直接氟化同时提高环氧绝缘子直流闪络性能和耐电弧性能

2020 IEEE International Conference on High Voltage Engineering and Application (ICHVE) Pub Date : 2020-09-06 DOI:10.1109/ICHVE49031.2020.9279903

Wenbo Huang, Kang Ping Chen, Z. An, Xin Wang, F. Zheng, Yewen Zhang

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引用次数: 0

摘要

如何有效抑制高压气体绝缘系统中环氧隔层上的电荷积累，是电气绝缘领域研究人员和工程人员最关心的问题之一，对发展高压直流/暖通GIL或GIS具有重要意义。为了抑制环氧绝缘子上的电荷积累，提高其直流闪电性能，同济大学早在2010年下半年就进行了环氧绝缘子直接氟化的首次尝试。在接下来的十年中，开展了一系列的研究，从样品和模型绝缘子到实际绝缘子，特别是在提高直流闪络性能和抗电弧性能方面。目前取得的研究成果将为今后直接氟化法改善环氧隔离剂的实际性能提供有力支持。本报告回顾了一系列研究的结果，以及从材料成分和结构的变化来看，性能改善背后的机制。

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Simultaneously Enhanced dc Flashover Performance and Arc Resistance of Epoxy Insulators by Direct Fluorination

Effective suppression of charge accumulation on epoxy spacers in high voltage gas insulated systems is one of the most concerned problems for the researchers and engineers in the field of electrical insulation, being of great significance for the development of HVDC/HVAC GIL or GIS. In order to suppress charge accumulation on the epoxy insulator and to improve its dc flashover performance, the first attempt to direct fluorination of epoxy insulators has been carried out as early as the second half of 2010 in Tongji University. In the next decade, a series of studies have been carried out, ranging from samples and model insulators to actual insulators, especially in terms of improving dc flashover performance and arc resistance. The research results achieved so far will provide strong support for the improvement by direct fluorination in practical performance of epoxy spacers in the future. This report reviews the results of a series of studies and the mechanisms behind the property/ performance improvements in terms of the changes in material composition and structure.

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2020 IEEE International Conference on High Voltage Engineering and Application (ICHVE)

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