Density Limits with Different Fuelling Methods in the HL-2A Tokamak

Density Limits with Different Fuelling Methods in the HL-2A Tokamak

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摘要 Density limits with different fuelling methods have been compared in HL-2A, i.e. direct gas puffing and supersonic molecular beam injection （SMBI） from outer midplane, and divertor gas fuelling. The maximum densities for low current discharges are 3.4×10^19 m-3, 4.3×10^19 m-3 and 4.7×10^19 m-3 for the 3 kinds of fuelling methods. The corresponding density ratios to Green- wald density limit are 0.9, 1.1, 1.2, respectively. The behavior of density limit disruption is analyzed as well. Density limits with different fuelling methods have been compared in HL-2A, i.e. direct gas puffing and supersonic molecular beam injection （SMBI） from outer midplane, and divertor gas fuelling. The maximum densities for low current discharges are 3.4×10^19 m-3, 4.3×10^19 m-3 and 4.7×10^19 m-3 for the 3 kinds of fuelling methods. The corresponding density ratios to Green- wald density limit are 0.9, 1.1, 1.2, respectively. The behavior of density limit disruption is analyzed as well.

作者严龙文周艳陈程远曹曾宋显明李伟董云波洪文玉杨青巍段旭如

机构地区 Southwestern Institute of Physics

出处《Plasma Science and Technology》 SCIE EI CAS CSCD 2009年第4期385-388,共4页 等离子体科学和技术（英文版）

基金 National Natural Science Foundation of China (Nos.10675041,10775044) the JSPS-CAS Core-University Program in the field of Plasma and Nuclear Fusion

关键词 density limit fuelling method supersonic molecular beam injection DISRUPTION density limit, fuelling method, supersonic molecular beam injection, disruption

分类号 TL62 [核科学技术—核技术及应用]

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1Hender T C, Wesley J C, Bialek J, et al. 2007, Nucl. Fusion, 47:S128.
2Greenwald M, Terry J L, Wolfe S M, et al. 1988. Nucl. Fusion, 28:2199.
3Loarte A, Lipschultz B, Kukushkin A S, et al. 2007, Nucl. Fusion, 47:S203.
4ITER Physics Basis 1999, Nucl. Fusion, 39:2137.
5Pitcher C S, Stangeby P C. 1997, Plasma Phys. Control. Fusion, 39:779.
6Miyazawa J, Sakamoto R, Masuzaki S, et al. 2008, Nucl. Fusion, 48:015003.
7Greenwald M. 2002, Plasma Phys. Control. Fusion, 44: R27.
8Yah L W, Yao L H, Zhou Y, et al. 2000, Plasma Science and Technology, 2:431.
9Yang Q W, Liu Y, Ding X T, et al. 2007, Nucl. Fusion, 47:S635.
10Yan L W, Cheng J, Zhao K J, et al. 2007, Nucl. Fusion 47:1673.

1Green.,M,荒禾.对托卡马克密度极限的重新考虑[J].国外核聚变与等离子体应用,1990(1):1-10.
2Pork.,RR,罗治.托卡马克实验[J].国外核聚变与等离子体应用,1990(3):1-12.
3Brow.,DL,肖晓.作为高密度极限托卡马克破裂的长时间前兆的约束变差和微…[J].国外核聚变与等离子体应用,1992(5):19-22.
4Vall.,JC,豫川.用各态历经偏滤器稳定密度极限下的托卡马克欧姆放电[J].国外核聚变与等离子体应用,1992(5):23-26.
5Vrie.,PC,姚良骅.TEXTOR—94上再循环对密度极限的影响[J].国外核聚变与等离子体应用,1999(5):24-27.
6Petr.,TW,石建.在DⅢ—D欧姆L模式和ELMH模式运行期间的等离子体密度极…[J].国外核聚变与等离子体应用,1994(6):1-11.
7Petr.,TW,石建.在DⅢ—D欧姆L模式和ELMH模式运行期间等离子体密度…[J].国外核聚变与等离子体应用,1995(1):10-22.
8Shee.,DP,李民.超过慢波密度极限的快波电流驱动[J].国外核聚变与等离子体应用,1991(1):25-29.
9CAO Zeng CUI Chenghe CAI Xiao GAO Xiaoyan DUAN Xuru PAN Yudong LI Quang.Siliconization for Wall Conditioning in the HL-2A Tokamak[J].Southwestern Institute of Physics Annual Report,2005(1):43-44.
10世界空间周的由来[J].河北遥感,2008(4):5-5.

Plasma Science and Technology

2009年第4期

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Density Limits with Different Fuelling Methods in the HL-2A Tokamak

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