Spatiotemporal Evolution of Electrical Conductivity in Current-Limiting-Fuse Arc

Journal of Physics D Pub Date : 2023-10-03 DOI:10.1088/1361-6463/acf9b2

Yuki Inada, Yusuke Fukai, Naoki Takayasu, Yusuke Nakano, Shungo Zen, Wataru Ohnishi, Yasushi Yamano, Mitsuaki Maeyama, Naoto Kodama

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Abstract

Abstract To improve the interruption capacity of a current-limiting fuse, a detailed diagnosis of the spatial electrical conductivity distribution inside the fuse arc under the current limiting phase around current zero is required, because this distribution determines the distribution of transient recovery voltage inside the fuse. However, well-established methodologies applicable to fuse arcs are lacking, so the spatial distribution remains unknown. This study presents a borescope-integrated spectroscopic system that simultaneously obtains single-shot recordings of the axial distributions of the electron density and arc temperature in the fuse arc just before extinction. Combining the electron densities and arc temperatures, we can identify the fuse arc composition and hence calculate the axial electrical conductivity distribution under the first Chapman–Enskog approximation. The electrical conductivity provided by this systematic methodology includes no large uncertainties, thus demonstrating its superiority against previous estimation methods of the electrical conductivity.

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限流熔断器电弧中电导率的时空演化

摘要为了提高限流熔断器的断流能力，需要对限流相下熔断器电弧内部的空间电导率分布进行详细的诊断，因为该分布决定了熔断器内部瞬态恢复电压的分布。然而，由于缺乏适用于熔断电弧的完善的方法，因此空间分布仍然是未知的。本研究提出了一种管镜集成光谱系统，该系统可同时获得熔断器灭弧前电弧中电子密度和电弧温度轴向分布的单次记录。结合电子密度和电弧温度，我们可以确定熔断器的电弧成分，从而计算出第一Chapman-Enskog近似下的轴向电导率分布。该系统方法所提供的电导率不包含大的不确定性，从而表明其优于以往的电导率估计方法。

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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Journal of Physics D

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