Evaluation of Gas Flow by Multi-point Pressure Measurement using a Self-blast Gas Circuit Breaker Model

2019 5th International Conference on Electric Power Equipment - Switching Technology (ICEPE-ST) Pub Date : 2019-10-01 DOI:10.1109/ICEPE-ST.2019.8928777

H. Kotsuji, T. Sakuyama, M. Terada, H. Urai

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Abstract

The self-blast type gas circuit breaker obtains high pressure by using arc energy to blow high pressure gas into arc. To understand the self-blast phenomenon, it is important to explain the characteristics of the arc as a pressure source for building up pressure in a thermal puffer chamber. In this study, we carried out multi-point pressure measurements to investigate the pressure build-up mechanism and blowing process quantitatively. The measurement points were at the thermal puffer chamber, mechanical puffer chamber, flow path, and in the nozzle throat. It was confirmed that the nozzle throat works as a pressure source at a high current due to arc plasma and the switch to the blowing phase a few milliseconds before current zero. The pressure ratio between the thermal puffer and nozzle throat were well agreed with the pressure ratio calculated from the sound speed condition just around current zero. Therefore formation of sound speed flow in nozzle throat was confirmed, and super sonic flow was established in the nozzle divergent area.

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用自爆气体断路器模型进行多点压力测量的气体流量评估

自爆式气体断路器是利用电弧能量将高压气体吹成电弧而获得高压的。为了理解自爆现象，重要的是要解释电弧作为压力源的特性，在热鼓风机室中建立压力。在本研究中，我们进行了多点压力测量，以定量地研究压力积聚机制和吹塑过程。测量点分别位于热鼓风机室、机械鼓风机室、流道和喷嘴喉部。实验证实，在电弧等离子体产生的高电流下，喷嘴喉部作为压力源工作，并在电流为零前几毫秒切换到吹气阶段。热鼓风机与喷嘴喉道之间的压力比与声速条件下的零电流附近的压力比吻合较好。由此证实了声速流在喷管喉部的形成，并在喷管发散区建立了超声速流。

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2019 5th International Conference on Electric Power Equipment - Switching Technology (ICEPE-ST)

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