Requirement Details
Electron Ion Collider
F-IR-HSR-LATTICE.2
Requirement details, history, relationships and interfaces associated with requirement F-IR-HSR-LATTICE.2
CURRENT RECORD
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Record Date: 01/27/2025 16:43 | |||
Identifier: | F-IR-HSR-LATTICE.2 | WBS: | 6.06.02 |
Date Modified: | TBD: | FALSE | |
Status Date: | Status: | In Process | |
Description: | The hadron beamline lattice elements through the IR shall have a large enough aperture throughout to accommodate a minimum of 10σ spread in x and y of the incoming hadron beam at all energies without obstruction for all energies set forth in [5.8]. | ||
Comments: |
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P-HSR-MAG-D5I.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-D5I.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-D5I.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-D5I.06 | 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: |
P-HSR-MAG-D5I.07 | 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: |
P-HSR-MAG-D5I.08 | 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: |
P-HSR-MAG-D5I.09 | 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. |
P-HSR-MAG-D5I.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-D5O.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-D5O.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-D5O.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-D5O.06 | 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: |
P-HSR-MAG-D5O.07 | 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: |
P-HSR-MAG-D5O.08 | 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: |
P-HSR-MAG-D5O.09 | 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. |
P-HSR-MAG-D5O.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-D6.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-D6.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-D6.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-D6.06 | 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: |
P-HSR-MAG-D6.07 | 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: |
P-HSR-MAG-D6.08 | 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: |
P-HSR-MAG-D6.09 | 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. |
P-HSR-MAG-D6.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-D8.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-D8.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-D8.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-D8.06 | 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: |
P-HSR-MAG-D8.07 | 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: |
P-HSR-MAG-D8.08 | 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: |
P-HSR-MAG-D8.09 | 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. |
P-HSR-MAG-D8.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-D9.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-D9.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-D9.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-D9.06 | 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: |
P-HSR-MAG-D9.07 | 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: |
P-HSR-MAG-D9.08 | 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: |
P-HSR-MAG-D9.09 | 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. |
P-HSR-MAG-D9.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-Q1.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-Q1.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-Q1.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-Q1.06 | 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: |
P-HSR-MAG-Q1.07 | 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: |
P-HSR-MAG-Q1.08 | 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: |
P-HSR-MAG-Q1.09 | 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. |
P-HSR-MAG-Q1.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-Q2.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-Q2.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-Q2.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-Q2.06 | 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: |
P-HSR-MAG-Q2.07 | 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: |
P-HSR-MAG-Q2.08 | 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: |
P-HSR-MAG-Q2.09 | 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. |
P-HSR-MAG-Q2.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-Q3.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-Q3.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-Q3.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-Q3.06 | 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: |
P-HSR-MAG-Q3.07 | 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: |
P-HSR-MAG-Q3.08 | 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: |
P-HSR-MAG-Q3.09 | 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. |
P-HSR-MAG-Q3.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-Q4.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-Q4.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-Q4.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-Q4.06 | 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: |
P-HSR-MAG-Q4.07 | 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: |
P-HSR-MAG-Q4.08 | 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: |
P-HSR-MAG-Q4.09 | 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. |
P-HSR-MAG-Q4.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-Q5.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-Q5.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-Q5.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-Q5.06 | 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: |
P-HSR-MAG-Q5.07 | 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: |
P-HSR-MAG-Q5.08 | 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: |
P-HSR-MAG-Q5.09 | 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. |
P-HSR-MAG-Q5.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-Q6.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-Q6.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-Q6.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-Q6.06 | 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: |
P-HSR-MAG-Q6.07 | 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: |
P-HSR-MAG-Q6.08 | 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: |
P-HSR-MAG-Q6.09 | 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. |
P-HSR-MAG-Q6.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-Q7.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-Q7.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-Q7.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-Q7.06 | 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: |
P-HSR-MAG-Q7.07 | 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: |
P-HSR-MAG-Q7.08 | 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: |
P-HSR-MAG-Q7.09 | 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. |
P-HSR-MAG-Q7.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-Q8.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-Q8.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-Q8.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-Q8.06 | 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: |
P-HSR-MAG-Q8.07 | 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: |
P-HSR-MAG-Q8.08 | 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: |
P-HSR-MAG-Q8.09 | 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. |
P-HSR-MAG-Q8.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
P-HSR-MAG-Q9.03 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints. |
P-HSR-MAG-Q9.04 | The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints. |
P-HSR-MAG-Q9.05 | The magnet shall not be designed to constrain the external fringe field. |
P-HSR-MAG-Q9.06 | 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: |
P-HSR-MAG-Q9.07 | 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: |
P-HSR-MAG-Q9.09 | 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. |
P-HSR-MAG-Q9.08 | 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: |
P-HSR-MAG-Q9.10 | 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 ÒBNL MaterialsÓ List Doc. No. TBD. |
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