Abstract:In this paper, a RC charge collector is proposed and the initial plasma characteristics of TVS are experimentally analyzed. The experimental results indicate that a spike appears on the waveform of initial plasma current after triggering voltage appalling, and the waveform of initial plasma current oscillating decreases to zero after the trigger voltage breaking, and the charge of initial plasma includes electronic and ionic charge and the electronic charge is slightly more than ionic charge. The charge of initial plasma is affected by trigger voltage, trigger current, and trigger charge. From experiments, it is shown that the charge of initial plasma increases with the increment of trigger voltage, trigger current and trigger charge, but the ratio of charge of initial plasma to trigger charge decreases with increasing in trigger voltage and the ratio with negative trigger is slight larger than the ratio with positive trigger. After the initial plasma being ejected to the vacuum gap of triggered vacuum switch, they expand in the vacuum gap. The expansion time, during the initial plasma leave the trigger to arrive at anode of triggered vacuum switch, decreases with the increment of trigger voltage below 8kV, and then the expansion time remains stable during 66-69ns with the trigger voltage keeping on growing. And also the expansion time increases from 50ns to 70ns with expanding of the vacuum gap distance of triggered vacuum switch from 0.5mm to 8mm.
胡上茂, 姚学玲, 陈景亮. 沿面闪络触发真空开关初始等离子体特性实验[J]. 电工技术学报, 2012, 27(9): 271-276.
Hu Shangmao, Yao Xueling, Chen Jingliang. An Experimental Study on Initial Plasma Characteristics of Surface Flashover Triggered Vacuum Switch. Transactions of China Electrotechnical Society, 2012, 27(9): 271-276.
[1] Lafferty J M. Triggered vacuum gaps[J]. Proceedings of the Institute of Electrical and Electronics Engineers, 1966, 54(1): 23-32. [2] Vidyardh N, Rau R S N. Self-excited triggered vacuum gap[J]. Journal of Physics E-Scientific Instruments, 1973, 6(8): 695-697. [3] Kamakshaiah S, Rau R S N. Delay characteristics of a simple triggered vacuum gap[J]. Journal of Physics D-Applied Physics, 1975, 8(12): 1426-1429. [4] Raju G R G, Hackam R, Benson F A. Breakdown mechanisms and electrical-properties of triggered vacuum gaps[J]. Journal of Applied Physics, 1976, 47(4): 1310-1317. [5] Boxman R L. Triggering mechanisms in triggered vacuum gaps[J]. IEEE Transactions on Electron Devices, 1977, 24(2): 122-128. [6] Kamakshaiah S, Rau R S N. Low-voltage and high- current delay characteristics of a simple triggered vacuum gap[J]. Journal of Physics D-Applied Physics, 1977, 10(7): 1017-1022. [7] Raju G. R G, Hackam R, Benson F A. Firing characteristics of a triggered vacuum gap employing a dielectric coated with a semiconducting layer[J]. Journal of Applied Physics, 1977, 48(3): 1101-1105. [8] Raju G R G, Hackam R, Benson F A. Probability of firing of a triggered vacuum gap incorporating barium-titanate[J]. International Journal of Electronics, 1977, 42(2): 185-191. [9] Raju G R G, Hackam R, Benson F A. Time-delay to firing of a triggered vacuum gap with barium-titanate in trigger gap[J]. Proceedings of the Institution of Electrical Engineers, 1977, 124(9): 828-832. [10] Yao X L, Chen J L, Sun W. Experimental study on triggering characteristics of a surface flashover triggered vacuum switch[J]. Plasma Science & Technology, 2010, 12(6): 734-737. [11] Green A J, Christopoulos C. Plasma buildup and breakdown delay in a triggered vacuum gap[J]. IEEE Transactions on Plasma Science, 1979, 7(2): 111-115. [12] Earley L M, Scott G L. Firing characteristics of a low-jitter miniature laser-triggered vacuum switch[J]. IEEE Transactions on Plasma Science, 1990, 18(2): 247-249. [13] Zhou Z Y, Duan X Y, Liao M F, et al. Plasma stability in a triggered vacuum switch[J]. IEEE Transactions on Plasma Science, 2009, 37(4): 555-559. [14] Alferov D F, Kozmidi P K, Sidorov V A. Electric strength of a triggered vacuum switch[J]. Instruments and Experimental Techniques, 2010, 53(1): 89-94. [15] Zhou Z Y, Liao M F, Zou J Y, et al. Initial plasma development of field-breakdown triggered vacuum switch[J]. IEEE Transactions on Plasma Science, 2011, 39(1): 360-363. [16] 何俊佳, 邹积岩, 王海, 等. 触发真空开关中初始等离子体的产生和扩展[J]. 高压电器, 1996(6): 3-5. He Junjia, Zou Jiyan, Wang Hai, et al. Production and expansion of primary plasma in triggered vacuum switches[J]. High Voltage Apparatus, 1996(6): 3-5. [17] Neff S, Wright S, Ford J, et al. Faraday cup measurements of the energy spectrum of laser- accelerated protons[J]. IEEE Transactions on Plasma Science, 2008, 36(5): 2775-2779.