直流应力下电极表面覆膜对金属微粒启举的影响机理研究

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摘要针对直流GIL中的自由金属微粒污染物问题,研究表面覆膜措施对金属微粒启举的限制机理。利用气体电离及界面电荷积聚理论提出了直流应力下电极覆膜时金属微粒带电及启举模型,并根据微粒带电量的时变特征提出了充电时间的概念。为验证模型的正确性,构建了多功能模块的金属微粒带电-运动观测实验平台,对不同大小、材质的球形金属微粒以及不同厚度的PET薄膜开展实验,实验结果验证了模型的正确性:直流应力下,覆膜措施产生的界面极化过程只是增加了微粒的充电时间,而对微粒最终带电量并无影响,但覆膜产生的静电吸附力可显著提高微粒的启举电压;外施电压、覆膜介电常数及体电导率对微粒充电时间均有显著影响;而由于充电时间的存在使得电极覆膜措施下出现微粒“间歇启举”现象。

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	王健
	李庆民
	李伯涛
	陈超
	刘思华
	李成榕

关键词 ：直流GIL, 电极表面覆膜, 金属微粒启举, 充电时间常数, 间歇性启举, 重启举时长

Abstract：To solve the problem of free metal-particles pollution in DC gas insulated metal enclosed transmission line(GIL),the analysis of the coating measure’s restriction mechanism forthe metal-particle lifting is carried outin this paper.Based on the theory of gas ionization and the interface charge accumulation,the model of the metal particle’s charging and lifting on the coatings under DC voltage is proposed.Furthermore,the concept of the charging timeis defined according to the time-varying characteristics of the particle-charging.To verify the correctness of the models,the multi-function test platform of metal-particle’s charging and moving is established.Experiments are carried out on the spherical metal particles with different sizes andmaterials,and the PET films with different thicknesses under DC voltage.The results validate the accuracy of the model,i.e. the coating measure just increases the particle-charging time and has no effect on the final charge,but the effect of the electrostatic adsorption force can significantly improve the lifting voltage; applied voltage,coating’s permittivity and bulk conductivity have significant effect on the charging time;and due to the existence of the charging time,the phenomennon of “intermittentlifting” will appear.

Key words： DC GIL electrode-coating metal particle lifting charging time constant intermittent lifting re-lifting duration

收稿日期: 2014-12-01 出版日期: 2015-04-13

PACS:

TM315

基金资助:国家重点基础研究发展计划(973计划)(2014CB239502)资助项目。

通讯作者: 李庆民男,1968年生,教授,博士生导师,研究方向为高电压与绝缘技术。

作者简介: 王健男,1985年生,博士研究生,研究方向为GIL绝缘优化与机械承载能力。李庆民男,1968年生,教授,博士生导师,研究方向为高电压与绝缘技术。

引用本文:

王健,李庆民,李伯涛,陈超,刘思华,李成榕. 直流应力下电极表面覆膜对金属微粒启举的影响机理研究[J]. 电工技术学报, 2015, 30(5): 119-127. Wang Jian,Li Qingmin,Li Botao,Chen Chao,Liu Sihua,Li Chengrong. Mechanism Analysis of the Electrode-coating’s Impact on the Particle-lifting Under DC Voltage. Transactions of China Electrotechnical Society, 2015, 30(5): 119-127.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2015/V30/I5/119

[1] Takinami N,Kobayashi S,Miyazaki A.Applications of the world’s longest gas insulated transmission line in Japan[C].Proceedings of the 7th International Conference on Properties and Applications of Dielectric Materials,Nagoya,Japan,2003,1:19-22.
[2] Benato R,Carlini E M,Di Mario C,et al.Gas insulated transmission lines in railway galleries[J].IEEE Transactions on Power Delivery,2005,20(2):704-709.
[3] Hillers T.Gas insulated transmission lines (GIL):ready for the real world[C].Power Engineering Society Winter Meeting,Singapore,2000,1:575-579.
[4] 范建斌,李鹏,李金忠,等.±800 kV特高压直流GIL关键技术研究[J].中国电机工程学报,2008,28(13):1-7.
Fan Jianbin,Li Peng,Li Jinzhong,et al.Study on key technology of ±800 kV UHVDC GIL[J].Proceedings of the CSEE,2008,28(13):1-7.
[5] Volpov Evgeni K.HVDC gas insulated apparatus:Electric field specificity and insulation design concept[J].IEEE Electrical Insulation Magazine,2002,18(2):7-14.
[6] 吴晓文,舒乃秋,李洪涛,等.气体绝缘输电线路温升数值计算及相关因素分析[J].电工技术学报,2013,28(1):65-72.
Wu Xiaowen,Shu Naiqiu,Li Hongtao,et al.Analysis of numerical calculation and related factors of gas insulated transmission line temperature[J].Transactions of China Electrotechnical Society,2013,28(1):65-72.
[7] 汤浩,吴广宁,范建斌,等.直流气体绝缘输电线路的绝缘设计[J].电网技术,2008,32(6):65-70.
Tang Hao,Wu Guangning,Fan Jianbin,et al.Insulation design of gas insulated HVDC transmission lines[J].Power System Technology,2008,32(6):65-70.
[8] 张晓星,姚尧,唐炬,等.导电微粒局部放电下SF₆分解组分色谱信号的曲线拟合分峰[J].电工技术学报,2010,25(7):179-185.
Zhang Xiaoxing,Yao Yao,Tang Ju,et al.Separating overlapped chromatogram signals of SF₆ decomposed products under PD of conductive particles based on Curve-Fitting[J].Transactions of China Electrotechnical Society,2010,25(7):179-185.
[9] 贾江波,张乔根,师晓岩,等.交流电压下绝缘子附近导电微粒运动特性[J].电工技术学报,2008,23(5):7-11.
Jia Jiangbo,Zhang Qiaogen,Shi Xiaoyan,et al.Motion of conducting particle near PTFE spacer under AC voltage[J].Transactions of China Electrotechnical Society,2008,23(5):7-11.
[10]刘绍峻.SF₆气体绝缘电器中金属屑的控制[J].高压电器,1989,25(1):35-43.
Liu Shaojun.Control of SF₆ gas insulated metal scrap in electric appliance[J].High Voltage Apparatus,1989,25(1):35-43.
[11]Srivastava K D,van Heeswijk R G.Dielectric coatings-effect on breakdown and particle movement in GITL systems[J].IEEE Transactions on Power Apparatus and Systems,1985,PAS-104(1):22-31.
[12]Sakai K I,Labrado Abella D,Suehiro J,et al.Charging and behavior of a spherically conducting particle on a dielectrically coated electrode in the presence of electrical gradient force in atmospheric air[J].IEEE Transactions on Dielectrics and Electrical Insulation,2002,9(4):577-588.
[13]Morcos M M,Ward S A,Anis H,et al.Insulation integrity of GIS/GITL systems and management of particle contamination[J].Electrical Insulation Magazine,IEEE,2000,16(5):25-37.
[14]Parekh H,Srivastava K D,van Heeswijk R G.Lifting field of free conducting particles in compressed SF6 with dielectric coated electrodes[J].IEEE Transactions on Power Apparatus and Systems,1979,PAS98(3):748-758.
[15]张乔根,贾江波,杨兰均,等.气体绝缘系统电极表面覆膜时金属导电微粒带电原因分析[J].西安交通大学学报,2004,38(12):1287-1291.
Zhang Qiaogen,Jia Jiangbo,Yang Lanjun,et al.Charging mechanism of metallic conducting particle on a dielectrically coated electrode in gas insulated system[J].Journal of Xi’an Jiaotong University,2004,38(12):1287-1291.
[16]Pérez Alberto T.Charge and force on a conducting sphere between two parallel electrodes[J].Journal of Electrostatics,2002,56(2):199-217.
[17]贾江波,马自伟,查玮,等.稍不均匀电场中绝缘子附近导电微粒受力分析[J].中国电机工程学报,2006,26(10):141-145.
Jia Jiangbo,Ma Ziwei,Zha Wei,et al.A slightly uneven electric field of insulator in conducting particle near the stress analysis[J].Proceedings of the CSEE,2006,26(10):141-145.
[18]金维芳.电介质物理学[M].北京:机械工业出版社,1997.
[19]刘志民,邱毓昌.对绝缘子表面电荷积聚机理的讨论[J].电工技术学报,1999,14(2):65-68.
Liu Zhimin,Qiu Shuchang.The discussion about accumulation mechanism of surface charge on insulating spacer[J].Transactions of China Electrotechnical Society,1999,14(2):65-68.
[20]Kindersberger J,Lederle C.Surface charge decay on insulators in air and sulfurhexafluorid-Part I:Simulation[J].IEEE Transactions on Dielectrics and Electrical Insulation,2008,15(4):941-948.
[21]Wiegart N,Niemeyer L,Pinnekamp F,et al.Inhomogeneous field breakdown in GIS-the prediction of breakdown probabilities and voltages.I.Overview of a theory for inhomogeneous field breakdown in SF₆[J].IEEE Transactions on Power Delivery,1988,3(3):923-930.
[22]Wiegart N,Niemeyer L,Pinnekamp F,et al.Inhomogeneous field breakdown in GIS-the prediction of breakdown probabilities and voltages.Ⅱ.Ion density and statistical time lag[J].IEEE Transactions on Power Delivery,1988,3(3):931-938.
[23]Hosokawa M,Endo F,Yamagiwa T,et al.Particle-initiated breakdown characteristics and reliability improvement in SF₆ gas insulation[J].IEEE Transactions on Power Delivery,1986,1(1):58-65.