Development of electromagnetic pellet injector for disruption mitigation of tokamak plasma

doi:10.1088/1674-1056/acc7fb

中国物理B ›› 2023, Vol. 32 ›› Issue (7): 75205-075205.doi: 10.1088/1674-1056/acc7fb

Development of electromagnetic pellet injector for disruption mitigation of tokamak plasma

Feng Li(李峰)¹, Zhong-Yong Chen(陈忠勇)^1,†, Sheng-Guo Xia(夏胜国)², Wei Yan(严伟)¹, Wei-Kang Zhang(张维康)¹, Jun-Hui Tang(唐俊辉)², You Li(李由)¹, Yu Zhong(钟昱)¹, Jian-Gang Fang(方建港)¹, Fan-Xi Liu(刘凡溪)¹, Gui-Nan Zou(邹癸南)¹, Yin-Long Yu(喻寅龙)¹, Zi-Sen Nie(聂子森)¹, Zhong-He Jiang(江中和)¹, Neng-Chao Wang(王能超)¹, Yong-Hua Ding(丁永华)¹, Yuan Pan(潘垣)¹, and the J-TEXT team^1,‡

1 International Joint Research Laboratory of Magnetic Confinement Fusion and Plasma Physics, State Key Laboratory of Advanced Electromagnetic Engineering and Technology, School of Electrical and Electronic Engineering, Huazhong University of Science and Technology, Wuhan 430074, China;
2 Key Laboratory of Pulsed Power Technology Ministry of Education Huazhong University of Science and Technology, School of Electrical and Electronic Engineering, Huazhong University of Science and Technology, Wuhan 430074, China

收稿日期:2022-12-21 修回日期:2023-03-16 接受日期:2023-03-28 出版日期:2023-06-15 发布日期:2023-06-29
通讯作者: Zhong-Yong Chen E-mail:zychen@mail.hust.edu.cn
基金资助:
The authors are very grateful for the help of the J-TEXT team. Project supported by the National Magnetic Confinement Fusion Energy Research and Development Program of China (Grant No. 2019YFE03010004) and the National Natural Science Foundation of China (Grant Nos. 12175078, 11905077, and 51821005).

Development of electromagnetic pellet injector for disruption mitigation of tokamak plasma

1 International Joint Research Laboratory of Magnetic Confinement Fusion and Plasma Physics, State Key Laboratory of Advanced Electromagnetic Engineering and Technology, School of Electrical and Electronic Engineering, Huazhong University of Science and Technology, Wuhan 430074, China;
2 Key Laboratory of Pulsed Power Technology Ministry of Education Huazhong University of Science and Technology, School of Electrical and Electronic Engineering, Huazhong University of Science and Technology, Wuhan 430074, China

Received:2022-12-21 Revised:2023-03-16 Accepted:2023-03-28 Online:2023-06-15 Published:2023-06-29
Contact: Zhong-Yong Chen E-mail:zychen@mail.hust.edu.cn
Supported by:
The authors are very grateful for the help of the J-TEXT team. Project supported by the National Magnetic Confinement Fusion Energy Research and Development Program of China (Grant No. 2019YFE03010004) and the National Natural Science Foundation of China (Grant Nos. 12175078, 11905077, and 51821005).

摘要/Abstract

摘要： Disruption remains to be a serious threat to large tokamaks like the International Thermonuclear Experimental Reactor (ITER). The injection speed of disruption mitigation systems (DMS) driven by high pressure gas is limited by the sound speed of the propellant gas. When extrapolating to ITER-like tokamaks, long overall reaction duration and shallow penetration depth due to low injection speed make it stricter for plasma control system to predict the impending disruptions. Some disruptions with a short warning time may be unavoidable. Thus, a fast time response and high injection speed DMS is essential for large scale devices. The electromagnetic pellet-injection (EMPI) system is a novel massive material injection system aiming to provide rapid and effective disruption mitigation. Based on the railgun concept, EMPI can accelerate the payload to over 1000 m/s and shorten the overall reaction time to a few milliseconds. To verify the injection ability and stability of the EMPI, the prototype injector EMPI-1 has been designed and assembled. The preliminary test has been carried out using a 5.9 g armature to propel a dummy pellet and the results suggest that the EMPI configuration has a great potential to be the DMS of the large scale fusion devices.

关键词: tokamak, disruption mitigation system, electromagnetic pellet-injection (EMPI)

Abstract: Disruption remains to be a serious threat to large tokamaks like the International Thermonuclear Experimental Reactor (ITER). The injection speed of disruption mitigation systems (DMS) driven by high pressure gas is limited by the sound speed of the propellant gas. When extrapolating to ITER-like tokamaks, long overall reaction duration and shallow penetration depth due to low injection speed make it stricter for plasma control system to predict the impending disruptions. Some disruptions with a short warning time may be unavoidable. Thus, a fast time response and high injection speed DMS is essential for large scale devices. The electromagnetic pellet-injection (EMPI) system is a novel massive material injection system aiming to provide rapid and effective disruption mitigation. Based on the railgun concept, EMPI can accelerate the payload to over 1000 m/s and shorten the overall reaction time to a few milliseconds. To verify the injection ability and stability of the EMPI, the prototype injector EMPI-1 has been designed and assembled. The preliminary test has been carried out using a 5.9 g armature to propel a dummy pellet and the results suggest that the EMPI configuration has a great potential to be the DMS of the large scale fusion devices.

Key words: tokamak, disruption mitigation system, electromagnetic pellet-injection (EMPI)

中图分类号: (Tokamaks, spherical tokamaks)

52.55.Fa

Feng Li(李峰), Zhong-Yong Chen(陈忠勇), Sheng-Guo Xia(夏胜国), Wei Yan(严伟), Wei-Kang Zhang(张维康), Jun-Hui Tang(唐俊辉), You Li(李由), Yu Zhong(钟昱), Jian-Gang Fang(方建港), Fan-Xi Liu(刘凡溪),Gui-Nan Zou(邹癸南), Yin-Long Yu(喻寅龙), Zi-Sen Nie(聂子森), Zhong-He Jiang(江中和),Neng-Chao Wang(王能超), Yong-Hua Ding(丁永华), Yuan Pan(潘垣), and the J-TEXT team. Development of electromagnetic pellet injector for disruption mitigation of tokamak plasma[J]. 中国物理B, 2023, 32(7): 75205-075205.

参考文献

[1] Lehnen M, Aleynikova K, Aleynikov P B, Campbell D J, Drewelow P, Eidietis N W, Gasparyan Y, Granetz R S, Gribov Y, Hartmann N, Hollmann E M, Izzo V A, Jachmich S, Kim S H, Kočan M, Koslowski H R, Kovalenko D, Kruezi U, Loarte A, Maruyama S, Matthews G F, Parks P B, Pautasso G, Pitts R A, Reux C, Riccardo V, Roccella R, Snipes J A, Thornton A J and de Vries P C 2015 J. Nucl. Mater. 463 39
[2] Lehnen M, Jachmich S and Kruezi U 2020 IAEA Technical Meeting on Plasma Disruptions and their Mitigation, July 20-23, 2020, Vienna, Austria
[3] Hollmann E M, Aleynikov P B, Fülöp T, Humphreys D A, Izzo V A, Lehnen M, Lukash V E, Papp G, Pautasso G, Saint-Laurent F and Snipes J A 2015 Phys. Plasmas 22 021802
[4] Lehnen M, Alonso A, Arnoux G, Baumgarten N, Bozhenkov S A, Brezinsek S, Brix M, Eich T, Gerasimov S N, Huber A, Jachmich S, Kruezi U, Morgan P D, Plyusnin V V, Reux C, Riccardo V, Sergienko G and Stamp M F 2011 Nucl. Fusion 51 123010
[5] Bakhtiari M, Kawano Y, Tamai H, Miura Y, Yoshino R and Nishida Y 2002 Nucl. Fusion 42 1197
[6] Lukash V E, Mineev A B and Morozov D K 2007 Nucl. Fusion 47 1476
[7] Commaux N, Baylor L R, Jernigan T C, Hollmann E M, Parks P B, Humphreys D A, Wesley J C and Yu J H 2010 Nucl. Fusion 50 112001
[8] Herfindal J L, Shiraki D, Baylor L R, Eidietis N W, Hollmann E M, Lasnier C J and Moyer R A 2019 Nucl. Fusion 59 106034
[9] Vega J, Dormido-Canto S, López J M, Murari A, Ramírez J M, Moreno R, Ruiz M, Alves D and Felton R 2013 Fusion Eng. Des. 88 1228
[10] Hawke R S 1983 J. Vac. Sci. Technol. A 1 969
[11] Combs S K, Meitner S J, Baylor L R, Caughman J, Commaux N, Fehling D T, Foust C R, Jernigan T C, McGill J M, Parks P B and Rasmussen D A 2010 IEEE Trans. Plasma Sci. 38 400
[12] Chen C, Lan T, Xiao C, Zhuang G, Kong D, Zhang S B, Zhang S, Ding W, Wu Z, Mao W, Wu J, Xu H, Wu J, Zu Y, Zhang D, Wei Z, Wen X, Zhou C, Liu A, Xie J, Li H and Liu W 2022 Plasma Sci. Technol. 24 045102
[13] Raman R, Lay W S, Jarboe T, Menard J and Ono M 2018 Nucl. Fusion 59 016021
[14] Raman R, Lunsford R, Clauser C F, Jardin S C, Menard J E and Ono M 2021 Nucl. Fusion 61 126034
[15] Raman R, Jarboe T R, Menard J E, Gerhardt S P, Ono M, Baylor L and Lay W S 2015 Fusion Sci. Technol. 68 797
[16] Zhongyong C, Weikang Z, Junhui T, Feng L and Shengguo X 2022 Trans. China Electrotech. Soc. 037 5056

Development of electromagnetic pellet injector for disruption mitigation of tokamak plasma

Development of electromagnetic pellet injector for disruption mitigation of tokamak plasma

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