Pattern Analysis of Discharge Characteristics for Condition Evaluation of Polymer Insulators in Fog-Haze Environment

2018 IEEE Conference on Electrical Insulation and Dielectric Phenomena (CEIDP) Pub Date : 2018-10-01 DOI:10.1109/CEIDP.2018.8544782

Kai Zhou, Yong Liu, Kuan Ye, Chunsheng Li, Qian Wang, Yingmiao Cai, Liang Yang, Ruizhe Zhang

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Abstract

With the frequent appearance of fog-haze weather in China, outdoor insulators are exposed to the new contamination problem, which is characterized as the long-term heavy humidity and severe fine polluted particles, which can enhance the probability of the surface discharges, even flashover. An artificial fog-haze system was established to simulate typical fog-haze conditions of outdoor insulators in the operation. The salt fog and fine particles were simultaneously injected into the artificial climate chamber. The fog was generated by an ultrasonic vibration salt fog generator filled with saline water solution. The fine particles were prepared by both conductive and nonconductive particles at different components. When the experimental condition was sustained for different duration, the transition of surface discharges until the flashover was recorded by using an analog to digital (A/D) converter, with the sampling frequency of 10kHz. Then, pattern identification of discharge currents was carried out based on non-linear analysis method to reflect the process and underlying mechanism of surface flashover in fog-haze environments. The obtained results show that with the duration of fog-haze conditions, the flashover voltage show the rapid decreasing tendency, especially with the increase in the conductive components of fine-particles and fog conductivity. The nonlinear analysis of discharge currents can reveal the prominent increase of peak value with the experimental duration, and with the increase in the conductive components of fine-particles and fog conductivity, which is well in accordance with the transition of surface discharges to the flashover. The investigation is beneficial to reflect the discharge characteristics and flashover mechanism of outdoor insulators in fog-haze environments, which is helpful to enhance the operating reliability of outdoor insulator in power system.

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雾霾环境下聚合物绝缘子状态评估放电特性模式分析

随着中国雾霾天气的频繁出现，室外绝缘子暴露出新的污染问题，其特征是长期的重湿度和严重的细污染颗粒，这可以提高表面放电，甚至闪络的概率。建立了模拟运行中室外绝缘子典型雾霾工况的人工雾霾系统。将盐雾和细颗粒物同时注入人工气候室。雾是由充满盐水溶液的超声波振动盐雾发生器产生的。采用导电颗粒和非导电颗粒在不同组分下制备细颗粒。当实验条件持续不同时间时，用模数(A/D)转换器记录表面放电到闪络的转变过程，采样频率为10kHz。然后，基于非线性分析方法对放电电流进行模式识别，以反映雾霾环境下表面闪络的过程和潜在机理。结果表明，随着雾霾条件的持续，闪络电压呈快速下降趋势，特别是随着细颗粒导电成分和雾电导率的增加。放电电流的非线性分析表明，放电峰值随实验时间的延长、细颗粒导电成分和雾电导率的增加而显著增加，这与表面放电向闪络的过渡非常吻合。该研究有利于反映雾霾环境下室外绝缘子的放电特性和闪络机理，有助于提高电力系统室外绝缘子的运行可靠性。

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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2018 IEEE Conference on Electrical Insulation and Dielectric Phenomena (CEIDP)

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