温度梯度场对高直流电压下聚乙烯中空间电荷及场强畸变的影响

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摘要高压电缆运行中由于导体发热引起绝缘由内到外形成温度梯度。直流电压下温度梯度的存在必然会影响电荷的注入和迁移, 同时引起绝缘电阻的梯度变化进而引起场强的梯度变化, 加剧了位于绝缘层外表面的电荷积聚和场强畸变, 降低了电缆的使用寿命。因此研究温度梯度场下直流绝缘中空间电荷分布及场强畸变特性, 对新型直流电缆绝缘设计具有较高的理论和工程应用价值。本文测量了70kV/mm场强、0.5mm厚聚乙烯试样两面在不同温度差(Δ T=0～40℃)所形成的温度梯度场下空间电荷分布和场强畸变特性。结果表明：当温度差达到40℃时, 试样体内最大畸变场强达到230kV/mm, 即场强增加了2.28倍。同时测量结果表明温度差的增加与最大畸变场强近似呈线性增长关系。

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	陈曦
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	彭宗仁
	成永红

关键词 ：聚乙烯, 空间电荷, 温度梯度, 直流电场, 畸变

Abstract：Temperature gradient across cable thickness is caused by Joule heat originating from the current in the HV cable conductor, which must influence the injection and migration of charge, lead to the gradient of insulation resistance and then the gradient of electrical field. As a result, the lifetime of cable is decreased due to charge accumulation and stress distortion at the outer surface of insulation. So, it is a high theory and engineering values for new direct current (DC) cable insulation design to study the space charge accumulation and stress distortion in cable insulation under DC stress and temperature gradient. In this paper, space charge profiles and field distributions of polyethylene (PE) with thickness of 0.5mm are measured under the different temperature difference(Δ T=0～40℃), when DC stress of 70kV/mm is applied. The test results show that the maximum electrical field reaches 230kV/mm, that is, increases 2.28 times when the temperature difference is 40℃. At the same time, the maximum electrical field increases linearly with the temperature difference.

Key words： Polyethylene space charge temperature gradient DC stress distortion

收稿日期: 2009-09-11 出版日期: 2014-03-07

PACS:

TM215.1

基金资助:国家自然科学基金资助项目(50907050)。

作者简介: 陈曦女, 1983年生, 博士研究生, 主要研究方向为聚合物绝缘材料的测量与改性技术。王霞女, 1976年生, 讲师, 博士, 主要研究方向为聚合物绝缘中空间电荷测量、绝缘破坏机理与改性技术。

引用本文:

陈曦, 王霞, 吴锴, 彭宗仁, 成永红. 温度梯度场对高直流电压下聚乙烯中空间电荷及场强畸变的影响[J]. 电工技术学报, 2011, 26(3): 13-19. Chen Xi, Wang Xia, Wu Kai, Peng Zongren, Cheng Yonghong. Space Charge Accumulation and Stress Distortion in Polyethylene Under High DC Voltage and Temperature Gradient. Transactions of China Electrotechnical Society, 2011, 26(3): 13-19.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2011/V26/I3/13

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