Surface Charge Properties of SiR/SiC Composites in DC and Pulse Combined Field

2018 IEEE Conference on Electrical Insulation and Dielectric Phenomena (CEIDP) Pub Date : 2018-10-01 DOI:10.1109/CEIDP.2018.8544794

Z. R. Yang, B. Du, Z. L. Li, J. Li, H. M. Wanc, S. C. Fanc

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Abstract

The nonlinear conductivity layer has become a highly concerned method to modify the distorted electrical field caused by the complicated cable accessory structure. It is unavoidable for a HVDC transmission system to experience transient overvoltage caused by switching and lightning. A challenge still lies in the understanding of the charge property in the insulation with nonlinear conductivity. This paper focuses on the surface charge property of silicone rubber (SiR)/SiC composites at coupling voltage. The nonlinear conductivity was obtained by blending SiC particles with the SiR matrix. The sample conductivity were measured at 30°C. The surface potential decay (SPD) was measured at 30°C. The carrier mobility and trap distribution were calculated according to the SPD. The results proved that the SiR/SiC composites presented nonlinear conductivity. At DC voltage, the initial potential becomes higher and the decay rate increases. The cross-over phenomenon was observed. The high surface potential caused by the pulse voltage leads to a nonlinear conductivity which immediately dissipates the surface charge. The increase in DC voltage is proven to be more effective in accumulating surface charge. The nonlinear conductivity and the diffusion are two factors concern the initial surface potential.

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SiR/SiC复合材料在直流和脉冲复合场中的表面电荷特性

非线性导电性层已成为修正复杂电缆附件结构引起的电场畸变的一种备受关注的方法。高压直流输电系统不可避免地会出现开关和雷电引起的瞬态过电压。对具有非线性电导率的绝缘体的电荷性质的理解仍然是一个挑战。研究了耦合电压下硅橡胶/SiC复合材料的表面电荷特性。通过将SiC颗粒与SiR基体共混，获得了非线性电导率。在30℃下测量样品的电导率。在30℃下测量表面电位衰减(SPD)。根据SPD计算载流子迁移率和陷阱分布。结果表明，SiR/SiC复合材料具有非线性导电性。在直流电压下，初始电位增大，衰减率增大。观察到交叉现象。脉冲电压引起的高表面电位导致非线性电导率，从而立即耗散表面电荷。直流电压的增加对表面电荷的积累更为有效。非线性电导率和扩散是影响初始表面电位的两个因素。

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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