Corona Discharge Characteristics and Free Gas Generation Law in Insulating Oil

2021 11th International Conference on Power, Energy and Electrical Engineering (CPEEE) Pub Date : 2021-02-26 DOI:10.1109/CPEEE51686.2021.9383339

Yuping Zheng, Xuefei Li, Chonghao Wu, Shuyan Pan, F. Long, Huaidong Lu

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引用次数: 1

Abstract

The gas in the transformer Buchholz relay was caused by the faults operating inside the transformer such as electrical and thermal faults. In order to further use the gas accumulated in the Buchholz relay to determine the fault type in the transformer, this paper conducts lots of experiments based on the corona discharge model in oil, studies the pulse signal change characteristic of the corona discharge in the oil, and analyzes the change characteristic of free gas generated during the development process of the discharge. The experimental results show that the corona discharge type fault in the oil takes 4 hour and 40 minutes to develop to breakdown under a constant voltage of 20kV. There is no free gas generated during most of the experiment process, and it will only appear when the discharge is defined as disruptive discharge. Then a large amount of gas is produced and part of it becomes free gas, which combustible gas component is mainly H2, C2H2, CH4 and CO. At that time, the pulse repetition frequency reaches the magnitude of 0.4C/s, which is a serious fault. This data can be used as an improvement basis for the existing gas protection.

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绝缘油电晕放电特性及游离气体产生规律

变压器布赫兹继电器中的气体是由变压器内部的电气、热故障等故障引起的。为了进一步利用布赫兹继电器中积累的气体来判断变压器的故障类型，本文基于油中电晕放电模型进行了大量实验，研究了油中电晕放电的脉冲信号变化特征，分析了放电发展过程中产生的游离气体的变化特征。实验结果表明，在20kV恒电压条件下，油液中电晕放电型故障发展到击穿需要4小时40分钟。在大部分实验过程中不产生自由气体，只有在放电被定义为破坏性放电时才会出现。此时产生大量气体，部分变为自由气体，其中可燃气体成分主要为H2、C2H2、CH4和CO。此时脉冲重复频率达到0.4C/s量级，是严重故障。该数据可作为现有气体保护的改进依据。

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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2021 11th International Conference on Power, Energy and Electrical Engineering (CPEEE)

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