SF6替代气体中绝缘子沿面闪络特性研究现状
满林坤,肖登明
(上海交通大学 电气工程系,上海 200030)
摘 要:阐述了目前国内外对SF6替代气体中绝缘子沿面闪络特性的研究现状,介绍了气体中影响绝缘子沿面闪络的因素,指出气体的绝缘子闪络性能受气压和SF6含量的影响最大,闪络电压通常随气压增大而增大,并呈线性关系;绝缘子形状、接触情况、湿度、温度、表面粒子的长度、粗糙度等因素对闪络性能也有一定影响。
关键词:SF6替代气体;绝缘子沿面闪络性能;影响因素;研究现状
中图分类号:TM216 文献标识码:A 文章编号:1007-3175(2016)09-0001-06
Research Status of Insulators Along-Surface Flashover
Property in SF6 Alternative Gas
MAN Lin-kun, XIAO Deng-ming
(Department of Electrical Engineering, Shanghai Jiaotong University, Shanghai 200030, China)
Abstract: This paper expounded the research status of insulators along-surface flashover property in SF6 alternative gas now at home and abroad. Introduction was made to the factors impacting on insulators along-surface flashover. It is pointed out that the air pressure and SF6 contents have the largest impact on the gas insulator flashover property and the flashover voltage usually increases with the linear increase of air pressure. Many factors such as the shape, contact situation, humidity, temperature, surface particle, length and roughness of insulators will impact on the flashover property.
Key words: SF6 alternative gas; insulator along-surface flashover property; influence factor; research status
参考文献
[1] 王湘汉,汪沨,邱毓昌. 均匀场中SF6二维流注放电模型的动态仿真[J]. 高电压技术,2008,34(7):1358-1362.
[2] 芦竹茂,梁基重,王天正,等. SF6红外成像检漏技术在特高压带电检测中的应用[J]. 绝缘材料,2015,48(9):29-33.
[3] 宴年平,于钦学,曹淳枫,等.SF6电力设备局部放电与分解气体组分关系的研究进展[J]. 绝缘材料,2013,46(5):1-3.
[4] 杨俊坤,彭詠涛,谭向宇,等.GIS 设备中通过SF6气体分解产物检测判定放电类型的研究[J]. 绝缘材料,2012,45(2):61-64.
[5] 张刘春,肖登明. c-C4F8/CF4替代SF6可行性的SST实验分析[J]. 电工技术学报,2008,23(6):14-18.
[6] 汤昕,廖四军,杨鑫.SF6混合/ 替代气体绝缘性能的研究进展[J]. 绝缘材料,2014,47(6):18-22.
[7] YAMAMOTO O, TAKUMA T, HAMADA S.Applying a gas mixtures containing c-C4F8 as an insulating medium[J]. IEEE Transactions on Dielectrics and Electrical Insulation,2001,8(6):4204-4207.
[8] 张晓星,周君杰,唐炬,等. CF3I/N2混合气体局部放电特性的实验研究[J]. 高电压技术,2013,39(2):287-293.
[9] 孟晓波,梅红伟,陈昌龙,等. 绝缘介质表面流注发展特性的机理研究[J]. 中国电机工程学报,2013,33(22):155-165.
[10] 王琦,汪沨,邱毓昌. 表面电荷积聚对冲击电压下绝缘子沿面放电的影响[J]. 电力设备,2004,5(7):19-22.
[11] 林海丹,刘熊,梁义明,等. 绝缘材料沿面闪络发展特性的研究进展[J]. 绝缘材料,2015,48(7):1-8.
[12] 肖登明. 环保型绝缘气体的发展前景[J]. 高电压技术,2016,42(4):1035-1046.
[13] 赵洪,吴变桃,肖登明. c-C4F8和CF4混合气体在极不均匀电场下的交流绝缘特性[J]. 华东电力,2007,35(10):44-46.
[14] 成俊奇,丁立健.SF6、N2和合成空气中绝缘子沿面闪络性能的研究[J]. 绝缘材料,2014,47(6):83-86.
[15] 肖登明,朱莉莉,李红雷. SF6—CO2混合气体中电子输运特性的蒙特卡洛模拟[J]. 上海交通大学学报,1999,33(12):1482-1484.
[16] 杨冬.SF6、N2 及其混合气体绝缘特性实验研究[D].哈尔滨:哈尔滨理工大学,2006.
[17] 王璁.0.1~0.25 MPa下SF6混合气体中绝缘子的沿面闪络特性研究[D]. 北京:华北电力大学,2012.
[18] 吴振跃. 低压力N2的绝缘特性研究[D]. 上海:上海交通大学,2015.
[19] 汪沨,张乔根,邱毓昌. GIS中绝缘子与电极接触不良时闪络特性的分析[J]. 绝缘材料,2003,36(1):45-47.
[20] OKABE S, YOROZUYA T, ENDO F, et al. Voltage-time characteristics for steep-front impulse voltages of particle-contaminated spacers in SF6 gasinsulated switchgear[J]. IEEE Transactions on Power Delivery,1992,7(3):1232-1238.
[21] YAMAMOTO O, TAKUMA T, FUKUDA M, et al. Improving withstand voltage by roughening the surface of an insulating spacer used in vacuum[J]. IEEE Transactions on Dielectrics and Electrical Insulation,2003,10(4):71-74.
