F-HSR-RF.01
The HSR Ring Normal Conducting RF system shall include an, h=315 system capable of capture and acceleration of all beams defined in the MPT [Document: EIC-SEG-RSI-005].
04/03/2025
Approved
FALSE

F-HSR-RF.02
The HSR Ring Normal Conducting RF system shall include an, h=630 system to perform the 1:2 bunch splitting required to produce store bunch patterns defined in the MPT [Document: EIC-SEG-RSI-005]..
04/03/2025
Approved
FALSE

F-HSR-RF.03
The HSR Ring Normal Conducting RF system shall include an, h=1260 system to perform the 2:4 bunch splitting required to produce store bunch patterns defined in the MPT [Document: EIC-SEG-RSI-005]..
04/03/2025
Approved
FALSE

F-HSR-RF.04
The HSR Ring Normal Conducting RF system shall include an h=2520 system to perform initial bunch length compression to achieve the required store bunch lengths defined in the MPT [Document: EIC-SEG-RSI-005]..
04/03/2025
Approved
FALSE

F-HSR-RF.05
The HSR Ring Super Conducting RF system shall include an, h=7560 system to perform final bunch length compression to achieve the required store bunch lengths defined in the MPT [Document: EIC-SEG-RSI-005]..
04/03/2025
Approved
FALSE

F-HSR-RF.06
Normal conducting HSR Ring RF systems shall be located in the IR 4 straight section.
04/03/2025
Approved
FALSE

F-HSR-RF.07
Superconducting HSR Ring RF systems shall be located in the IR 10 straight section.
04/03/2025
Approved
FALSE

F-HSR-RF.08
The Longitudinal Impedance Budget sum of all the longitudinal narrowband impedances from all the HSR Ring RF and Crab RF systems shall not exceed a level which compromises the machine parameters given in the MPT [Document: EIC-SEG-RSI-005]..
04/03/2025
Approved
FALSE

F-HSR-RF.09
The transverse Impedance Budget sum of all the transverse narrowband impedances of all HSR Ring RF and Crab RF systems shall not exceed a level which compromises the machine parameters given in the MPT [Document: EIC-SEG-RSI-005]..
04/03/2025
Approved
FALSE

F-HSR-RF.10
The HSR Ring RF system shall provide controls and diagnostics for all cavities and system functionality.
04/03/2025
Approved
FALSE

HSR-RF-NCRF : HSR Normal Conducting RF Systems (WBS 6.08.04.01)

HSR-RF-NCRF-TBD1 : HSR Main RF SCFCM Store2 Mode (WBS 6.08.04.01)

HSR-RF-SRF : HSR Superconducting RF Systems (WBS 6.08.05)

HSR-RF-SRF-197_Crab : HSR Main RF Capture & Accel Mode (WBS 6.08.05.04)

HSR-RF-SRF-394_Crab : HSR Main RF Split1 Mode (WBS 6.08.05.05)

HSR-RF-SRF-591_1Cell

HSR-RF-ACAV:197

P-HSR-RF-ACAV:197.01
6.08.05.08
The NCRF Cavity System shall be outfitted with flow control, thermometry, vacuum pressure, and RF instrumentation as to monitor and control all sub-systems during operation and testing.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.02.01
6.08.05.08
The NCRF Cavity System shall be designed to operate at a maximum steady state temperature of 70°C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.02.02
6.08.05.08
The NCRF Cavity System chilled water and low-conductivity water operational supply temperature range shall be 26.5 ± 3 °C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.02.03
6.08.05.08
The NCRF Cavity System chilled water and low-conductivity water operational supply pressure range shall be 6-9 bar.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.03.01
6.08.05.08
The minimum NCRF Cavity System Slow Tuner 1% range tuning cycles shall be 1,200,000 cycles.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.03.02
6.08.05.08
The minimum NCRF Cavity System Slow Tuner full range tuning cycles shall be shall be 120,000 cycles.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.03.03
6.08.05.08
The NCRF Cavity System maximum manufactured field emission at operational voltage shall be 10 Gy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.03.04
6.08.05.08
The NCRF Cavity System components that are not replaceable in-situ shall be designed with a minimum lifetime radiation tolerance of 1,000 kGy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.03.05
6.08.05.08
The NCRF Cavity System components that are replaceable in-situ shall have a minimum lifetime radiation tolerance of 1 kGy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.03.06
6.08.05.08
The NCRF Cavity System critical monitoring and control instruments that cannot be maintained in-situ shall utilize a back-up instrument.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.03.07
6.08.05.08
The NCRF Cavity System shall maximize the number of instrumentats that can be maintained and replaced in-situ.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.03.08
6.08.05.08
The NCRF Cavity System components shall be ergonomically accessible.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.04.01
6.08.05.08
The sum of all NCRF Cavity System RF longitudinal impedance (accelerator definition) shall be no greater than 180 kΩ Ghz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.04.02
6.08.05.08
The sum of all NCRF Cavity System RF horizontal impedance (accelerator definition) shall be no greater than 5 MΩ/m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.04.03
6.08.05.08
The sum of all NCRF Cavity System RF vertical impedance (accelerator definition) shall be no greater than 5 MΩ/m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.04.04
6.08.05.08
The NCRF Cavity System minimum cavity aperture radius shall be 75 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.04.05
6.08.05.08
The NCRF Cavity System maximum broadband RF power emitted from the cavity via the beampipe shall be 1 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.04.06
6.08.05.08
The NCRF Cavity System Maximum Dipole multipole content shall be 50 mT-m.
04/21/2025
In Process
FALSE

P-HSR-RF-ACAV:197.04.07
6.08.05.08
The NCRF Cavity System Maximum Quadrupole multipole content shall be 4 mT.
04/22/2025
In Process
FALSE

P-HSR-RF-ACAV:197.04.08
6.08.05.08
The NCRF Cavity System Maximum Sextuple multipole content shall be 2 T/m.
04/22/2025
In Process
FALSE

P-HSR-RF-ACAV:197.04.09
6.08.05.08
The NCRF Cavity System Maximum Octupole multipole content shall be 50 mT/m^2.
04/21/2025
In Process
FALSE

P-HSR-RF-ACAV:197.05.01
6.08.05.08
The NCRF Cavity System minimum manufactured quality factor (Qo) shall be 43,000.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.05.02
6.08.05.08
The sum of all NCRF Cavity System minimum manufactured gradients shall be 6 MV.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.05.03
6.08.05.08
The NCRF Cavity System field probe Qext range shall be (2.2 ± 0.4)e8.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.05.04
6.08.05.08
The NCRF Cavity System nominal frequency shall be 197.051 MHz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.05.05
6.08.05.08
The NCRF Cavity System FPC external quality factor shall be (4.8 ± 0.2)e4.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.05.06
6.08.05.08
The NCRF Cavity System FPC window design shall be rated to a minimum input power of 60 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.05.07
6.08.05.08
The NCRF Cavity System loop HOM Damper maximum total broadband power on each shall be 5 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.05.08
6.08.05.08
The NCRF Cavity System e-probe HOM Damper maximum total broadband power on each shall be 0.1 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.05.09
6.08.05.08
The NCRF Cavity System loop HOM Damper maximum fundamental power leakage under nominal frequency and voltage shall be 200 W.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.06.01
6.08.05.08
The NCRF Cavity System maximum vacuum shall be 1.0e-8 mbar.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.06.02
6.08.05.08
The NCRF Cavity System maximum vacuum leak rate shall be 5.0e-9 mbar L/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.07.01
6.08.05.08
The NCRF Cavity System Slow Tuner tuning range shall be -120 to +120 KHz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.07.02
6.08.05.08
The minimum NCRF Cavity System slow tuner resolution shall be 10 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.07.03
6.08.05.08
The minimum NCRF Cavity System slow tuner tuning rate shall be 1,600 Hz/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.07.04
6.08.05.08
The maximum NCRF Cavity System Slow Tuner hysteresis shall be 100 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.08.01
6.08.05.08
The NCRF Cavity System maximum Qext of the Fundamental Mode Damper shall be 500.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.08.02
6.08.05.08
The NCRF Cavity System Fundamental Mode Damper shall handle a minimum power of 20 W.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.08.03
6.08.05.08
The NCRF Cavity System Fundamental Mode Damper minimum insertion speed shall be 700 mm/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.08.04
6.08.05.08
The NCRF Cavity System Fundamental Mode Damper minimum retraction speed shall be 140 mm/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.09.01
6.08.05.08
All NCRF Cavity System surfaces accessible to workers shall be less than 60°C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.09.02
6.08.05.08
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME B31.3.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.09.03
6.08.05.08
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME BPVC.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.09.04
6.08.05.08
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASTM C1055.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.09.05
6.08.05.08
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.09.06
6.08.05.08
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70E.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.09.07
6.08.05.08
The NCRF Cavity System shall be designed and manufactured as directed by the BNL SBMS to meet all applicable safety standards as defined by API 520 & API 521.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.09.08
6.08.05.08
The NCRF Cavity System shall be designed and manufactured as directed by the BNL SBMS to meet all applicable safety standards as defined by AWS.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.01
6.08.05.08
The NCRF Cavity System full assembly maximum length shall be 0.9 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.02
6.08.05.08
The NCRF Cavity System full assembly maximum width shall be 1.9 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.03
6.08.05.08
The NCRF Cavity System full assembly maximum height (including tetrode amplifier) shall be 3.0 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.04
6.08.05.08
The distance from the NCRF Cavity System beamline to the tunnel floor shall be 1270.0 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.05
6.08.05.08
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in X shall be ± 0.7 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.06
6.08.05.08
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in Y shall be ± 0.7 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.07
6.08.05.08
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in Z shall be ± 10 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.08
6.08.05.08
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the roll shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.09
6.08.05.08
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the pitch shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.10.10
6.08.05.08
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the yaw shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.11.01
6.08.05.08
The NCRF Cavity System shall be capable of withstanding a maximum allowable vertical acceleration of 4 G.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:197.11.02
6.08.05.08
The NCRF Cavity System shall be capable of withstanding a maximum allowable lateral acceleration of 1.5 G.
04/22/2025
In Process
FALSE

P-HSR-RF-ACAV:197.11.03
6.08.05.08
The NCRF Cavity System shall be capable of withstanding a maximum allowable beamline axis acceleration of 5 G.
04/21/2025
In Process
FALSE

HSR-RF-ACAV:24

P-HSR-RF-ACAV:24.01
6.08.05.04
The NCRF Cavity System shall be outfitted with flow control, thermometry, vacuum pressure, and RF instrumentation as to monitor and control all sub-systems during operation and testing.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.02.01
6.08.05.04
The NCRF Cavity System shall be designed to operate at a maximum steady state temperature of 70°C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.02.02
6.08.05.04
The NCRF Cavity System chilled water and low-conductivity water operational supply temperature range shall be 26.5 ± 3 °C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.02.03
6.08.05.04
The NCRF Cavity System chilled water and low-conductivity water operational supply pressure range shall be 6-9 bar.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.03.01
6.08.05.04
The minimum NCRF Cavity System fast tuner lifetime shall be 20 years.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.03.02
6.08.05.04
The minimum NCRF Cavity System Slow Tuner 1% range tuning cycles shall be 1,200,000 cycles.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.03.03
6.08.05.04
The minimum NCRF Cavity System Slow Tuner full range tuning cycles shall be 120,000 cycles.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.03.04
6.08.05.04
The NCRF Cavity System maximum manufactured field emission at operational voltage shall be 10 Gy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.03.05
6.08.05.04
The NCRF Cavity System components that are not replaceable in-situ shall be designed with a minimum lifetime radiation tolerance of 1,000 kGy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.03.06
6.08.05.04
The NCRF Cavity System components that are replaceable in-situ shall have a minimum lifetime radiation tolerance of 1 kGy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.03.07
6.08.05.04
The NCRF Cavity System critical monitoring and control instruments that cannot be maintained in-situ shall utilize a back-up instrument.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.03.08
6.08.05.04
The NCRF Cavity System shall maximize the number of instrumentats that can be maintained and replaced in-situ.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.03.09
6.08.05.04
The NCRF Cavity System components shall be ergonomically accessible.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.04.01
6.08.05.04
The sum of all NCRF Cavity System RF longitudinal impedance (accelerator definition) shall be no greater than 180 kΩ Ghz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.04.02
6.08.05.04
The sum of all NCRF Cavity System RF horizontal impedance (accelerator definition) shall be no greater than 5 MΩ/m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.04.03
6.08.05.04
The sum of all NCRF Cavity System RF vertical impedance (accelerator definition) shall be no greater than 5 MΩ/m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.04.04
6.08.05.04
The NCRF Cavity System minimum cavity aperture radius shall be 75 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.04.05
6.08.05.04
The NCRF Cavity System maximum broadband RF power emitted from the cavity via the beampipe shall be 1 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.04.06
6.08.05.04
The NCRF Cavity System Maximum Dipole multipole content shall be 50 mT-m.
04/21/2025
In Process
FALSE

P-HSR-RF-ACAV:24.04.07
6.08.05.04
The NCRF Cavity System Maximum Quadrupole multipole content shall be 4 mT.
04/21/2025
In Process
FALSE

P-HSR-RF-ACAV:24.04.08
6.08.05.04
The NCRF Cavity System Maximum Sextuple multipole content shall be 2 T/m.
04/21/2025
In Process
FALSE

P-HSR-RF-ACAV:24.04.09
6.08.05.04
The NCRF Cavity System Maximum Octupole multipole content shall be 50 mT/m^2.
04/21/2025
In Process
FALSE

P-HSR-RF-ACAV:24.05.01
6.08.05.04
The NCRF Cavity System minimum manufactured quality factor (Qo) shall be 12,500.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.05.02
6.08.05.04
The sum of all NCRF Cavity System minimum manufactured gradients shall be 0.6 MV.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.05.03
6.08.05.04
The NCRF Cavity System field probe Qext range shall be (2.7 ± 0.5)e7.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.05.04
6.08.05.04
The NCRF Cavity System nominal frequency shall be 24.631 MHz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.05.05
6.08.05.04
The NCRF Cavity System FPC external quality factor shall be (7.1 ± 0.3)e3.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.05.06
6.08.05.04
The NCRF Cavity System FPC window design shall be rated to a minimum input power of 60 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.05.07
6.08.05.04
The NCRF Cavity System loop HOM Damper maximum total broadband power on each shall be 5 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.05.08
6.08.05.04
The NCRF Cavity System e-probe HOM Damper maximum total broadband power on each shall be 0.1 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.05.09
6.08.05.04
The NCRF Cavity System loop HOM Damper maximum fundamental power leakage under nominal frequency and voltage shall be 200 W.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.05.10
6.08.05.04
DELETE
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.06.01
6.08.05.04
The NCRF Cavity System maximum vacuum shall be 1.0e-8 mbar.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.06.02
6.08.05.04
The NCRF Cavity System maximum vacuum leak rate shall be 5.0e-9 mbar L/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.07.01
6.08.05.04
The NCRF Cavity System Slow Tuner tuning range shall be -160 to +40 KHz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.07.02
6.08.05.04
The minimum NCRF Cavity System slow tuner resolution shall be 10 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.07.03
6.08.05.04
The minimum NCRF Cavity System slow tuner tuning rate shall be 1600 Hz/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.07.04
6.08.05.04
The maximum NCRF Cavity System Slow Tuner hysteresis shall be 100 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.07.05
6.08.05.04
The minimum NCRF Cavity System Fast Tuner tuning range shall be 20 kHz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.07.06
6.08.05.04
The minimum NCRF Cavity System Fast Tuner resolution shall be 10 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.07.07
6.08.05.04
The minimum NCRF Cavity System Fast tuning rate shall be 10 MHz/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.07.08
6.08.05.04
The maximum NCRF Cavity System Fast Tuner hysteresis shall be 100 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.08.01
6.08.05.04
All NCRF Cavity System surfaces accessible to workers shall be less than 60°C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.08.02
6.08.05.04
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME B31.3.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.08.03
6.08.05.04
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME BPVC.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.08.04
6.08.05.04
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASTM C1055.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.08.05
6.08.05.04
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.08.06
6.08.05.04
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70E.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.08.07
6.08.05.04
The NCRF Cavity System shall be designed and manufactured as directed by the BNL SBMS to meet all applicable safety standards as defined by API 520 & API 521.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.08.08
6.08.05.04
The NCRF Cavity System shall be designed and manufactured as directed by the BNL SBMS to meet all applicable safety standards as defined by AWS.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.01
6.08.05.04
The NCRF Cavity System full assembly maximum length shall be 3.0 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.02
6.08.05.04
The NCRF Cavity System full assembly maximum width shall be 1.8 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.03
6.08.05.04
The NCRF Cavity System full assembly maximum height (including tetrode amplifier) shall be 2.3 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.04
6.08.05.04
The distance from the NCRF Cavity System beamline to the tunnel floor shall be 1270.0 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.05
6.08.05.04
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in X shall be ± 0.7 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.06
6.08.05.04
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in Y shall be ± 0.7 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.07
6.08.05.04
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in Z shall be ± 10 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.08
6.08.05.04
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the roll shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.09
6.08.05.04
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the pitch shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.09.10
6.08.05.04
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the yaw shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.10.01
6.08.05.04
The NCRF Cavity System shall be capable of withstanding a maximum allowable vertical acceleration of 4 G.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.10.02
6.08.05.04
The NCRF Cavity System shall be capable of withstanding a maximum allowable lateral acceleration of 1.5 G.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:24.10.03
6.08.05.04
The NCRF Cavity System shall be capable of withstanding a maximum allowable beamline axis acceleration of 5 G.
04/22/2025
Reviewed
FALSE

HSR-RF-ACAV:49

P-HSR-RF-ACAV:49.01
6.08.05.05
The NCRF Cavity System shall be outfitted with flow control, thermometry, vacuum pressure, and RF instrumentation as to monitor and control all sub-systems during operation and testing.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.02.01
6.08.05.05
The NCRF Cavity System shall be designed to operate at a maximum steady state temperature of 70°C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.02.02
6.08.05.05
The NCRF Cavity System chilled water and low-conductivity water operational supply temperature range shall be 26.5 ± 3°C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.02.03
6.08.05.05
The NCRF Cavity System chilled water and low-conductivity water operational supply pressure range shall be 6-9 bar.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.03.01
6.08.05.05
The minimum NCRF Cavity System Slow Tuner 1% range tuning cycles shall be 1,200,000 cycles.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.03.02
6.08.05.05
The minimum NCRF Cavity System Slow Tuner full range tuning cycles shall be shall be 120,000 cycles.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.03.03
6.08.05.05
The NCRF Cavity System maximum manufactured field emission at operational voltage shall be 10 Gy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.03.04
6.08.05.05
The NCRF Cavity System components that are not replaceable in-situ shall be designed with a minimum lifetime radiation tolerance of 1,000 kGy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.03.05
6.08.05.05
The NCRF Cavity System components that are replaceable in-situ shall have a minimum lifetime radiation tolerance of 1 kGy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.03.06
6.08.05.05
The NCRF Cavity System critical monitoring and control instruments that cannot be maintained in-situ shall utilize a back-up instrument.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.03.07
6.08.05.05
The NCRF Cavity System shall maximize the number of instrumentats that can be maintained and replaced in-situ.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.03.08
6.08.05.05
The NCRF Cavity System components shall be ergonomically accessible.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.04.01
6.08.05.05
The sum of all NCRF Cavity System RF longitudinal impedance (accelerator definition) shall be no greater than 180 kΩ Ghz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.04.02
6.08.05.05
The sum of all NCRF Cavity System RF horizontal impedance (accelerator definition) shall be no greater than 5 MΩ/m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.04.03
6.08.05.05
The sum of all NCRF Cavity System RF vertical impedance (accelerator definition) shall be no greater than 5 MΩ/m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.04.04
6.08.05.05
The NCRF Cavity System minimum cavity aperture radius shall be 75 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.04.05
6.08.05.05
The NCRF Cavity System maximum broadband RF power emitted from the cavity via the beampipe shall be 1 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.04.06
6.08.05.05
The NCRF Cavity System Maximum Dipole multipole content shall be 50 mT-m.
04/22/2025
In Process
FALSE

P-HSR-RF-ACAV:49.04.07
6.08.05.05
The NCRF Cavity System Maximum Quadrupole multipole content shall be 4 mT.
04/21/2025
In Process
FALSE

P-HSR-RF-ACAV:49.04.08
6.08.05.05
The NCRF Cavity System Maximum Sextuple multipole content shall be 2 T/m.
04/22/2025
In Process
FALSE

P-HSR-RF-ACAV:49.04.09
6.08.05.05
The NCRF Cavity System Maximum Octupole multipole content shall be 50 mT/m^2.
04/22/2025
In Process
FALSE

P-HSR-RF-ACAV:49.05.01
6.08.05.05
The NCRF Cavity System minimum manufactured quality factor (Qo) shall be 10,000.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.05.02
6.08.05.05
The sum of all NCRF Cavity System minimum manufactured gradients shall be 0.5 MV.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.05.03
6.08.05.05
The NCRF Cavity System field probe Qext range shall be (5.3 ± 1.0)e7.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.05.04
6.08.05.05
The NCRF Cavity System nominal frequency shall be 49.263 MHz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.05.05
6.08.05.05
The NCRF Cavity System FPC external quality factor shall be (4.6 ± 0.2)e3.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.05.06
6.08.05.05
The NCRF Cavity System FPC window design shall be rated to a minimum input power of 120 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.05.07
6.08.05.05
The NCRF Cavity System loop HOM Damper maximum total broadband power on each shall be 5 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.05.08
6.08.05.05
The NCRF Cavity System e-probe HOM Damper maximum total broadband power on each shall be 0.1 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.05.09
6.08.05.05
The NCRF Cavity System loop HOM Damper maximum fundamental power leakage under nominal frequency and voltage shall be 200 W.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.06.01
6.08.05.05
The NCRF Cavity System maximum vacuum shall be 1.0e-8 mbar.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.06.02
6.08.05.05
The NCRF Cavity System maximum vacuum leak rate shall be 5.0e-9 mbar L/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.07.01
6.08.05.05
The NCRF Cavity System Slow Tuner tuning range shall be -280 to +40 KHz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.07.02
6.08.05.05
The minimum NCRF Cavity System slow tuner resolution shall be 10 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.07.03
6.08.05.05
The minimum NCRF Cavity System slow tuner tuning rate shall be 1600 Hz/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.07.04
6.08.05.05
The maximum NCRF Cavity System Slow Tuner hysteresis shall be 100 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.08.01
6.08.05.05
The NCRF Cavity System maximum Qext of the Fundamental Mode Damper shall be 170.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.08.02
6.08.05.05
The NCRF Cavity System Fundamental Mode Damper shall handle a minimum power of 5 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.08.03
6.08.05.05
The NCRF Cavity System Fundamental Mode Damper minimum insertion speed shall be 1000 mm/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.08.04
6.08.05.05
The NCRF Cavity System Fundamental Mode Damper minimum retraction speed shall be 200 mm/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.09.01
6.08.05.05
All NCRF Cavity System surfaces accessible to workers shall be less than 60°C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.09.02
6.08.05.05
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME B31.3.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.09.03
6.08.05.05
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME BPVC.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.09.04
6.08.05.05
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASTM C1055.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.09.05
6.08.05.05
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.09.06
6.08.05.05
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70E.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.09.07
6.08.05.05
The NCRF Cavity System shall be designed and manufactured as directed by the BNL SBMS to meet all applicable safety standards as defined by API 520 & API 521.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.09.08
6.08.05.05
The NCRF Cavity System shall be designed and manufactured as directed by the BNL SBMS to meet all applicable safety standards as defined by AWS.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.01
6.08.05.05
The NCRF Cavity System full assembly maximum length shall be 1.5 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.02
6.08.05.05
The NCRF Cavity System full assembly maximum width shall be 1.9 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.03
6.08.05.05
The NCRF Cavity System full assembly maximum height shall be 1.9 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.04
6.08.05.05
The distance from the NCRF Cavity System beamline to the tunnel floor shall be 1270.0 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.05
6.08.05.05
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in X shall be ± 0.7 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.06
6.08.05.05
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in Y shall be ± 0.7 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.07
6.08.05.05
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in Z shall be ± 10 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.08
6.08.05.05
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the roll shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.09
6.08.05.05
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the pitch shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.10.10
6.08.05.05
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the yaw shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.11.01
6.08.05.05
The NCRF Cavity System shall be capable of withstanding a maximum allowable vertical acceleration of 4 G.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.11.02
6.08.05.05
The NCRF Cavity System shall be capable of withstanding a maximum allowable lateral acceleration of 1.5 G.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:49.11.03
6.08.05.05
The NCRF Cavity System shall be capable of withstanding a maximum allowable beamline axis acceleration of 5 G.
04/22/2025
Reviewed
FALSE

HSR-RF-ACAV:591S

P-HSR-RF-ACAV:591S.01
6.08.04.01
The SRF Cryomodule shall be outfitted with flow control, thermometry, pressure, and RF instrumentation as to monitor and control all sub-systems during the cooldown, warm-up, operation and testing.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.02
6.08.04.01
The cavity helium bath maximum operational temperature shall be 2 K.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.03
6.08.04.01
The cavity helium bath maximum operational pressure shall be 30 mbar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.04
6.08.04.01
The cavity helium bath operation pressure stability shall be ±0.1 mbar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.05
6.08.04.01
The maximum helium supply operational temperature shall be 5.5 K.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.06
6.08.04.01
The range of the helium supply operational pressure shall be 3 to 3.5 bar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.07
6.08.04.01
The range of the combined helium return temperature shall be 64 to 66 K.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.08
6.08.04.01
The range of the combined helium return pressure shall be 2.4 to 2.6 bar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.09
6.08.04.01
The maximum sub-atmospheric helium return temperature shall be 4.5 K.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.10
6.08.04.01
The maximum Subatmospheric helium return pressure shall be 30 mbar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.11
6.08.04.01
The minimum cooldown rate of the SRF cavity between 300K to 150K shall be 10 K/hour.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.12
6.08.04.01
The minimum cooldown rate of the SRF cavity between 150K to 50K shall be 30 K/hour.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.13
6.08.04.01
The minimum cooldown rate of the SRF cavity between 50K to 4.5K shall be 10 K/hour.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.14
6.08.04.01
The minimum cooldown rate of the SRF cavity between 4.5K to 2K shall be 0.5 K/hour.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.15
6.08.04.01
The minimum warmup rate of the SRF cavity between 50K to 150K shall be 30 K/hour.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.16
6.08.04.01
The maximum thermal radiative heat transfer to all 2K and 5K surfaces shall be 2 W/cm^2.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.17
6.08.04.01
The maximum thermal radiative heat transfer to all 50K surfaces shall be 2 W/m^2.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.18
6.08.04.01
The SRF Cryomodule shall achieve steady state temperature with the cavity bath at 4K in a maximum of 2 days.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.19
6.08.04.01
The chilled water and low-conductivity water operational temperature range shall be 295 to 315 K.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.20
6.08.04.01
The chilled water and low-conductivity water operational pressure range shall be 7.5 to 8.5 bar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.21
6.08.04.01
The minimum magnetic shield attenuation factor at SRF cavity equator shall be 50 .
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.22
6.08.04.01
The SRF cryomodule maximum design ambient magnetic field amplitude shall be 700 mG.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.23
6.08.04.01
The SRF Cryomodule shall operate through a minimum of 200 thermal cycles.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.24
6.08.04.01
The minimum SRF Cryomodule Slow Tuner 1% range tuning cycles shall be 100000 cycles.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.25
6.08.04.01
The minimum SRF Cryomodule Slow Tuner full range tuning cycles shall be 1000 cycles
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.26
6.08.04.01
The manufactured SRF Cryomodule Cavity shall produce no field emission at 4 MV
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.27
6.08.04.01
The SRF Cryomodule components that cannot be maintained in-situ shall be designed with a minimum lifetime radiation tolerance of 1000 kGy
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.28
6.08.04.01
The SRF Cryomodule components that can be maintained in-situ shall have an annual minimum radiation tolerance of 1 kGy
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.29
6.08.04.01
The active SRF cavity tuning mechanism components (bearings/motor/piezo) shall be replaceable and maintainable in-situ.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.30
6.08.04.01
The SRF Cavity Fast Tuner shall have a minimum lifetime of 1 year between maintenance cycles .
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.31
6.08.04.01
All critical monitoring and control instruments that cannot be maintained in-situ shall utilize a back-up instrument.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.32
6.08.04.01
The total SRF maximum RF longitudinal impedance (accelerator definition) shall be 52 MΩ Ghz.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.33
6.08.04.01
The total SRF maximum RF horizontal impedance (accelerator definition) shall be 24 MΩ/m.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.34
6.08.04.01
The total SRF maximum RF vertical impedance (accelerator definition) shall be 24 MΩ/m.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.35
6.08.04.01
The minimum cavity aperture radius shall be 30 mm.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.36
6.08.04.01
The maximum broadband RF power emitted from the cryomodule shall be 30 kW for all EIC design energies and currents.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.37
6.08.04.01
The SRF Cryomodule shall be designed to operate with a beam current up to 2.5 A.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.38
6.08.04.01
The Maximum Dipole content shall be 50 mT-m.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.39
6.08.04.01
The Maximum Quadrupole content shall be 4 mT.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.40
6.08.04.01
The Maximum Sextuple content shall be 2 T/m.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.41
6.08.04.01
The Maximum Octupole content shall be 50 mT/m^2.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.42
6.08.04.01
The SRF cavity minimum manufactured quality factor (Qo) shall be 1.5E10.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.43
6.08.04.01
The SRF cavity minimum manufactured gradient shall be 4 MV.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.44
6.08.04.01
The SRF cavity field probe Qext range shall be 1.00E11 to 2.00E11.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.45
6.08.04.01
The SRF cavity nominal cold frequency shall be 591.149 MHz.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.46
6.08.04.01
The SRF pressure sensitivity maximum shall be 10 Hz/mbar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.47
6.08.04.01
The SRF maximum lorentz force detuning shall be 5 Hz/(MV/m)^2.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.48
6.08.04.01
The SRF cavity maximum Niobium temperature shall be 5 K.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.49
6.08.04.01
The warm beamline maximum vacuum shall be 5.0e-7 mbar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.50
6.08.04.01
The cold beamline maximum vacuum shall be 1.0e-9 mbar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.51
6.08.04.01
The beamline vacuum maximum leak rate shall be 5e-10 mbar L/s.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.52
6.08.04.01
The warm insulating maximum vacuum shall be 1.0e-5 mbar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.53
6.08.04.01
The cold insulating maximum vacuum shall be 5.0e-7 mbar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.54
6.08.04.01
The insulating vacuum maximum leak rate shall be 1.0e-8 mbar L/s.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.55
6.08.04.01
The The minimum SRF Cavity Slow Tuner tuning range shall be shall be 600 KHz.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.56
6.08.04.01
The minimum SRF Cavity slow tuner tuning rate shall be 800 Hz/s.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.57
6.08.04.01
The maximum SRF Cavity Slow Tuner resolution shall be ±1 Hz.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.58
6.08.04.01
The maximum SRF Cavity Slow Tuner hysteresis shall be ±10 Hz.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.59
6.08.04.01
The minimum SRF Cavity Fast Tuner tuning range shall be 400 Hz.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.60
6.08.04.01
The minimum SRF Cavity Fast Tuner resolution shall be ±1 Hz.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.61
6.08.04.01
The minimum SRF Cavity Fast Tuner tuning rate shall be 10000 Hz/s.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.62
6.08.04.01
The maximum SRF Cavity Fast Tuner hysteresis shall be ±1 Hz.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.63
6.08.04.01
The external warm maximum allowable working pressure of the SRF cavity shall not exceed 2.2 bar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.64
6.08.04.01
The external cold maximum allowable working pressure of the SRF cavity shall not exceed 5.2 bar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.65
6.08.04.01
The internal maximum allowable working pressure of the SRF cavity shall not exceed 1.8 bar.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.66
6.08.04.01
All cryomodule surfaces accessible to workers shall be within the temperature range of 283 to 333 K.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.67
6.08.04.01
The SRF Cryomodule shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME B31.3.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.68
6.08.04.01
The SRF Cryomodule shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME BPVC.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.69
6.08.04.01
The SRF Cryomodule shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASTM C1055.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.70
6.08.04.01
The SRF Cryomodule shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.71
6.08.04.01
The SRF Cryomodule shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70E.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.72
6.08.04.01
The SRF Cryomodule shall be designed and manufactured as directed by the JLAB ES&H Manual to meet all applicable safety standards as defined by API 520 & API 521.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.73
6.08.04.01
The SRF Cryomodule shall be designed and manufactured as directed by the JLAB ES&H Manual to meet all applicable safety standards as defined by CGA S1.3.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.74
6.08.04.01
The SRF Cryomodule shall be designed and manufactured as directed by the JLAB ES&H Manual to meet all applicable safety standards as defined by AWS.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.75
6.08.04.01
The SRF Cryomodule shall be designed to meet all applicable standards as directed by the DOE Vacuum Vessel Consensus Standards .
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.76
6.08.04.01
The SRF Cryomodule maximum length shall be 7.2 m.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.77
6.08.04.01
The SRF Cryomodule maximum width shall be 2.15 m.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.78
6.08.04.01
The SRF Cryomodule maximum height shall be 1.7 m.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.79
6.08.04.01
The distance from the beamline to the tunnel floor shall be 1381.09 ± 20 mm.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.80
6.08.04.01
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance in X shall be ±250 μm.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.81
6.08.04.01
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance in Y shall be ±250 μm.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.82
6.08.04.01
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance in Z shall be ±5 mm.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.83
6.08.04.01
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance for the roll shall be ±0.04 radians.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.84
6.08.04.01
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance for the pitch shall be ±0.01 radians.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.85
6.08.04.01
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance for the yaw shall be ±0.01 radians.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.86
6.08.04.01
Conditioning for individual cavities shall have a maximum average cryogenic power dissipation of 200 W.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.87
6.08.04.01
Conditioning for individual cavities shall be achieved with a maximum temperature of 2.1 K.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.88
6.08.04.01
The SRF Cryomodule shall be capable of withstanding a maximum allowable vertical acceleration of ±4 G.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.89
6.08.04.01
The SRF Cryomodule shall be capable of withstanding a maximum allowable lateral acceleration of ±1.5 G.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.90
6.08.04.01
The SRF Cryomodule shall be capable of withstanding a maximum allowable beamline axis acceleration of ±5 G.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.91
6.08.04.01
The SRF Cryomodule shall be designed to withstand a tilt around the beamline axis (roll) up to ±1.4 radians.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.92
6.08.04.01
The SRF Cryomodule cavity loaded quality factor shall be 2.9e5 ± TBD.
04/15/2025
In Process
FALSE

P-HSR-RF-ACAV:591S.93
6.08.04.01
The SRF Cryomodule FPC external quality factor balance shall be TBD.
04/15/2025
In Process
FALSE

HSR-RF-ACAV:98

P-HSR-RF-ACAV:98.01
6.08.05.06
The NCRF Cavity System shall be outfitted with flow control, thermometry, vacuum pressure, and RF instrumentation as to monitor and control all sub-systems during operation and testing.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.02.01
6.08.05.06
The NCRF Cavity System shall be designed to operate at a maximum steady state temperature of 70°C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.02.02
6.08.05.06
The NCRF Cavity System chilled water and low-conductivity water operational supply temperature range shall be 26.5 ± 3 °C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.02.03
6.08.05.06
The NCRF Cavity System chilled water and low-conductivity water operational supply pressure range shall be 6-9 bar.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.03.01
6.08.05.06
The minimum NCRF Cavity System Slow Tuner 1% range tuning cycles shall be 1,200,000 cycles.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.03.02
6.08.05.06
The minimum NCRF Cavity System Slow Tuner full range tuning cycles shall be shall be 120,000 cycles.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.03.03
6.08.05.06
The NCRF Cavity System maximum manufactured field emission at operational voltage shall be 10 Gy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.03.04
6.08.05.06
The NCRF Cavity System components that are not replaceable in-situ shall be designed with a minimum lifetime radiation tolerance of 1,000 kGy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.03.05
6.08.05.06
The NCRF Cavity System components that are replaceable in-situ shall have a minimum lifetime radiation tolerance of 1 kGy.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.03.06
6.08.05.06
The NCRF Cavity System critical monitoring and control instruments that cannot be maintained in-situ shall utilize a back-up instrument.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.03.07
6.08.05.06
The NCRF Cavity System shall maximize the number of instrumentats that can be maintained and replaced in-situ.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.03.08
6.08.05.06
The NCRF Cavity System components shall be ergonomically accessible.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.04.01
6.08.05.06
The sum of all NCRF Cavity System RF longitudinal impedance (accelerator definition) shall be no greater than 180 kΩ Ghz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.04.02
6.08.05.06
The sum of all NCRF Cavity System RF horizontal impedance (accelerator definition) shall be no greater than 5 MΩ/m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.04.03
6.08.05.06
The sum of all NCRF Cavity System RF vertical impedance (accelerator definition) shall be no greater than 5 MΩ/m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.04.04
6.08.05.06
The NCRF Cavity System minimum cavity aperture radius shall be 75 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.04.05
6.08.05.06
The NCRF Cavity System maximum broadband RF power emitted from the cavity via the beampipe shall be 1 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.04.06
6.08.05.06
The NCRF Cavity System Maximum Dipole multipole content shall be 50 mT-m.
04/22/2025
In Process
FALSE

P-HSR-RF-ACAV:98.04.07
6.08.05.06
The NCRF Cavity System Maximum Quadrupole multipole content shall be 4 mT.
04/21/2025
In Process
FALSE

P-HSR-RF-ACAV:98.04.08
6.08.05.06
The NCRF Cavity System Maximum Sextuple multipole content shall be 2 T/m.
04/22/2025
In Process
FALSE

P-HSR-RF-ACAV:98.04.09
6.08.05.06
The NCRF Cavity System Maximum Octupole multipole content shall be 50 mT/m^2.
04/22/2025
In Process
FALSE

P-HSR-RF-ACAV:98.05.01
6.08.05.06
The NCRF Cavity System minimum manufactured quality factor (Qo) shall be 7,650.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.05.02
6.08.05.06
The sum of all NCRF Cavity System minimum manufactured gradients shall be 0.6 MV.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.05.03
6.08.05.06
The NCRF Cavity System field probe Qext range shall be (5.4 ± 1.0)e7.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.05.04
6.08.05.06
The NCRF Cavity System nominal frequency shall be 98.525 MHz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.05.05
6.08.05.06
The NCRF Cavity System FPC external quality factor shall be (3.9 ± 0.2)e3.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.05.06
6.08.05.06
The NCRF Cavity System FPC window design shall be rated to a minimum input power of 120 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.05.07
6.08.05.06
The NCRF Cavity System loop HOM Damper maximum total broadband power on each shall be 5 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.05.08
6.08.05.06
The NCRF Cavity System e-probe HOM Damper maximum total broadband power on each shall be 0.1 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.05.09
6.08.05.06
The NCRF Cavity System loop HOM Damper maximum fundamental power leakage under nominal frequency and voltage shall be 200 W.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.06.01
6.08.05.06
The NCRF Cavity System maximum vacuum shall be 1.0e-8 mbar.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.06.02
6.08.05.06
The NCRF Cavity System maximum vacuum leak rate shall be 5.0e-9 mbar L/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.07.01
6.08.05.06
The NCRF Cavity System Slow Tuner tuning range shall be -120 to +120 KHz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.07.02
6.08.05.06
The minimum NCRF Cavity System slow tuner resolution shall be 10 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.07.03
6.08.05.06
The minimum NCRF Cavity System slow tuner tuning rate shall be 1600 Hz/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.07.04
6.08.05.06
The maximum NCRF Cavity System Slow Tuner hysteresis shall be 100 Hz.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.08.01
6.08.05.06
The NCRF Cavity System maximum Qext of the Fundamental Mode Damper shall be 115.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.08.02
6.08.05.06
The NCRF Cavity System Fundamental Mode Damper shall handle a minimum power of 5 kW.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.08.03
6.08.05.06
The NCRF Cavity System Fundamental Mode Damper minimum insertion speed shall be 700 mm/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.08.04
6.08.05.06
The NCRF Cavity System Fundamental Mode Damper minimum retraction speed shall be 140 mm/s.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.09.01
6.08.05.06
All NCRF Cavity System surfaces accessible to workers shall be less than 60°C.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.09.02
6.08.05.06
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME B31.3.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.09.03
6.08.05.06
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASME BPVC.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.09.04
6.08.05.06
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by ASTM C1055.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.09.05
6.08.05.06
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.09.06
6.08.05.06
The NCRF Cavity System shall be designed and manufactured to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), as defined by NFPA 70E.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.09.07
6.08.05.06
The NCRF Cavity System shall be designed and manufactured as directed by the BNL SBMS to meet all applicable safety standards as defined by API 520 & API 521.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.09.08
6.08.05.06
The NCRF Cavity System shall be designed and manufactured as directed by the BNL SBMS to meet all applicable safety standards as defined by AWS.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.01
6.08.05.06
The NCRF Cavity System full assembly maximum length shall be 0.9 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.02
6.08.05.06
The NCRF Cavity System full assembly maximum width shall be 1.5 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.03
6.08.05.06
The NCRF Cavity System full assembly maximum height shall be 1.3 m.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.04
6.08.05.06
The distance from the NCRF Cavity System beamline to the tunnel floor shall be 1270.0 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.05
6.08.05.06
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in X shall be ± 0.7 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.06
6.08.05.06
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in Y shall be ± 0.7 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.07
6.08.05.06
The NCRF Cavity System Electromagnetic Center Alignment Tolerance in Z shall be ± 10 mm.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.08
6.08.05.06
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the roll shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.09
6.08.05.06
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the pitch shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.10.10
6.08.05.06
The NCRF Cavity System Electromagnetic Center Alignment Tolerance for the yaw shall be ± 0.1 radians.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.11.01
6.08.05.06
The NCRF Cavity System shall be capable of withstanding a maximum allowable vertical acceleration of 4 G.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.11.02
6.08.05.06
The NCRF Cavity System shall be capable of withstanding a maximum allowable lateral acceleration of 1.5 G.
04/22/2025
Reviewed
FALSE

P-HSR-RF-ACAV:98.11.03
6.08.05.06
The NCRF Cavity System shall be capable of withstanding a maximum allowable beamline axis acceleration of 5 G.
04/22/2025
Reviewed
FALSE

HSR-RF-CCAV:197

P-HSR-RF-CCAV:197.01
6.08.04.04
The SRF CM shall be outfitted with flow control, thermometry, pressure, and RF instrumentation as to monitor and control all sub-systems during the cooldown, warm-up, operation and testing
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.02
6.08.04.04
The cavity helium bath maximum operational temperature shall be 2 K
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.03
6.08.04.04
The cavity helium bath maximum operational pressure shall be 30 mbar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.04
6.08.04.04
The cavity helium bath operation pressure stability shall be ±0.1 mbar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.05
6.08.04.04
The maximum helium supply operational temperature shall be 5.5 K
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.06
6.08.04.04
The range of the helium supply operational pressure shall be 3 to 3.5 bar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.07
6.08.04.04
The range of the combined helium return temperature shall be 64 to 66 K
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.08
6.08.04.04
The range of the combined helium return pressure shall be 2.4 to 2.6 bar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.09
6.08.04.04
The maximum sub-atmospheric helium return temperature shall be 4.5 K
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.10
6.08.04.04
The maximum Subatmospheric helium return pressure shall be 30 mbar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.11
6.08.04.04
The minimum cooldown rate of the SRF cavity between 300K and 4.5K shall be 20 K/hour
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.12
6.08.04.04
The minimum cooldown rate of the SRF cavity between 4.5K to 2K shall be 0.5 K/hour
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.13
6.08.04.04
The SRF CM shall achieve steady state temperature with the cavity bath at 4K in a maximum of 4 days
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.14
6.08.04.04
The minimum warmup rate of the SRF cavity between 50K to 150K shall be 30 K/hour
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.15
6.08.04.04
The maximum thermal radiative heat transfer to all 2K and 5K surfaces shall be 2 W/cm^2
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.16
6.08.04.04
The maximum thermal radiative heat transfer to all 50K surfaces shall be 2 W/m^2
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.17
6.08.04.04
The chilled water and low-conductivity water operational temperature range shall be 295 to 315 K
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.18
6.08.04.04
The chilled water and low-conductivity water operational pressure range shall be 7.5 to 8 bar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.19
6.08.04.04
The minimum magnetic shield attenuation factor at SRF cavity equator shall be 50
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.20
6.08.04.04
The SRF CM shall operate through a minimum of 100 thermal cycles
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.21
6.08.04.04
The minimum SRF Cavity Slow tuner minimum lifetime shall be 30 years
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.22
6.08.04.04
The minimum SRF CM Slow Tuner 1% range tuning cycles shall be 100000 cycles
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.23
6.08.04.04
The minimum SRF CM Slow Tuner full range tuning cycles shall be 1000 cycles
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.24
6.08.04.04
The manufactured SRF CM Cavity shall produce no field emission at 4 MV
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.25
6.08.04.04
The SRF CM components that are not replaceable in-situ shall be designed with a radiation tolerance greater than 1 MGy
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.26
6.08.04.04
The SRF CM components that are replaceable in-situ shall have a radiation tolerance greater than 1 kGy
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.27
6.08.04.04
The active SRF cavity tuning mechanism components (bearings/motor/piezo) shall be replaceable and maintainable in-situ.
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:197.28
6.08.04.04
All critical monitoring and control instruments that cannot be maintained in-situ shall utilize a back-up instrument.
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.29
6.08.04.04
The SRF CM instrument should have maximized instruments that can be maintained and replaced in-situ
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.30
6.08.04.04
The SRF maximum (per cavity) RF longitudinal impedance shall be 0.26 MΩ GHz
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.31
6.08.04.04
The SRF maximum (per cavity) RF horizontal impedance shall be 0.132 MΩ/m
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:197.32
6.08.04.04
The SRF maximum (per cavity) RF vertical impedance shall be 0.66 MΩ/m
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.33
6.08.04.04
The minimum cavity aperture radius shall be 50 mm
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.34
6.08.04.04
The maximum broadband RF power emitted from the CM shall be 20 kW
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.35
6.08.04.04
The Maximum Quadrupole multipole content shall be 8 mT
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.36
6.08.04.04
The Maximum Sextupole multipole content shall be 160 mT/m
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.37
6.08.04.04
The Maximum Octupole multipole content shall be 7.6 T/m^2
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.38
6.08.04.04
The Maximum Decapole multipole content shall be 410 T/m^3
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.39
6.08.04.04
The SRF cavity minimum manufactured quality factor (Qo) shall be 6000000000
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:197.40
6.08.04.04
The SRF cavity minimum manufactured voltage shall be 8.5 MV
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.41
6.08.04.04
The SRF cavity fundamental power coupler Qext shall be 1750000
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.42
6.08.04.04
The SRF cavity field probe Qext range shall be 27000000000
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.43
6.08.04.04
The SRF cavity nominal cold frequency shall be 197.0508 MHz
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.44
6.08.04.04
The SRF cavity maximum Niobium temperature shall be 4.5 K
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.45
6.08.04.04
The SRF Pressure sensitivity maximum shall be 10 Hz/mBar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.46
6.08.04.04
The SRF maximum Lorentz force detuning shall be 5 Hz/(Mv/m)^2
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.47
6.08.04.04
The warm beamline maximum vacuum shall be 1.0e-7 mbar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.48
6.08.04.04
The cold beamline maximum vacuum shall be 1.0e-9 mbar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.49
6.08.04.04
The beamline vacuum maximum leak rate shall be 1.0e-11 mbar L/s
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.50
6.08.04.04
The warm insulating maximum vacuum shall be 1.0e-5 mbar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.51
6.08.04.04
The cold insulating maximum vacuum shall be 5.0e-7 mbar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.52
6.08.04.04
The insulating vacuum maximum leak rate shall be 1.0e-9 mbar L/s
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.53
6.08.04.04
The minimum SRF Cavity Slow Tuner tuning range shall be shall be -170, +101 kHz
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.54
6.08.04.04
The minimum SRF Cavity slow tuner tuning rate shall be 800 Hz/s
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:197.55
6.08.04.04
The maximum SRF Cavity Slow Tuner resolution shall be ±5 Hz
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.56
6.08.04.04
The maximum SRF Cavity Slow Tuner hysteresis shall be ±1 Hz
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.57
6.08.04.04
The external warm maximum allowable working pressure of the SRF cavity shall not exceed 2.2 bar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.58
6.08.04.04
The external cold maximum allowable working pressure of the SRF cavity shall not exceed 5.2 bar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.59
6.08.04.04
The internal maximum allowable working pressure of the SRF cavity shall not exceed 1.8 bar
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.60
6.08.04.04
All cryomodule surfaces accessible to workers shall be within the temperature range of 283 to 333 K
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.61
6.08.04.04
The SRF CM shall be designed to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), and defined by ASME B31.3
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.62
6.08.04.04
The SRF CM shall be designed to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), and defined by ASME BPVC
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.63
6.08.04.04
The SRF CM shall be designed to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), and defined by ASTM C1055
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.64
6.08.04.04
The SRF CM shall be designed to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), and defined by NFPA 70
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.65
6.08.04.04
The SRF CM shall be designed and manufactured as directed by the JLAB ES&H Manual to meet all applicable safety standards as defined by API 520 & API 521
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.66
6.08.04.04
The SRF CM shall be designed to meet all applicable standards,as directed by the EIC Code of Record and/or all applicable excluded items governed by the EIC Memorandum of Agreements (MOA), and defined by NFPA 70E
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.67
6.08.04.04
The SRF CM shall be designed and manufactured as directed by the JLAB ES&H Manual to meet all applicable safety standards as defined by CGA S1.3
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.68
6.08.04.04
The SRF CM shall be designed and manufactured as directed by the JLAB ES&H Manual to meet all applicable safety standards as defined by AWS
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.69
6.08.04.04
The SRF CM shall be designed to meet all applicable standards as directed by the DOE Vacuum Vessel Consensus Standards
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.70
6.08.04.04
The SRF CM maximum length shall be 5.21 m
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.71
6.08.04.04
The SRF CM maximum width shall be 1.37 m
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.72
6.08.04.04
The SRF CM maximum height shall be 2.67 m
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.73
6.08.04.04
FPC Sizing Placeholder TBD
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.74
6.08.04.04
FPC Sizing Placeholder TBD
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.75
6.08.04.04
FPC Sizing Placeholder TBD
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.76
6.08.04.04
The distance from the beamline to the tunnel floor shall be 1.27 m
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:197.77
6.08.04.04
The Cavity Electromagnetic Center Alignment Tolerance in X shall be ±250 μm
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.78
6.08.04.04
The Cavity Electromagnetic Center Alignment Tolerance in Y shall be ±250 μm
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.79
6.08.04.04
The Cavity Electromagnetic Center Alignment Tolerance in Z shall be ±5 mm
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.80
6.08.04.04
The Cavity Electromagnetic Center Alignment Tolerance for the roll shall be ±2.0 degrees
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.81
6.08.04.04
The Cavity Electromagnetic Center Alignment Tolerance for the pitch shall be ±1.0 degrees
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.82
6.08.04.04
The Cavity Electromagnetic Center Alignment Tolerance for the yaw shall be ±0.03 degrees
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.83
6.08.04.04
Conditioning for individual cavities shall have a maximum average cryogenic power dissipation of 200 W
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:197.84
6.08.04.04
Conditioning for individual cavities shall be achieved with a maximum temperature of 2.1 K
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.85
6.08.04.04
The SRF CM shall be capable of withstanding a maximum allowable vertical acceleration of 4 G
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.86
6.08.04.04
The SRF CM shall be capable of withstanding a maximum allowable lateral acceleration of 1.5 G
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.87
6.08.04.04
The SRF Cryomodule shall be capable of withstanding a maximum allowable beamline axis acceleration of 5 G.
04/15/2025
Reviewed
FALSE

P-HSR-RF-CCAV:197.88
6.08.04.04
The SRF Cryomodule shall be designed to withstand a minimum tilt around the beamline axis (roll) of ± 0.26 radians
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:197.89
6.08.04.04
The SRF Cryomodule loaded quality factor shall be TBD ± TBD.
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:197.90
6.08.04.04
The SRF Cryomodule FPC external quality factor balance shall be TBD.
04/15/2025
In Process
FALSE

HSR-RF-CCAV:394

P-HSR-RF-CCAV:394.01
6.08.04.05
The SRF CM shall be outfitted with flow control, thermometry, pressure, and RF instrumentation as to monitor and control all sub-systems during the cooldown, warm-up, operation and testing
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.02
6.08.04.05
The cavity helium bath maximum operational temperature shall be TBD K
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.03
6.08.04.05
The cavity helium bath maximum operational pressure shall be TBD mbar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.04
6.08.04.05
The cavity helium bath operation pressure stability shall be ±TBD mbar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.05
6.08.04.05
The maximum helium supply operational temperature shall be TBD K
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.06
6.08.04.05
nan
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.07
6.08.04.05
The range of the combined helium return temperature shall be TBD to TBD K
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.08
6.08.04.05
The range of the combined helium return pressure shall be TBD to TBD bar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.09
6.08.04.05
The maximum sub-atmospheric helium return temperature shall be TBD K
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.10
6.08.04.05
The maximum Subatmospheric helium return pressure shall be TBD mbar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.11
6.08.04.05
The minimum cooldown rate of the SRF cavity between 300K and 4.5K shall be TBD K/hour
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.12
6.08.04.05
The minimum cooldown rate of the SRF cavity between 4.5K to 2K shall be TBD K/hour
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.13
6.08.04.05
The SRF CM shall achieve steady state temperature with the cavity bath at 4K in a maximum of TBD days
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.14
6.08.04.05
The chilled water and low-conductivity water operational temperature range shall be TBD to TBD K
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.15
6.08.04.05
The chilled water and low-conductivity water operational pressure range shall be TBD to TBD bar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.16
6.08.04.05
The minimum magnetic shield attenuation factor at SRF cavity equator shall be TBD
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.17
6.08.04.05
The SRF CM shall operate through a minimum of TBD thermal cycles
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.18
6.08.04.05
The minimum SRF Cavity Slow tuner minimum lifetime shall be TBD years
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.19
6.08.04.05
The minimum SRF CM Slow Tuner 1% range tuning cycles shall be TBD cycles
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.20
6.08.04.05
The minimum SRF CM Slow Tuner full range tuning cycles shall be TBD cycles
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.21
6.08.04.05
The manufactured SRF CM Cavity shall produce no field emission at TBD MV
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.22
6.08.04.05
The SRF CM components that are not replaceable in-situ shall be designed with a radiation tolerance greater than TBD MGy
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.23
6.08.04.05
The SRF CM components that are replaceable in-situ shall have a radiation tolerance greater than TBD kGy
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.24
6.08.04.05
The active SRF cavity tuning mechanism components (bearings/motor/piezo) shall be replaceable and maintainable in-situ.
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.25
6.08.04.05
All critical monitoring and control instruments that cannot be maintained in-situ shall utilize a back-up instrument.
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.26
6.08.04.05
The SRF CM instrument should have maximized instruments that can be maintained and replaced in-situ
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.27
6.08.04.05
The SRF maximum (per cavity) RF longitudinal impedance shall be TBD MΩ GHz
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.28
6.08.04.05
The SRF maximum (per cavity) RF horizontal impedance shall be TBD MΩ/m
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.29
6.08.04.05
nan
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.30
6.08.04.05
The minimum cavity aperture radius shall be TBD mm
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.31
6.08.04.05
The maximum broadband RF power emitted from the CM shall be TBD kW
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.32
6.08.04.05
The Maximum Quadrupole multipole content shall be TBD mT
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.33
6.08.04.05
The Maximum Sextupole multipole content shall be TBD mT/m
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.34
6.08.04.05
The Maximum Octupole multipole content shall be TBD T/m^2
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.35
6.08.04.05
The Maximum Decapole multipole content shall be TBD T/m^3
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.36
6.08.04.05
The SRF cavity minimum manufactured quality factor (Qo) shall be TBD
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.37
6.08.04.05
The SRF cavity minimum manufactured voltage shall be TBD MV
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.38
6.08.04.05
The SRF cavity fundamental power coupler Qext shall be TBD
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.39
6.08.04.05
The SRF cavity field probe Qext range shall be TBD
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.40
6.08.04.05
The SRF cavity nominal cold frequency shall be TBD MHz
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.41
6.08.04.05
The SRF cavity maximum Niobium temperature shall be TBD K
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.42
6.08.04.05
The SRF Pressure sensitivity maximum shall be TBD Hz/mBar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.43
6.08.04.05
The SRF maximum Lorentz force detuning shall be TBD Hz/(Mv/m)^2
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.44
6.08.04.05
The warm beamline maximum vacuum shall be TBD mbar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.45
6.08.04.05
The cold beamline maximum vacuum shall be TBD mbar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.46
6.08.04.05
The beamline vacuum maximum leak rate shall be TBD mbar L/s
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.47
6.08.04.05
The warm insulating maximum vacuum shall be TBD mbar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.48
6.08.04.05
The cold insulating maximum vacuum shall be TBD mbar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.49
6.08.04.05
The insulating vacuum maximum leak rate shall be TBD mbar L/s
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.50
6.08.04.05
The minimum SRF Cavity Slow Tuner tuning range shall be shall be -TBD, +TBD kHz
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.51
6.08.04.05
The minimum SRF Cavity slow tuner tuning rate shall be TBD Hz/s
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.52
6.08.04.05
The maximum SRF Cavity Slow Tuner resolution shall be TBD Hz
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.53
6.08.04.05
The maximum SRF Cavity Slow Tuner hysteresis shall be ±TBD Hz
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.54
6.08.04.05
The external warm maximum allowable working pressure of the SRF cavity shall not exceed TBD bar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.55
6.08.04.05
The external cold maximum allowable working pressure of the SRF cavity shall not exceed TBD bar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.56
6.08.04.05
The internal maximum allowable working pressure of the SRF cavity shall not exceed TBD bar
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.57
6.08.04.05
All cryomodule surfaces accessible to workers shall be within the temperature range of TBD to TBD K
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.58
6.08.04.05
The SRF CM shall be designed and manufactured as directed by the EIC code of records to meet all applicable safety standards as defined by ASME B31.3
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.59
6.08.04.05
The SRF CM shall be designed and manufactured as directed by the EIC code of records to meet all applicable safety standards as defined by ASME BPVC
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.60
6.08.04.05
The SRF CM shall be designed and manufactured as directed by the EIC code of records to meet all applicable safety standards as defined by ASTM C1055
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.61
6.08.04.05
The SRF CM shall be designed and manufactured as directed by the EIC code of records to meet all applicable safety standards as defined by NFPA 70
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.62
6.08.04.05
The SRF CM shall be designed and manufactured as directed by the JLAB ES&H Manual to meet all applicable safety standards as defined by API 520 & API 521
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.63
6.08.04.05
The SRF CM shall be designed and manufactured as directed by the EIC code of records to meet all applicable safety standards as defined by NFPA 70E
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.64
6.08.04.05
The SRF CM shall be designed and manufactured as directed by the JLAB ES&H Manual to meet all applicable safety standards as defined by CGA S1.3
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.65
6.08.04.05
The SRF CM shall be designed and manufactured as directed by the JLAB ES&H Manual to meet all applicable safety standards as defined by AWS
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.66
6.08.04.05
The SRF CM maximum length shall be TBD m
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.67
6.08.04.05
The SRF CM maximum width shall be TBD m
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.68
6.08.04.05
The SRF CM maximum height shall be TBD m
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.69
6.08.04.05
nan
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.70
6.08.04.05
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance in X shall be ±TBD μm
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.71
6.08.04.05
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance in Y shall be ±TBD μm
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.72
6.08.04.05
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance in Z shall be ±TBD mm
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.73
6.08.04.05
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance for the roll shall be ±TBD degrees
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.74
6.08.04.05
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance for the pitch shall be ±TBD degrees
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.75
6.08.04.05
The SRF Cryomodule Cavity Electromagnetic Center Alignment Tolerance for the yaw shall be ±TBD degrees
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.76
6.08.04.05
Conditioning for individual cavities shall have a maximum average cryogenic power dissipation of TBD W
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.77
6.08.04.05
Conditioning for individual cavities shall be achieved with a maximum temperature of TBD K
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.78
6.08.04.05
The SRF CM shall be capable of withstanding a maximum allowable vertical acceleration of TBD G
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.79
6.08.04.05
The SRF CM shall be capable of withstanding a maximum allowable lateral acceleration of TBD G
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.80
6.08.04.05
The SRF CM shall be capable of withstanding a maximum allowable beamline axis acceleration of TBD G
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.81
6.08.04.05
The SRF Cryomodule shall be designed to withstand a minimum tilt around the beamline axis (roll) of ±0.26 radians.
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.82
6.08.04.05
The SRF Cryomodule loaded quality factor shall be TBD ± TBD.
04/15/2025
In Process
FALSE

P-HSR-RF-CCAV:394.83
6.08.04.05
The SRF Cryomodule FPC external quality factor balance shall be TBD.
04/15/2025
In Process
FALSE

HSR-ARC

HSR-ARC-MAG : HSR ARC Magnets

HSR-ARC-SNAK

HSR-CRYO

HSR-MP : Machine Protection

HSR-MP-ABORT

F-HSR-MP-ABORT.01
The HSR shall contain a beam abort system to dump the beam.
04/03/2025
Approved
FALSE

F-HSR-MP-ABORT.02
The HSR beam abort system shall consist of a set of kickers and a beam dump
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.03
The HSR beam abort system shall be located in the tunnel between Q3 and Q4 at 9 o'clock side of the IR10 straight section.
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.04
The HSR beam abort system shall re-use a RHIC beam dump to safely absorb the energy of the stored beam in a controlled fashion.
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.05
The HSR beam abort system shall receive its trigger from the HSR machine protection system.
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.06
The HSR beam dump shall be capable of absorbing the entire HSR proton beam (275 GeV, 1160 bunches, 11 nC each, 3.2 MJ stored energy) as well the entire Au ion beam (110 GeV/u, 290 bunches, 25 nC each, 2 MJ stored energy)) without sustaining permanent damage
04/03/2025
Approved
FALSE

F-HSR-MP-ABORT.07
The HSR beam dump shall be capable of absorbing the entire HSR full energy beam (proton or Au ion) every 3 hours.
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.08
The HSR beam dump system must ensure reliable protection from quenches, caused by secondary particles, of Q4 SC magnet down stream of the beam dump.
04/03/2025
Approved
FALSE

F-HSR-MP-ABORT.09
Radiation shielding shall be provided as part of the HSR beam dump assembly such that the radiation on the outer surface of the beam dump does not exceed TBD after TBD beam aborts at full intensity.
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.10
The HSR abort kickers shall be installed downstream of Q3 magnet on the 9 o'clock side of the IR10 straight section.
04/03/2025
Approved
FALSE

F-HSR-MP-ABORT.11
The rise time of the HSR abort kicker system shall not exceed 1 (μS).
04/03/2025
Approved
FALSE

F-HSR-MP-ABORT.12
The HSR abort kicker pulse shall remain at or near its peak value for a duration of at least 13 (μS).
04/03/2025
Approved
FALSE

F-HSR-MP-ABORT.13
The HSR abort kicker pulse amplitude shall be sufficiently large to deflect the beam safely into the beam dump.
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.14
The rising edge of the HSR abort kicker pulse shall be synchronized with the abort gap in the HSR bunch train, such that all bunches receive a kick sufficient to deflect them into the beam dump.
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.15
The number of HSR abort kicker modules shall be chosen such that the required total detection angle is provided efficiently.
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.16
The design of the HSR abort kickers must be consistent with the impedance budget requirements of the HSR.
04/02/2025
Approved
FALSE

F-HSR-MP-ABORT.17
The HSR abort kicker power supply scheme shall be designed to eliminate the possibility of kicker module sporadic firing (pre-fire).
04/03/2025
Approved
FALSE

F-HSR-MP-ABORT.18
The HSR horizontal half aperture for the circulating beam at the location of the beam dump shall correspond to at least 6 sigma horizontal RMS beam sizes, based on the Au injection emittances defined in the Master Parameter Table (MPT). [Document#: EIC-SEG-RSI-005]
04/04/2025
Approved
FALSE

F-HSR-MP-ABORT.19
The HSR vertical half aperture for the circulating beam at the location of the beam dump shall correspond to at least 6 sigma vertical RMS beam sizes, based on the Au injection emittances defined in the Master Parameter Table (MPT). [Document#: EIC-SEG-RSI-005]
04/04/2025
Approved
FALSE

HSR-SNAKE

F-HSR-SNAKE.01
Six Siberian Snakes shall be required. Two existing yellow ring snakes, one in RHIC sector 9 and one in RHIC sector 3, shall stay. Four additional snakes will be positioned as specified in requirements F-HSR-SNAKE.05 to F-HSR-SNAKE.11
04/03/2025
Approved
FALSE

F-HSR-SNAKE.02
All the snake magnets shall operate utilizing exsisting RHIC ARC cyrogenic distrubution system.
04/02/2025
Approved
FALSE

F-HSR-SNAKE.03
All individual snake magnets shall be powered by individual power supplies.
04/02/2025
Approved
FALSE

F-HSR-SNAKE.04
The HSR snakes shall have the modifications required to accommodate the retrofitted HSR beam screens.
04/02/2025
In Process
FALSE

F-HSR-SNAKE.05
Two additional snakes shall be transferred over from the RHIC Blue ring.
04/02/2025
Approved
FALSE

F-HSR-SNAKE.06
One additional snake shall be placed between Q7 and Q8 at 11 o’clock area of high energy arc.
04/02/2025
Approved
FALSE

F-HSR-SNAKE.07
One additional snake shall be placed between Q8 and Q7 in sector 1 of the 2 o’clock area.
04/02/2025
Approved
FALSE

F-HSR-SNAKE.08
Two additional snakes shall be constructed by reconfiguring four spin rotators removed from the RHIC Blue ring.
04/02/2025
Approved
FALSE

F-HSR-SNAKE.09
One additional reconfigured snake shall be placed sector 5 with its axis parallel to the snake in sector 11.
04/02/2025
Approved
FALSE

F-HSR-SNAKE.10
One additional reconfigured snake shall be placed between Q7 and Q8 in sector 7 of the 8 o’clock area.
04/02/2025
Approved
FALSE

F-HSR-SNAKE.11
All additional snakes shall repeat the internal structure of existing Snakes.
04/02/2025
Approved
FALSE

HSR-STR : Hadron Storage Ring Functional Requirements

HSR-STR-BELW : Beam Screens

HSR-STR-COLL : Collomation

HSR-STR-INST

HSR-STR-INST-BLM : Beam Loss Monitoring Instrumentation

HSR-STR-INST-BPM : Beam Position Monitor Instrumentation

HSR-STR-INST-DCCT : Direct Current Current Transformer

HSR-STR-INST-FDBK_SYS : Feedback System Instrumentation

HSR-STR-INST-GC : Gap Cleaner Instrumentation

HSR-STR-INST-HFSCH : HF Schottky Instrumentation

HSR-STR-INST-HTPIUP : Head Tail Pickup Instrumentation

HSR-STR-INST-LFSCH : LF Schottky Instrumentation

HSR-STR-INST-LNG_DMP : Longitudnal Damping Instrumentation

HSR-STR-INST-LPM : Longitudinal Profile Monitoring Instrumentation

HSR-STR-INST-TM : Tune Monitoring Instrumentation

HSR-STR-INST-TM_BB : Base-band Tune Meter Instrumentation

HSR-STR-INST-TPM : Transverse Profile Monitoring Instrumentation

HSR-STR-INST-TRNSV_DMP : Tansverse Damping Instrumentation

HSR-STR-IR : Hadron Storage Ring Straight Section IR Beam

HSR-STR-IR-IR02 : IR02 Straight Section

HSR-STR-IR-IR04 : IR04 Straight Section

HSR-STR-IR-IR06 : IR06 Straight Section

HSR-STR-IR-IR08 : IR08 Straight Section

HSR-STR-IR-IR10 : IR10 Straight Section

HSR-STR-IR-IR12 : IR12 Straight Section

HSR-STR-IR02

HSR-STR-IR04

HSR-STR-IR06

HSR-STR-IR08

HSR-STR-IR10

HSR-STR-IR12

HSR-STR-MAG : Magnets

HSR-STR-PS : Magnet Power Supplies

HSR-STR-VAC

HSR-STR-VAC-BS : Vacuum Beam Screen