Investigation on the high current interruption principle for series gaps of vacuum gap and CO2 gas gap

2016 27th International Symposium on Discharges and Electrical Insulation in Vacuum (ISDEIV) Pub Date : 2016-09-01 DOI:10.1109/DEIV.2016.7763962

Xian Cheng, Zhanqing Chen, G. Ge, Lian-yao Jiao

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Abstract

The current interruption capacity of gas gap can be enhanced by series connecting with vacuum gap in hybrid circuit breaker. For the purpose of compensating the inferior interruption performance of CO2 gas gap, as the substitute for SF6 gas gap, the interruption principle and the dielectric strength recovery process of the series gaps of vacuum gap and CO2 gas gap are studied in this paper. Based on the established test prototype, tests are carried on series gaps to investigate the influences of various arcing times, voltage-dividing capacitor, and CO2 gas pressure on its interruption performance via synthetic test circuit system. The test results convey that, CO2 gas gap with gas pressure at 0.8 Mpa can recover its dielectric strength faster and withstand higher recovery voltage under the effect of voltage-dividing capacitor while vacuum gap undertakes initial transient recovery voltage. But limited by the simple structure of gas interrupter and the interruption performance of CO2 gas, CO2 gas can't recover its dielectric strength rapidly.

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真空间隙与CO2气隙串联间隙大电流中断原理研究

在混合式断路器中，气隙与真空隙串联可提高气隙的断流能力。为了弥补CO2气隙中断性能较差的缺点，本文研究了真空气隙与CO2气隙串联缝隙的中断原理和介电强度恢复过程，作为SF6气隙的替代品。在已建立的试验样机的基础上，通过综合试验电路系统对串联间隙进行了试验，研究了不同电弧次数、分压电容和CO2气体压力对其中断性能的影响。试验结果表明，气体压力为0.8 Mpa时，CO2气隙在分压电容作用下能更快地恢复其介电强度，承受更高的恢复电压，而真空隙承担初始瞬态恢复电压。但受气体中断器结构简单和CO2气体中断性能的限制，CO2气体的介电强度不能迅速恢复。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 27th International Symposium on Discharges and Electrical Insulation in Vacuum (ISDEIV)

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