基于真空开断的145 kV无氟环保型断路器绝缘特性分析*

doi:10.13385/j.cnki.vacuum.2025.06.08

Abstract

Abstract: Finding environmentally friendly alternatives to SF₆ circuit breakers is an urgent issue in the field of high-voltage switchgear. This article proposes a design concept and overall plan for a fluorine free environmentally friendly circuit breaker using dry air as the insulating gas. A numerical simulation model of 145 kV fluorine free environmentally friendly circuit breaker was established using 3D design software, and numerical simulatlon software was used for simulation analysis to obtain the electric field distribution of key parts of the circuit breaker's external insulation. The research results show that the electric field strength of the outgoing conductor supported by the three-phase dynamic and static ends of the circuit breaker is the highest under different working conditions. By optimizing the structure of the dynamic and static end supports and the connection parts of the conductor, the maximum electric field strength of the external insulation structure of the circuit breaker was reduced by 34.40%, which provides a theoretical basis for the development of 145 kV fluorine free environmentally friendly circuit breakers.

Key words: fluorine free environmentally friendly circuit breaker, dry air, electric field analysis, structural optimization

CLC Number: TM561

CHAI Ziyuan, WANG Wenbo, WEI Jianwei, CHAI Yinghui, GAO Zhenkui, SHI Chunling, ZHANG Qinwei. Analysis of Insulation Characteristics of 145 kV Fluorine-Free Environmentally Friendly Circuit Breaker Based on Vacuum Breaking[J].VACUUM, 2025, 62(6): 54-61.

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Analysis of Insulation Characteristics of 145 kV Fluorine-Free Environmentally Friendly Circuit Breaker Based on Vacuum Breaking

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