复合绝缘子直流电场下的水滴运动及覆冰特性

doi:10.19595/j.cnki.1000-6753.tces.190244

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摘要输电线路绝缘子覆冰威胁着电力系统运行稳定,而绝缘子覆冰形态及速率是预测其闪络发展的关键参数。为准确模拟绝缘子覆冰,该文从水滴运动及捕获角度探究了直流电场对绝缘子覆冰的影响。以复合绝缘子为样品,基于流体力学及电磁场原理建立水滴运动数学模型,计算了水滴在绝缘子表面因为电场力作用发生的轨迹偏移率,以此为基础,计算了有、无电场下绝缘子伞裙边缘及芯棒处的水滴局部碰撞系数β₁分布,结果显示：小风速小水滴半径下,电场作用下的水滴轨迹偏移最大,且对绝缘子芯棒处的β₁值提高百分比超过15%。在人工气候室内对复合绝缘子进行了带电和不带电覆冰试验。结果表明：小水滴半径下的干增长覆冰时,电场对覆冰速率的提高百分比达30%,同时可造成更加粗糙的覆冰表面,但对于大水滴半径下的湿增长覆冰速率影响较小,主要造成弯曲生长的冰棱形态。

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关键词 ：复合绝缘子, 覆冰, 水滴, 碰撞系数, 直流电场

Abstract：Insulator icing threats the stability of power network, and the insulator icing rate and shape are the key parameters for ice flashover predicting. In order to simulate insulator icing accurately, from the point of water droplet movement, taking composite insulator FXBW-35/70 as a sample, this paper built a mathematic model based on the principles of fluid dynamics and electromagnetic field. Accordingly, the shifting rate of water droplets and the local collision efficiency β₁ under charged and uncharged conditions were calculated and analyzed. The result shows that, under the condition of low wind speed and small water droplet radius, the electric field can efficiently promote the shifting rate of droplets and increase the collision efficiency by more than 15%. The related icing experiments under charged and uncharged conditions were conducted in an artificial climate chamber. Moreover, the electric field has a remarkable effect on dry-growth icing with an increasing icing rate of 30% and a rougher icing outer shape. However, under the large droplet size, the wet-growth icing has a small effect from electric field, and the icicle can grow with a bending shape.

Key words： Composite insulator icing water droplet collision efficiency DC electric field

收稿日期: 2019-03-08 出版日期: 2020-05-12

PACS:

TM85

基金资助:国家自然科学基金重点项目（51637002）和国家创新研究群体基金项目（51321063）资助

通讯作者: 韩兴波男,1992年生,博士研究生,研究方向为复杂大气环境下输电线路外绝缘及防护。E-mail: hanxingbocqu@163.com

作者简介: 蒋兴良男,1961年生,教授,博士生导师,研究方向为高电压绝缘技术、气体放电以及输电线路覆冰及防护。E-mail: xljiang@cqu.edu.cn

引用本文:

韩兴波, 蒋兴良, 黄亚飞, 任晓东, 陈宇. 复合绝缘子直流电场下的水滴运动及覆冰特性[J]. 电工技术学报, 2020, 35(9): 2042-2050. Han Xingbo, Jiang Xingliang, Huang Yafei, Ren Xiaodong, Chen Yu. Icing Properties of Composite Insulator and Droplet Movement under DC Electric Field. Transactions of China Electrotechnical Society, 2020, 35(9): 2042-2050.

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