基于M-W极化模型的低电场极性反转下XLPE/硅橡胶空间电荷与电场分布特性研究

doi:10.19595/j.cnki.1000-6753.tces.221231

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摘要相比于单一介质的电缆绝缘,高压直流电缆附件复合绝缘因介质不连续性更易在界面处积聚空间电荷。在基于电网换相器的高压直流（LCC-HVDC）输电系统中,进行潮流反转调整时需改变电压极性,高压直流电缆附件将会承受极性反转电场,尽管是短时的,但由于空间电荷的累积效应也会在局部产生极高的电场,严重影响绝缘性能。为此,该文利用实验获得交联聚乙烯（XLPE）与硅橡胶（SR）电导率与电场强度的变化关系,基于Maxwell-Wagner（M-W）极化模型仿真研究了低电场极性反转下XLPE/SR双层介质中空间电荷与电场的分布特性。结果表明：室温下,SR的低电场电导率要高于XLPE,且SR电导率受电场强度的影响相对较小而XLPE则较大。由于界面电荷极性变化滞后于电压极性变化,极性反转期间界面处残留的负极性电荷造成SR中出现最大瞬态电场;电压极性反转越快,XLPE/SR界面残留的负极性电荷越多,SR中的最大瞬态电场强度越高;外施电压越高,由于SR与XLPE的电导率比值降低,SR中的最大瞬态电场畸变率越小。

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关键词 ：直流电缆附件, 极性反转, 电导率, 空间电荷, 电场畸变, Maxwell-Wagner极化模型

Abstract：As the key equipment of connecting the cable system, high voltage direct current (HVDC) cable accessory has become the weakest insulation point of the cable system due to the composite insulation composed of different dielectrics. Compared with cable body insulation of a single dielectric, the HVDC cable accessory of composite insulation is more easily to accumulate space charges at the interface due to the discontinuity of dielectric. In the line commutated converter high voltage direct current (LCC-HVDC) transmission system, the voltage polarity needs to be reversed when performing the power flow reversal adjustment, and cable accessories will withstand polarity reversal electric field. Although it is temporary, an extremely high electric field would be applied locally due to the cumulative effect of space charge, which threatens the safety of cable system.
Firstly, the conductivities of cross-linked polyethylene (XLPE) and silicone rubber (SR) under different electric fields were measured at room temperature. Then, fitting these experimental data, the conductivity model parameters of XLPE and SR could be obtained. Finally, the finite element method was used to study the space charge and electric field distribution characteristics of XLPE/SR under polarity reversal voltage based on the Maxwell-Wagner model. Furthermore, the effects of voltage reversal time and voltage amplitude on the interface charges and the maximal transient electric field were discussed.
The conductivity test results show that, the conductivity of SR is higher than XLPE within 14 kV/mm. As the field increases, the conductivity of XLPE shows an exponential growth trend and its change is obvious, while that of SR changes less and increases relatively slowly. Simulation results show that: Firstly, set the field to 5 kV/mm, voltage reversal time to 30 s and temperature to 25℃. When voltage reversal is completed, the residual negative charges at the interface enhance the field in the SR, which causes the maximal transient field reaches 8.06 kV/mm, and weaken the field in the XLPE, which reaches -1.14 kV/mm. The space charge and field distributions in the steady state before and after voltage inversion show a "mirror" distribution. Secondly, keep the temperature and field unchanged, when voltage reversal time is 5 s, 30 s, 90 s, the maximal transient field distortion rate in the SR is 63.82%, 61.30%, 55.18%, respectively. Thirdly, hold voltage reversal time and temperature unchanged, When voltage amplitude is 1.56 kV, 2.60 kV, 3.64 kV, the XLPE steady-state electric field distortion rate before voltage inversion is 125.55%, 110.38%, 90.31%, and that of SR is -85.40%, -74.28%, -59.56%,while the maximal transient field distortion rate in the SR is 71.78%, 61.29%, 46.59%, respectively.
The results show that: (1) The conductivity of SR is higher than XLPE. There is a clear difference in the conductivity properties of XLPE and SR as a function of electric field, which is one reason for the accumulation of interface charges. (2) Since interface charge polarity change lags voltage polarity change, the residual negative charge at the interface would cause the maximal transient field in the SR. (3) The shorter the reverse period, the more residual negative charge at the XLPE/SR interface, resulting in a higher maximal transient field in the SR. (4) As the applied voltage increases, The conductivity ratio of SR to XLPE decreases gradually, so the maximal transient field distortion rate in SR decreases with increasing electric filed.

Key words： DC cable accessory polarity reversal conductivity space charge electric field distortion Maxwell-Wagner model

收稿日期: 2022-06-28

PACS:

TM85

基金资助:国家自然科学基金资助项目（51377056）

通讯作者: 王伟, 男,1960年生,教授,博士生导师,研究方向为高电压绝缘技术、电气设备在线监测与故障诊断等。E-mail：wwei@ncepu.edu.cn

作者简介: 宋柯, 男,1996年生,硕士研究生,研究方向为高压直流电缆绝缘空间电荷。E-mail：songke0513@163.com

引用本文:

宋柯, 钱定冬, 鲍国栋, 王伟, 齐佳乐. 基于M-W极化模型的低电场极性反转下XLPE/硅橡胶空间电荷与电场分布特性研究[J]. 电工技术学报, 2023, 38(16): 4479-4488. Song Ke, Qian Dingdong, Bao Guodong, Wang Wei, Qi Jiale. Study on Space Charge and Field Distribution Characteristics of XLPE/SR under Low Electric Field Polarity Reversal Based on the M-W Model. Transactions of China Electrotechnical Society, 2023, 38(16): 4479-4488.

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[1] 杜伯学, 韩晨磊, 李进, 等. 高压直流电缆聚乙烯绝缘材料研究现状[J]. 电工技术学报, 2019, 34(1): 179-191.
Du Boxue, Han Chenlei, Li Jin, et al.Research status of polyethylene insulation for high voltage direct current cables[J]. Transactions of China Electrotechnical Society, 2019, 34(1): 179-191.
[2] 李晖, 刘栋, 姚丹阳. 面向碳达峰碳中和目标的我国电力系统发展研判[J]. 中国电机工程学报, 2021, 41(18): 6245-6259.
Li Hui, Liu Dong, Yao Danyang.Analysis and reflection on the development of power system towards the goal of carbon emission peak and carbon neutrality[J]. Proceedings of the CSEE, 2021, 41(18): 6245-6259.
[3] 赵健康, 赵鹏, 陈铮铮, 等. 高压直流电缆绝缘材料研究进展评述[J]. 高电压技术, 2017, 43(11): 3490-3503.
Zhao Jiankang, Zhao Peng, Chen Zhengzheng, et al.Review on progress of HVDC cables insulation materials[J]. High Voltage Engineering, 2017, 43(11): 3490-3503.
[4] 何金良, 党斌, 周垚, 等. 挤压型高压直流电缆研究进展及关键技术述评[J]. 高电压技术, 2015, 41(5): 1417-1429.
He Jinliang, Dang Bin, Zhou Yao, et al.Reviews on research progress and key technology in extruded cables for HVDC transmission[J]. High Voltage Engineering, 2015, 41(5): 1417-1429.
[5] 李进. 高压直流电缆附件绝缘EPDM/LDPE界面电荷调控方法与抑制机理研究[D]. 天津: 天津大学, 2017.
[6] 罗兵, 孟繁博, 王婷婷, 等. 脱气处理对高压直流电缆绝缘特性的影响[J]. 电工技术学报, 2021, 36(增刊2): 730-735.
Luo Bing, Meng Fanbo, Wang Tingting, et al.Effect of degassing treatments on insulation characteristics of high voltage DC cables[J]. Transactions of China Electrotechnical Society, 2021, 36(S2): 730-735.
[7] 李国倡, 梁箫剑, 魏艳慧, 等. 配电电缆附件复合绝缘界面缺陷类型和位置对电场分布的影响研究[J]. 电工技术学报, 2022, 37(11): 2707-2715.
Li Guochang, Liang Xiaojian, Wei Yanhui, et al.Influence of composite insulation interface defect types and position on electric field distribution of distribution cable accessories[J]. Transactions of China Electrotechnical Society, 2022, 37(11): 2707-2715.
[8] Li Jin, Du Boxue, Xu Hang.Suppressing interface charge between LDPE and EPDM for HVDC cable accessory insulation[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2017, 24(3): 1331-1339.
[9] 李国倡, 王家兴, 魏艳慧, 等. 高压直流电缆附件XLPE/SIR材料特性及界面电荷积聚对电场分布的影响[J]. 电工技术学报, 2021, 36(14): 3081-3089.
Li Guochang, Wang Jiaxing, Wei Yanhui, et al.Effect of material properties of XLPE/SIR and interface charge accumulation on electric field distribution of HVDC cable accessory[J]. Transactions of China Electrotechnical Society, 2021, 36(14): 3081-3089.
[10] Li Gen, An Ting, Liang Jun, et al.Power reversal strategies for hybrid LCC/MMC HVDC systems[J]. CSEE Journal of Power and Energy Systems, 2020, 6(1): 203-212.
[11] Chen Xi, Wang Xia, Wu Kai, et al.Effect of voltage reversal on space charge and transient field in LDPE films under temperature gradient[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2012, 19(1): 140-149.
[12] 罗山. 极性反转下炭黑/聚乙烯复合材料空间电荷的研究[D]. 北京: 华北电力大学(北京), 2017.
[13] Fu M, Dissado L A, Chen G, et al.Space charge formation and its modified electric field under applied voltage reversal and temperature gradient in XLPE cable[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2008, 15(3): 851-860.
[14] 兰莉, 尹毅, 吴建东. 双层介质的电声脉冲法空间电荷波形恢复[J]. 中国电机工程学报, 2016, 36(2): 570-576.
Lan Li, Yin Yi, Wu Jiandong.Recovery of space charge waveform in multi-layer dielectrics by means of the pulsed electro-acoustic method[J]. Proceedings of the CSEE, 2016, 36(2): 570-576.
[15] 王霞, 姚航, 吴锴, 等. 交联聚乙烯与硅橡胶界面涂抹不同硅脂对其电荷特性的影响[J]. 高电压技术, 2014, 40(1): 74-79.
Wang Xia, Yao Hang, Wu Kai, et al.Effect of different coating silicone grease on space charge characteristics at XLPE/SR interface[J]. High Voltage Engineering, 2014, 40(1): 74-79.
[16] 郭高飞, 李文鹏, 王亚林, 等. 不同涂层对XLPE和EPDM双层绝缘介质空间电荷特性的影响[J]. 绝缘材料, 2019, 52(7): 80-85.
Guo Gaofei, Li Wenpeng, Wang Yalin, et al.Effect of coating material on space charge characteristics of XLPE and EPDM double-layer insulation medium[J]. Insulating Materials, 2019, 52(7): 80-85.
[17] 杨毅伟, 柳松, 彭嘉康, 等. 拉伸状态下硅橡胶/交联聚乙烯双层介质界面的空间电荷特性[J]. 绝缘材料, 2014, 47(5): 106-109.
Yang Yiwei, Liu Song, Peng Jiakang, et al.Space charge characteristics of cross-linked polyethylene and silicone rubber interface under different tensile rate[J]. Insulating Materials, 2014, 47(5): 106-109.
[18] Du Boxue, Li Jin.Interface charge behaviors between LDPE and EPDM filled with carbon black nanoparticles[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2016, 23(6): 3696-3703.
[19] 冯慈璋, 马西奎. 工程电磁场导论[M]. 北京: 高等教育出版社, 2000.
[20] Vu T T N, Teyssedre G, Vissouvanadin B, et al. Correlating conductivity and space charge measurements in multi-dielectrics under various electrical and thermal stresses[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2015, 22(1): 117-127.
[21] 兰莉. 温度对聚合物绝缘中空间电荷行为的影响[D]. 上海: 上海交通大学, 2015.
[22] 王霞, 刘霞, 郑明波, 等. 温度梯度场下硅橡胶与交联聚乙烯界面上空间电荷的形成机理[J]. 高电压技术, 2011, 37(10): 2424-2430.
Wang Xia, Liu Xia, Zheng Mingbo, et al.Formation mechanism of space charge accumulation at SR and XLPE interface under temperature gradient[J]. High Voltage Engineering, 2011, 37(10): 2424-2430.
[23] Boggs S, Damon D H, Hjerrild J, et al.Effect of insulation properties on the field grading of solid dielectric DC cable[J]. IEEE Transactions on Power Delivery, 2001, 16(4): 456-461.
[24] 孙目珍. 电介质物理基础[M]. 广州: 华南理工大学出版社, 2000.
[25] Morshuis P H F, Bodega R, Fabiani D, et al. Calculation and measurement of space charge in MV-size extruded cables systems under load conditions[C]//2007 IEEE International Conference on Solid Dielectrics, Winchester, UK, 2007: 502-505.
[26] 齐佳乐. 电缆绝缘介质界面空间电荷的特性研究[D]. 北京: 华北电力大学(北京), 2020.
[27] 王霞, 朱有玉, 王陈诚, 等. 空间电荷效应对直流电缆及附件绝缘界面电场分布的影响[J]. 高电压技术, 2015, 41(8): 2681-2688.
Wang Xia, Zhu Youyu, Wang Chencheng, et al.Effect of space charge on electric field distribution at the insulating interface between DC cable and accessory[J]. High Voltage Engineering, 2015, 41(8): 2681-2688.
[28] Vu T T N, Teyssedre G, Vissouvanadin B, et al. Electric field profile measurement and modeling in multi-dielectrics for HVDC application[C]//2013 IEEE International Conference on Solid Dielectrics, Bologna, Italy, 2013: 413-416.