Calculation of the pressure rise in the cooling tube of a two-phase cooling system during a quench of an indirectly cooled superconducting magnet

Green, M.A.

doi:10.1109/20.305767

Cited by 3 publications

(1 citation statement)

References 4 publications

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“…The helium used to cool these leads comes directly from the liquid helium cooling circuit. Gas-cooled leads attached to the end of the magnet are located within the cryostat vacuum, so these leads must be completely vacuum tight and they must withstand any increase in pressure that might occur in the cooling circuit during a quench [70]. The bundled nested tube leads that were used on the PEP-4 experiment [71] and the 8-2 solenoids [72] can be operated at any orientation within the cryostat vacuum vessel.…”

Section: Coil Electrical Connections and Leads To The Outside Worldmentioning

confidence: 99%

High‐Energy Physics Particle Detector Magnets

Green

1999

Wiley Encyclopedia of Electrical and Electronics Engineering

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The sections in this article are The Development of Detector Solenoids The Defining Parameters for Thin Solenoids Thin Detector Solenoid Design Criteria Magnet Power Supply and Coil Quench Protection Design Criteria for The Ends of a Detector Solenoid Cryogenic Cooling of a Thin Detector Solenoid

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Section: Coil Electrical Connections and Leads To The Outside Worldmentioning

confidence: 99%

High‐Energy Physics Particle Detector Magnets

Green

1999

Wiley Encyclopedia of Electrical and Electronics Engineering

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Superconducting Detector Magnets for Particle Physics

Green

2016

Digital Encyclopedia of Applied Physics

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The article contains sections titled: The Development of Detector Solenoids LHC Detector Magnets for the ATLAS , CMS , and ALICE Experiments The Future of Detector Magnets for Particle Physics The Defining Parameters for Thin Solenoids Thin Detector Solenoid Design Criteria Magnet Power Supply and Coil Quench Protection Design Criteria for the Ends of a Detector Solenoid Cryogenic Cooling of a Detector Magnet

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Superconducting Magnets

Hull

Wilson

Bottura

et al. 2015

Applied Superconductivity

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On the nature of the molecular forces which regulate the constitution of the luminferous ether. Trans. Camb. Philos. Soc., 7, 97-112. 12. Hull, J.R. and Cansiz, A. (1999) Vertical and lateral forces between a permanent magnet and a high-temperature superconductor. The numerical modeling and measurement of demagnetization effect in bulk YBCO superconductors subjected to transverse field. IEEE Trans. X. (2011) Experimental and theoretical levitation forces in a superconducting bearing for a real-scale maglev system. IEEE Trans. Appl. Supercond., 21, 3532-3540. 17. Hull, J.R., Passmore, J.L., Mulcahy, T.M., and Rossing, T.D. (1994) Stable levitation of steel rotors using permanent magnets and high-temperature superconductors.

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Calculation of the pressure rise in the cooling tube of a two-phase cooling system during a quench of an indirectly cooled superconducting magnet

Cited by 3 publications

References 4 publications

High‐Energy Physics Particle Detector Magnets

High‐Energy Physics Particle Detector Magnets

Superconducting Detector Magnets for Particle Physics

Superconducting Magnets

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