Simulation Analysis of Temperature Rise of 10kV Atmospheric Pressure Sealed Air Insulated Switch Cabinet

2023 5th Asia Energy and Electrical Engineering Symposium (AEEES) Pub Date : 2023-03-23 DOI:10.1109/AEEES56888.2023.10114120

Hengzheng Li, Zilan He, Sixiang Chen, Guowei Guo, Jing Huang, G. Sun, Jianmao Chen, Xiyao Min

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Abstract

In this paper, a simulation model was established for the 10kV atmospheric pressure sealed air insulated switch cabinet in COMSOL. The multi-physical field simulation of electrothermal coupling was carried out by finite element analysis method, and the internal temperature rise of the switch cabinet was obtained. Firstly, the internal temperature distribution rule of switch cabinet during static state operation is studied, and it is concluded that the highest temperature rise inside switch cabinet is located at the circuit breaker contacts, and the temperature decreases gradually from the circuit breaker contacts to both ends with the conductor rod of circuit breaker. Then the internal temperature distribution of the switchgear under short-circuit condition is studied. It is concluded that the temperature of the breaker contacts increases rapidly with the increase of short circuit time, and the temperature may lead to the damage of the contacts due to excessive temperature. The research results of this paper can provide some reference for temperature rise monitoring, fault diagnosis and maintenance scheme design of the switchgear.

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10kV常压密封空气绝缘开关柜温升仿真分析

本文对COMSOL公司10kV常压密封空气绝缘开关柜建立了仿真模型。采用有限元分析方法对电热耦合进行了多物理场模拟，得到了开关柜内部温升。首先，对开关柜静态运行时内部温度分布规律进行了研究，得出开关柜内部温升最高的位置在断路器触点处，从断路器触点到断路器导体杆两端温度逐渐降低的结论。然后研究了短路工况下开关柜的内部温度分布。得出断路器触点温度随短路时间的增加而迅速升高，温度过高可能导致触点损坏。本文的研究成果可为开关柜的温升监测、故障诊断和维护方案设计提供一定的参考。

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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2023 5th Asia Energy and Electrical Engineering Symposium (AEEES)

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