Performance of first insert coil with REBCO CICC sub-size cable exceeding 6 kA at 21 T magnetic field

Abstract The Institute of Plasma Physics at the Chinese Academy of Sciences is developing the REBCO cable in conduit conductor (CICC) technology for applications in next-generation nuclear fusion devices. The aim is to develop a CICC comprised of six REBCO sub-cables to satisfy the requirements of o...

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Published inSuperconductor science & technology Vol. 35; no. 11; pp. 114003 - 114010
Main Authors Zhou, Chao, Jin, Huan, Fang, Zhen, Xiao, Guanyu, Ma, Hongjun, Liu, Fang, Liu, Huajun, Ma, Tao, Tan, Yunfei, Chen, Wenge, Wu, Zuojiafeng, Kanazawa, Shintetsu, Nijhuis, Arend, Devred, Arnaud, Li, Jiangang, Qin, Jinggang
Format Journal Article
LanguageEnglish
Published IOP Publishing 01.11.2022
Subjects
electromagnetic load
high field
REBCO insert solenoid
warm-up-cool-down treatment
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Abstract Abstract The Institute of Plasma Physics at the Chinese Academy of Sciences is developing the REBCO cable in conduit conductor (CICC) technology for applications in next-generation nuclear fusion devices. The aim is to develop a CICC comprised of six REBCO sub-cables to satisfy the requirements of operation with a current of around 40 kA and a peak field of up to 20 T. To qualify the performance of the sub-size REBCO cable to be used in the CICC, two 25-turn insert solenoids have been designed, manufactured and tested at a current exceeding 6 kA subjected in a background field supplied by a water-cooled resistive magnet. The insert solenoid, wound from a 11.5 m long REBCO CORC ® cable, was designed to investigate its current carrying capacity under high field and electromagnetic (EM) load at 4.2 K. Tests were performed under a background magnetic field up to 18.5 T, resulting in a peak magnetic field on the innermost layer turns of around 21.1 T at an operating current of 6.3 kA. The effects of operation with cyclic EM loads were tested by repeated current ramps to around 95% of the critical current. Moreover, the V – I characteristics were measured at 77 K and the self-field, to check the effects from warm-up and cool-down (WUCD) cycles between room temperature and 77 K with liquid nitrogen. The results show no obvious degradation after dozens of high-current test cycles in background fields ranging from 10 T to 18.5 T. The insert solenoid demonstrates the stable operation of the REBCO sub-size cable for CICC with EM loads of about 90 kN m −1 and WUCD cycles between room temperature and 77 K. These promising results indicate the potential of this technology for further applicationsin particular, for full-size CICC for high-performance fusion magnets.
AbstractList Abstract The Institute of Plasma Physics at the Chinese Academy of Sciences is developing the REBCO cable in conduit conductor (CICC) technology for applications in next-generation nuclear fusion devices. The aim is to develop a CICC comprised of six REBCO sub-cables to satisfy the requirements of operation with a current of around 40 kA and a peak field of up to 20 T. To qualify the performance of the sub-size REBCO cable to be used in the CICC, two 25-turn insert solenoids have been designed, manufactured and tested at a current exceeding 6 kA subjected in a background field supplied by a water-cooled resistive magnet. The insert solenoid, wound from a 11.5 m long REBCO CORC ® cable, was designed to investigate its current carrying capacity under high field and electromagnetic (EM) load at 4.2 K. Tests were performed under a background magnetic field up to 18.5 T, resulting in a peak magnetic field on the innermost layer turns of around 21.1 T at an operating current of 6.3 kA. The effects of operation with cyclic EM loads were tested by repeated current ramps to around 95% of the critical current. Moreover, the V – I characteristics were measured at 77 K and the self-field, to check the effects from warm-up and cool-down (WUCD) cycles between room temperature and 77 K with liquid nitrogen. The results show no obvious degradation after dozens of high-current test cycles in background fields ranging from 10 T to 18.5 T. The insert solenoid demonstrates the stable operation of the REBCO sub-size cable for CICC with EM loads of about 90 kN m −1 and WUCD cycles between room temperature and 77 K. These promising results indicate the potential of this technology for further applicationsin particular, for full-size CICC for high-performance fusion magnets.
Author Chen, Wenge
Zhou, Chao
Tan, Yunfei
Devred, Arnaud
Qin, Jinggang
Li, Jiangang
Ma, Hongjun
Xiao, Guanyu
Jin, Huan
Fang, Zhen
Nijhuis, Arend
Liu, Huajun
Ma, Tao
Wu, Zuojiafeng
Liu, Fang
Kanazawa, Shintetsu
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Snippet Abstract The Institute of Plasma Physics at the Chinese Academy of Sciences is developing the REBCO cable in conduit conductor (CICC) technology for...
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StartPage 114003
SubjectTerms electromagnetic load
high field
REBCO insert solenoid
warm-up-cool-down treatment
Title Performance of first insert coil with REBCO CICC sub-size cable exceeding 6 kA at 21 T magnetic field
URI https://iopscience.iop.org/article/10.1088/1361-6668/ac8cbc
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