1 100 kV特高压交流复合套管局放原因分析及改进措施
王赛豪1,史恒超2,秦政敏3,孙 英杰1,刘 龙1
(1 平高集团有限公司,河南 平顶山 467001;2 河南平高电气股份有限公司,河南 平顶山 467001;3 河南平芝高压开关有限公司,河南 平顶山 467001)
摘 要:1 100 kV特高压交流复合套管在例行出厂试验中出现局放超标问题,从耐压设备、试验场地、装配过程、测量系统、元件质量等多个方面进行原因分析,完成套管局放定位,后借助有限元方法对该位置予以确认。综合各种因素分析,局放产生的原因是由于空心复合绝缘子制造工艺的分散性,导致绝缘件内部出现缺陷,进而诱发局部放电。根据有限元分析结果,提出了双层屏蔽结构优化措施,重新制造样机并进行试验,试验结果表明:优化后的屏蔽结构,能有效提高套管的起晕电压,降低局放水平,保证产品可靠安全运行。
关键词:特高压套管;局部放电;双层屏蔽;电场分析
中图分类号:TM 216+.5;TM 853 文献标识码:A 文章编号:1007-3175(2017)09-0027-05
Partial Discharge Cause Analysis of 1 100 kV Extra-High Voltage AC Composite Bushing and Improvement Measure
WANG Sai-hao1, SHI Heng-chao2, QIN Zheng-min3, SUN Ying-jie1, LIU Long1
(1 Pinggao Group Co., Ltd, Pingdingshan 46 7001, China;2 Henan Pinggao Electric Co., Ltd, Pingdingshan 46 7001, China;
3 Henan Pingzhi High Voltage Switchgear Co., Ltd, Pingdingshan 46 7001, China)
Abstract: The partial discharge (PD) problem occurs in the 1 100 kV extra-high voltage AC composite bushing's routine factory test. This paper carried out the cause analysis from the respects, such as voltage test apparatus, test site environment, assembly process, test system, and component quality etc to complete the bushing PD location and to determine the location by the finite element analysis method. According to the synthesized analysis of various factors, it was found that the reason for PD was dispersion on composite bushing’s manufacturing process, which led to internal defects in insulators and caused PD to happen ultimately. Based on the finite element analysis result, this paper proposed the double-deck shield structure optimization measures to re-manufacture the prototype, carrying out test for it. The final test result shows that the optimized shield structure can raise bushing’s discharge inception voltage effectively, which reduces the PD level to ensure the reliable and safe operation for the products.
Key words: extra-high voltage bushing; partial discharge; double-deck shield; electric field analysis
参考文献
[1] 舒印彪,张文亮.特高压输电若干关键技术研究[J].中国电机工程学报,2007,27(31):l-6.
[2] 孙岗,吴光亚,张锐,等.特高压GIS出线套管用空心复合绝缘子运行性能分析[J].电瓷避雷器,2014(6):1-7.
[3] 马斌.复合空心绝缘子产品及其制造技术[J].变压器,2003,40(8):35-38.
[4] 张锐,吴光亚,张广全,等.复合空心绝缘子的发展现状与应用前景[J].电力设备,2007,8(4):36-38.
[5] 马斌.1 100 kV交流SF6组合电器用空心复合绝缘子的设计及实现[J].电网技术,2006,30(12):98-101.
[6] 王晓琪,吴春风,李培,吴士普.1 000 kV GIS用套管的设计[J].高电压技术,2008,34(9):1792-1796.
[7] 李乃一,彭宗仁,刘鹏,等.特高压SF6气体绝缘套管内屏蔽结构研究[J].高电压技术,2015,41(11):3737-3745.
[8] 钟建英,狄谦.550 kV SF6气体绝缘GIS套管内屏蔽结构的研究[J].高压电器,2011,47(4):33-36.
[9] 方江,孔维贞.800 kV六氟化硫气体绝缘复合套管的研制[J].电工电气,2012(4):42-45.
[10] 吴光亚,叶廷路,吴巾克,等.±500 kV换流站直流分压器用复合套管外绝缘闪络事故分析及处理措施[J].电瓷避雷器,2010(5):17-22.
[11] 杜林,崔婷,孙才新.UVT RONR2862型紫外传感器检测交流电晕放电[J].高电压技术,2009,35(2):272-276.
[12] 许学勤,张重远,李燕青,等.接地内屏蔽对SF6套管电场分布影响的研究[J].华北电力大学学报(自然科学版),2007,34(6):11-14.
[13] 钟建英,韩书谟,张友鹏,等.特高压复合套管设计计算与分析[J].电气制造,2008(2):62-64.
[14] 张宏亮.特高压交流1 100 kV GIS出线套管内绝缘结构优化[D].西安:西安交通大学,2009.
[15] 黎斌.SF6高压电器设计[M].北京:机械工业出版社,2003.
