Quench in a pancake coil wound with REBCO Roebel cable: model and validation
Quench in a pancake coil wound with REBCO Roebel cable: model and validation
Roebel cables assembled with high temperature superconducting tapes are a promising technology for several AC and DC applications. Their mechanical flexibility and compact design, combined with the capability of REBCO tapes to carry high transport currents in intense magnetic fields make them suitable for the application both in power devices and high field magnets. In this paper, an electro-thermal finite-element model developed at the University of
Bologna (Italy) is described. The model allows computing the current and heat redistribution between the strands of the cable and from turn to turn inside a winding through non-uniform distributed thermal and electrical resistances between strands. The tape is ‘homogenized’ so as to create an anisotropic continuum model through a previously developed homogenization
technique. The model is validated by comparison with quench tests performed on a well instrumented 7-turn pancake coil wound with a 2 m long Roebel cable composed of 15 REBCO tapes. The experiments were performed at the University of Southampton (UK) in the frame of the R&D activities of the EuCARD-2 project. The quench decision time, the temperature and electric potential evolution, the current and heat redistribution between strands in the event of a quench are analysed and discussed in the present study.
HTS, quench, Roebel, modelling
Cavallucci, Lorenzo
c7db63fe-4607-4dbc-a2c1-71778993caba
Breschi, Marco
b605754a-fe6d-4aa3-9b96-7113a7b0a4c4
Ribani, Pier Luigi
e0538146-7705-4ab8-b246-7a99a5806258
Zhang, Qingbo
d9e5bf57-ea39-42e9-8056-eb2be5845e3f
Yang, Yifeng
4cac858a-e0c0-4174-a839-05ca394fc51f
Cavallucci, Lorenzo
c7db63fe-4607-4dbc-a2c1-71778993caba
Breschi, Marco
b605754a-fe6d-4aa3-9b96-7113a7b0a4c4
Ribani, Pier Luigi
e0538146-7705-4ab8-b246-7a99a5806258
Zhang, Qingbo
d9e5bf57-ea39-42e9-8056-eb2be5845e3f
Yang, Yifeng
4cac858a-e0c0-4174-a839-05ca394fc51f
Cavallucci, Lorenzo, Breschi, Marco, Ribani, Pier Luigi, Zhang, Qingbo and Yang, Yifeng
(2021)
Quench in a pancake coil wound with REBCO Roebel cable: model and validation.
Superconductor Science and Technology, 34 (10).
(doi:10.1088/1361-6668/ac1bf7).
Abstract
Roebel cables assembled with high temperature superconducting tapes are a promising technology for several AC and DC applications. Their mechanical flexibility and compact design, combined with the capability of REBCO tapes to carry high transport currents in intense magnetic fields make them suitable for the application both in power devices and high field magnets. In this paper, an electro-thermal finite-element model developed at the University of
Bologna (Italy) is described. The model allows computing the current and heat redistribution between the strands of the cable and from turn to turn inside a winding through non-uniform distributed thermal and electrical resistances between strands. The tape is ‘homogenized’ so as to create an anisotropic continuum model through a previously developed homogenization
technique. The model is validated by comparison with quench tests performed on a well instrumented 7-turn pancake coil wound with a 2 m long Roebel cable composed of 15 REBCO tapes. The experiments were performed at the University of Southampton (UK) in the frame of the R&D activities of the EuCARD-2 project. The quench decision time, the temperature and electric potential evolution, the current and heat redistribution between strands in the event of a quench are analysed and discussed in the present study.
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More information
Accepted/In Press date: 9 August 2021
e-pub ahead of print date: 24 August 2021
Keywords:
HTS, quench, Roebel, modelling
Identifiers
Local EPrints ID: 487284
URI: http://eprints.soton.ac.uk/id/eprint/487284
ISSN: 0953-2048
PURE UUID: afc2a47a-932b-408c-a179-f95d37b6d945
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Date deposited: 16 Feb 2024 17:16
Last modified: 18 Mar 2024 02:39
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Contributors
Author:
Lorenzo Cavallucci
Author:
Marco Breschi
Author:
Pier Luigi Ribani
Author:
Qingbo Zhang
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