Influence of surface contamination on electric field distribution of insulators

doi:10.1088/1674-1056/ada54d

中国物理B ›› 2025, Vol. 34 ›› Issue (3): 34101-034101.doi: 10.1088/1674-1056/ada54d

Influence of surface contamination on electric field distribution of insulators

Xingcai Li(李兴财)^1,†, Yingge Liu(刘滢格)¹, and Juan Wang(王娟)^1,2

1 School of Physics, Ningxia University, Yinchuan 750021, China;
2 Xinhua College, Ningxia University, Yinchuan 750021, China

收稿日期:2024-10-26 修回日期:2024-12-11 接受日期:2025-01-03 发布日期:2025-03-15
通讯作者: Xingcai Li E-mail:nxulixc2011@126.com
基金资助:
Project supported by the National Natural Science Foundation of China (Grant Nos. 12064034 and 11562017), the Leading Talents Program of Science and Technology Innovation in Ningxia Hui Autonomous Region, China (Grant No. 2020GKLRLX08), and the Natural Science Foundation of Ningxia Hui Autonomous Region, China (Grant No. 2024AAC05040).

Influence of surface contamination on electric field distribution of insulators

Xingcai Li(李兴财)^1,†, Yingge Liu(刘滢格)¹, and Juan Wang(王娟)^1,2

1 School of Physics, Ningxia University, Yinchuan 750021, China;
2 Xinhua College, Ningxia University, Yinchuan 750021, China

Received:2024-10-26 Revised:2024-12-11 Accepted:2025-01-03 Published:2025-03-15
Contact: Xingcai Li E-mail:nxulixc2011@126.com
Supported by:
Project supported by the National Natural Science Foundation of China (Grant Nos. 12064034 and 11562017), the Leading Talents Program of Science and Technology Innovation in Ningxia Hui Autonomous Region, China (Grant No. 2020GKLRLX08), and the Natural Science Foundation of Ningxia Hui Autonomous Region, China (Grant No. 2024AAC05040).

摘要/Abstract

摘要： Atmospheric particle adsorption on insulator surfaces, coupled with humid environments, significantly affects contamination flashover, necessitating a clear understanding of the electric field distribution on insulator surfaces with adsorbed particles. This is crucial for accurately assessing insulator safety and informing critical decision-making. Although previous research has demonstrated that particle arrangement significantly influences the electric field distribution around transmission lines, an in-depth analysis of its effects on insulator surfaces remains lacking. To address this gap, this study establishes a composite insulator model to examine how three types of spherical contamination layers affect the electric field distribution on insulator surfaces under varying environmental conditions. The results reveal that in dry environments, the electric field strength at the apex of single-particle contamination layers increases with the particle size and relative permittivity. For the double-particle contamination layers, the electric field intensity on the insulator surface decreases as the particle spacing increases, and larger particles are more likely to attract smaller charged particles. For triple-particle contamination layers arranged in a triangular pattern, the maximum surface field strength is nearly double that of the chain-arranged particles. Furthermore, within the chain-arranged triple-particle contamination layers, a large-small-large size arrangement has a more pronounced impact on the surface electric field than a small-large-small size arrangement. In humid environments, the surface electric field strength of insulators decreases with increasing contamination levels. These findings are of significant theoretical and practical importance for ensuring the safe operation of power systems.

关键词: composite insulator, electric field distribution, contamination, humid environment, arrangement pattern

Abstract: Atmospheric particle adsorption on insulator surfaces, coupled with humid environments, significantly affects contamination flashover, necessitating a clear understanding of the electric field distribution on insulator surfaces with adsorbed particles. This is crucial for accurately assessing insulator safety and informing critical decision-making. Although previous research has demonstrated that particle arrangement significantly influences the electric field distribution around transmission lines, an in-depth analysis of its effects on insulator surfaces remains lacking. To address this gap, this study establishes a composite insulator model to examine how three types of spherical contamination layers affect the electric field distribution on insulator surfaces under varying environmental conditions. The results reveal that in dry environments, the electric field strength at the apex of single-particle contamination layers increases with the particle size and relative permittivity. For the double-particle contamination layers, the electric field intensity on the insulator surface decreases as the particle spacing increases, and larger particles are more likely to attract smaller charged particles. For triple-particle contamination layers arranged in a triangular pattern, the maximum surface field strength is nearly double that of the chain-arranged particles. Furthermore, within the chain-arranged triple-particle contamination layers, a large-small-large size arrangement has a more pronounced impact on the surface electric field than a small-large-small size arrangement. In humid environments, the surface electric field strength of insulators decreases with increasing contamination levels. These findings are of significant theoretical and practical importance for ensuring the safe operation of power systems.

Key words: composite insulator, electric field distribution, contamination, humid environment, arrangement pattern

中图分类号: (Electrostatics; Poisson and Laplace equations, boundary-value problems)

41.20.Cv

92.60.Mt (Particles and aerosols) 52.80.Mg (Arcs; sparks; lightning; atmospheric electricity) 84.70.+p (High-current and high-voltage technology: power systems; power transmission lines and cables)

Xingcai Li(李兴财), Yingge Liu(刘滢格), and Juan Wang(王娟). Influence of surface contamination on electric field distribution of insulators[J]. 中国物理B, 2025, 34(3): 34101-034101.

Xingcai Li(李兴财), Yingge Liu(刘滢格), and Juan Wang(王娟). Influence of surface contamination on electric field distribution of insulators[J]. Chin. Phys. B, 2025, 34(3): 34101-034101.

参考文献

[1] Liu Z, Bi W, Chen X, Chen J, Qi D and Jiao Y 2020 Insulators and Surge Arresters 4 228
[2] Kohei Y and Hiroya H 2018 IEEE Electrical Insulation Magazine 35 23
[3] Takuma T, Ikeda T and Kawamoto T 1981 IEEE Transactions on Power Apparatus and Systems 100 4802
[4] Li Y, Yang H, Zhang Q, Yang X, Yu X and Zhou J 2014 IEEE Transactions on Dielectrics and Electrical Insulation 21 1735
[5] 1992 Hybrid Transmission Corridor study, Report
[6] Hoppel 1980 Study of drifting, charged aerosols from HVDC lines, Report
[7] He B, Zhao H, Chen C, Liu S and Peng Z 2017 IEEE Transactions on Dielectrics and Electrical Insulation 24 2432
[8] Cui J, Su Z, Che W, Fan J, Liu X, Wu G and Zhao F 2001 Electrical Equipment 4 6
[9] Wang J 2022 Study on Multi-physical Field Analysis and Pollution Flashover Prediction of Catenary Insulator in Saline-alkali Area, M.D. Thesis (Lanzhou Jiaotong University)
[10] Wang J, Liang X D and Liu Y Proceedings of 2011 International Conference on Energy and Environment, January 27, 2011, Shenzhen, China, p. 271
[11] Zhao Y, Hu Y, Jiang X, liu H and Shen H 2024 Journal of Electronic Measurement and Instrumentation 37 186
[12] Wang J, Liang X D, Chen L H and Liu Y 2011 Annual Report Conference on Electrical Insulation and Dielectric Phenomena, October 16-19, 2011, Cancun, Mexico, p. 373
[13] Sun H 2017 Study on Dynamic Contamination Depositing Characteristics of Insulators Using Coupled DEM and CFD Methods, M.D. Thesis (Southwest Jiaotong University)
[14] Jiang M, Guo J, Jiang Y, Li L and Lu M 2020 Environmental Science and Pollution Research 27 23643
[15] Ma Z, Li Y, Wu Y and Li G 2020 Insulating Materials 53 90
[16] Lu T, Sun N, Su Z and Ma W 2021 Southern Power System Technology 15 46
[17] Liu Y, Wu G, Guo Y, Zhang X, Liu K, Kang Y and Shi C 2020 International Journal of Electrical Power & Energy Systems. 115 105447
[18] Lu J, He K, Ma X, Ju Y and Xie L 2015 Proceedings of the CSEE 35 6222
[19] Kumar K B and Thomas M J 2016 IEEE Transactions on Dielectrics and Electrical Insulation 23 974
[20] Peng S, Wu G and Shao M 2017 High Voltage Apparatus 53 110
[21] Gao T, Hu Y, An Y, Xian R and Hou F 2019 Insulating Materials 52 59
[22] Hu Q, Xia H, Jiang X, Liu M, Li Y and Zhu M 2020 Proceedings of the CSEE 40 6027
[23] Xiang Y, Guo J and Luo Z 2011 Southern Power System Technology 5 72
[24] Yu K 2019 China Electrical Equipment Industry 5 76
[25] Lv Y, Wang J, Song Q and Liu Y 2021 Power System Technology 45 1201
[26] Gao B, Zhang Y, Wang Q, Zhou J and Zhang Q 2008 Insulators and Surge Arresters 3 13
[27] Xu Z, Lv F, Li H and Liu Y 2011 High Voltage Engineering 37 944
[28] Liu Y, Zong H, Gao S and Du B 2020 International Journal of Electrical Power & Energy Systems 121 106176
[29] Qiao X, Zhang Z, Jiang X, Sundararajan R, Ma X and Li X 2020 International Journal of Electrical Power & Energy Systems 120 105993
[30] Fujii O, Honsali K, Mizuno Y and Naito K 2009 IEEE Transactions on Dielectrics and Electrical Insulation 16 116
[31] Abd Rahman M, Izadi M and Ab Kadir M 2014 IEEE International Conference on Power and Energy (PECon), pp. 113-118
[32] Ndoumbe J, Beroual A and Imano A M 2015 IEEE Transactions on Dielectrics and Electrical Insulation 22 2669
[33] Krzma A S and Khamaira M Y 2018 Elixir Elec. Engg. 116 50009
[34] Aouabed F, Bayadi A, Rahmani A E and Boudissa R 2018 IEEE Transactions on Dielectrics and Electrical Insulation 25 413
[35] Salem A A and Abd-Rahman R J. Phys.: Conf. Ser. 1049 012019
[36] reza Ahmadi-veshki M, Mirzaie M and Sobhani R 2020 International Journal of Electrical Power & Energy Systems 117 105679
[37] Kim T, Sanyal S, Rabelo M and Yi J 2022 ECS Journal of Solid State Science and Technology 11 073007
[38] Fadaeeasrami H, Faghihi F, Olamaei J and Mohammadnezhadshourkaei H 2022 International Journal of Electrical Power & Energy Systems 142 108274
[39] Liu Y, Li X, Wang J, Ma X and Sun W 2024 Chin. Phys. B 33 014101
[40] Li C and Lv B 2024 High Voltage Apparatus 60 147
[41] Wang S, Wang J, Zhao L and Chen L 2021 Electric Power 54 149
[42] Wan Q 1982 Mining Safety & Environmental Protection 1 17
[43] Huang Z 1996 Journal of Communication University of China (Science and Technology) 7 3
[44] Zhang C, Hu J and Li J 2018 IET Generation, Transmission & Distribution 12 406
[45] Jiang X and Li Y 2014 Power System Technology 38 576

Metrics

Viewed

Full text

HTML			PDF

最新录用	在线预览	正式出版	最新录用	在线预览	正式出版
0	0	0	0	0	42

来源	本网站	其他网站

次数	36	6
比例	86%	14%

Abstract

192

最新录用	在线预览	正式出版

0	0	192

	来源	本网站

	次数	192
	比例	100%

Cited

Web of Science	Crossref	ScienceDirect	Search for Citations in Google Scholar >>


This page requires you have already subscribed to WoS.

Shared

Influence of surface contamination on electric field distribution of insulators

Influence of surface contamination on electric field distribution of insulators

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 13

Metrics

本文评价

推荐阅读 0

[1]	Yueling Jiang(蒋越凌) and Quanlin Dong(董全林). Electron beam modeling and analyses of the electric field distribution and space charge effect[J]. 中国物理B, 2022, 31(5): 54103-054103.
[2]	Juan Qin(秦娟), Gang Cao(曹港), Run Xu(徐闰), Jing Lin(林婧), Hua Meng(孟华), Wen-Zhen Wang(王文贞), Zi-Ye Hong(洪子叶), Jian-Cong Cai(蔡健聪), and Dong-Mei Li(李冬梅). Investigation of transport properties of perovskite single crystals by pulsed and DC bias transient current technique[J]. 中国物理B, 2022, 31(11): 117102-117102.
[3]	吴浩, 段宝兴, 杨珞云, 杨银堂. Theoretical analytic model for RESURF AlGaN/GaN HEMTs[J]. 中国物理B, 2019, 28(2): 27302-027302.
[4]	董江鹏, 介万奇, 余竞一, 郭榕榕, Christian Teichert, Kevin-P Gradwohl, 张滨滨, 罗翔祥, 席守智, 徐亚东. Twin boundary dominated electric field distribution in CdZnTe detectors[J]. 中国物理B, 2018, 27(11): 117202-117202.
[5]	上官明佳, 夏海云, 窦贤康, 王冲, 裘家伟, 张云鹏, 舒志峰, 薛向辉. Comprehensive wind correction for a Rayleigh Doppler lidar from atmospheric temperature and pressure influences and Mie contamination[J]. 中国物理B, 2015, 24(9): 94212-094212.
[6]	孙晓艳, 卢兴强, 吕凤年, 张国文, 张臻, 尹宪华, 范滇元. General design basis for a final optics assembly to decrease filamentary damage[J]. 中国物理B, 2015, 24(5): 54209-054209.
[7]	于英霞, 林兆军, 栾崇彪, 吕元杰, 冯志红, 杨铭, 王玉堂. Influence of the channel electric field distribution on the polarization Coulomb field scattering in In_0.18Al_0.82N/AlN/GaN heterostructure field-effect transistors[J]. 中国物理B, 2014, 23(4): 47201-047201.
[8]	范春珍, 王俊俏, 程永光, 丁佩, 梁二军, 黄吉平. Electric field distribution around the chain of composite nanoparticles in ferrofluids[J]. 中国物理B, 2013, 22(8): 84703-084703.
[9]	张凯, 曹梦逸, 陈永和, 杨丽媛, 王冲, 马晓华, 郝跃. Fabrication and characterization of V-gate AlGaN/GaN high electron mobility transistors[J]. 中国物理B, 2013, 22(5): 57304-057304.
[10]	司马文霞, 彭庆军, 杨庆, 袁涛, 施健. Local electron mean energy profile of positive primary streamer discharge with pin-plate electrodes in oxygen–nitrogen mixtures[J]. 中国物理B, 2013, 22(1): 15203-015203.
[11]	丁霞, 贾艳霞, 魏恩泊. Electric field distribution and effective nonlinear AC and DC responses of graded cylindrical composites[J]. 中国物理B, 2012, 21(5): 57202-057202.
[12]	王光红, 张晓丹, 许盛之, 郑新霞, 魏长春, 孙建, 熊绍珍, 耿新华, 赵颖. Reduction of the phosphorus contamination for plasma deposition of p–i–n microcrystalline silicon solar cells in a single chamber[J]. 中国物理B, 2010, 19(9): 98102-098102.
[13]	孙福和, 魏长春, 孙建, 张德坤, 耿新华, 熊绍珍, 赵颖. Research on the boron contamination at the p/i interface of microcrystalline silicon solar cells deposited in a single PECVD chamber[J]. 中国物理B, 2009, 18(10): 4558-4563.