Research on Lightning Protection of Overhead Power Distribution Lines 被引量：2

Research on Lightning Protection of Overhead Power Distribution Lines

下载PDF

导出

摘要 There are two major protective methods against lightning outages on overhead distribution lines.One is a surge arrester,and the other is an overhead ground wire.The surge arresters have rather constant effect regardless of the cause of the lightning outage.On the other hand,the effect of an overhead ground wire is quite different in two major causes,the direct lightning hit and the induced overvoltage.It is sufficient to provide surge arresters with an interval of 300 m for protection against the induced overvoltage caused by the nearby lightning stroke.Use of an overhead ground wire together with surge arresters is effective for lightning protection against the direct lightning hit to a distribution line.Puncture of surge arresters is the popular outage when the outage caused by the insulation break decreases sufficiently.Also,the existence of nearby trees leads to the line break due to the side flash from a tree.Advanced lightning protection equipment with ZnO arrester components is popular in Japan.Modeling of a pole transformer and application of an electromagnetic analysis method,such as FDTD method,to surge phenomena is considerably advanced. There are two major protective methods against lightning outages on overhead distribution lines. One is a surge arrester, and the other is an overhead ground wire. The surge arresters have rather constant effect regardless of the cause of the lightning outage. On the other hand, the effect of an overhead ground wire is quite different in two major causes, the direct lightning hit and the induced overvoltage. It is sufficient to provide surge arresters with an interval of 300 m for protection against the induced overvoltage caused by the nearby lightning stroke. Use of an overhead ground wire together with surge arresters is effective for lightning protection against the direct lightning hit to a distribution line. Puncture of surge arresters is the popular outage when the outage caused by the insulation break decreases sufficiently. Al- so, the existence of nearby trees leads to the line break due to the side flash from a tree. Advanced lightning protection equipment with ZnO an＇ester components is popular in Japan. Modeling of a pole transformer and application of an electromagnetic analysis method, such as FDTD method, to surge phenomena is considerably advanced.

作者 Shigeru Yokoyama Tomoyuki Sato

机构地区 Graduate School of Engineering Tohoku Electric Power Company

出处《高电压技术》 EI CAS CSCD 北大核心 2013年第10期2317-2328,共12页 High Voltage Engineering

关键词架空配电线路防雷保护雷击感应过电压时域有限差分方法架空地线避雷器防护方法直接雷击 lightning lightning protection distribution line surge arrester overhead ground wire induced overvoltage

分类号 TM726.3 [电气工程—电力系统及自动化] TM862 [电气工程—高电压与绝缘技术]

引文网络
相关文献

参考文献41

1Yokoyama S, Miyake K, Mitani H, et al. Simultaneous measurement of lightning induced voltages with associated stroke currents[J]. IEEE Transactions on Power Apparatus and Systems, 1983, 102(8): 2420-2427.
2Yokoyama S, Miyake K, Mitani H, et al. Advanced observations of lightning induced voltage on power distribution lines[J]. IEEE Transactions on Power Deli- very, 1986,1(2): 129-135.
3Yokoyama S, Miyake K, Fukui S. Advanced observations of lightning induced voltage on power distribution lines ( II)[J]. IEEE Transactions on Power Delivery, 1989, 4(4): 2196-2202.
4Yokoyama S. Calculation of lightning induces voltages on overhead mul- ti-conductor systems[J]. 1EEE Transactions on Power Apparatus and Systems, 1984, 103(1): 100-108.
5~okoyama S. Distribution surge arrester behavior due to lightning induced voltag- es[J]. IEEE Transactions on Power Delivery, 1986, 1(1): 171-178.
6Yokoyama S, Asakawa A. Experimental study of response of power distribution lines to direct lightning hits[J]. IEEE Transactions on Power Delivery, 1989, 4(1): 2242-2248.
7Taniguchi H, Sugimoto H, Yokoyama S. Observation of lighming performance on power distribution lines by still cameras[C]//Proceedings of 23~d International Conference on Lightning Protection (ICLP). Firenze, Italy: [s.n.], 1996:119-124.
8Yokoyama S, Miyake K, Shindo T, et al. Characteristics of lightning in winter and manner of outages on power lines due to it[C]//Proceedings of 10th International Symposium on High Voltage Engineering. Montreal, Canada: ISH, 1997.
9Sugimoto H. Lightning protection against winter lightning[C]//Proceedings of the 28th International Conference on Lightning Protection. Kanazawa, Ja- pan: [s.n.], 2006: 26-32.
10Miki M. Observation of current and leader development characteristics of winter lightning[C] // Proceedings of the 28th International Conference on Lightning Protection.Kanazawa, Japan: [s.n.], 2006: 14-19.

同被引文献19

1邓新丽,赵志斌,靳晓军,董松昭.架空线路感应电压的计算与分析[J].微波学报,2012,28(S3):319-322. 被引量：2
2张义军,吕伟涛,郑栋,周恩伟,陈绍东,李斌,陈绿文,潘汉波,曾昌军.负地闪先导-回击过程的光学观测和分析[J].高电压技术,2008,34(10):2022-2029. 被引量：31
3李文才,李学军,闫铁芳.建筑物内电子信息系统雷击电磁脉冲的危害与防护[J].智能建筑电气技术,2009(1):44-47. 被引量：2
4李宝忠,何金良,周辉,程引会,马良,吴伟,李进玺.核电磁脉冲环境中传输线的电磁干扰[J].高电压技术,2009,35(11):2753-2758. 被引量：27
5王羽,文习山,蓝磊,张露,陈楠,郭卫.提高架空配电线路耐雷水平的仿真分析[J].高电压技术,2011,37(10):2471-2476. 被引量：57
6王希,王顺超,何金良,曾嵘.安装避雷器后10kV配电线路的雷电感应过电压特性[J].电网技术,2012,36(7):149-154. 被引量：40
7边凯,陈维江,李成榕,沈海滨.架空配电线路雷电感应过电压计算研究[J].中国电机工程学报,2012,32(31):191-199. 被引量：67
8余占清,曾嵘,王绍安,陆国俊,熊俊,刘宇.配电线路雷电感应过电压仿真计算分析[J].高电压技术,2013,39(2):415-422. 被引量：78
9周浩,李杨,沈扬,万亦如,陈光,孙可.架空线对入侵超高压变压器的特快速暂态过电压波前陡度的限制[J].高电压技术,2013,39(4):943-950. 被引量：18
10朱时阳,周文俊,邓雨荣,盛博杰,杨帅,喻剑辉.可记录多重雷击的雷电流波形在线监测装置研制[J].高电压技术,2013,39(11):2699-2705. 被引量：27

引证文献2

1张春龙,行鸿彦,李春影,柴健,李鹏飞.不同类型电缆耦合雷电感应过电压研究[J].电子测量与仪器学报,2018,32(6):180-185. 被引量：7
2黄中华,方炯,杨先进,张阳阳.220kV GIS变电站雷击过电压分布特征仿真研究[J].电工技术,2020,0(7):126-128. 被引量：2

二级引证文献9

1徐艺峰,李常贤,路文连.内燃动车组线缆EMC仿真与防护设计[J].电子测量技术,2021,44(7):159-164. 被引量：3
2柴健,邳莹,朱传林,张春龙.开关型SPD冲击复位试验的研究分析[J].国外电子测量技术,2019,38(2):91-94. 被引量：2
3葛健玮,张航,毛水强,徐志勇.谐波交流电对交联聚乙烯电缆的树状放电的影响[J].电子测量技术,2019,42(21):76-81. 被引量：1
4李京校,杨金果,高金阁,李如箭,韩孟磊,张磊.圆形金属线圈雷电感应电压和感应电流数值模拟分析[J].科学技术与工程,2019,19(36):87-93. 被引量：4
5张成铭,徐晓英,舒晓榕,刘鹏宇,周钰雄.静电放电对PCB轨线耦合的实验及仿真研究[J].电子测量与仪器学报,2020,32(5):103-111. 被引量：9
6刘柏罕,丁黎明,车任达,宋宏彪,牛红军.220kV变电站雷电防护措施研究[J].河南科技,2021,40(36):47-49.
7郭易鑫.基于EMTP和BP神经网络的超高压电缆护套雷击感应电压研究[J].电瓷避雷器,2022(6):31-37. 被引量：5
8蒋龙云,杨丽娟,粟烨岭.750 kV变电站雷击过电压仿真研究[J].湖南文理学院学报（自然科学版）,2023,35(3):59-63.
9王鹏飞,刘恩博,李贤灵,王海星,张宗兵,田清文.一种强电磁脉冲模拟器的仿真及验证研究[J].现代电子技术,2023,46(22):28-32. 被引量：1

1汪亚民.计算机及通讯设备的防雷[J].广东公安科技,1995,0(2):9-12.
2黄振汉.35kV架空线路感应过电压探究[J].建材与装饰（上旬）,2012(12):185-187.
3杨保华,白洁.架空绝缘导线雷电过电压与防雷综合措施[J].科技传播,2011,3(15):127-127. 被引量：3
4刘汉辉.10kV配电线路的雷电感应过电压特性[J].低碳世界,2016,6(36):33-34. 被引量：3
5王井坤,陈中跃.35kV线路的综合防雷措施[J].煤矿机电,2007,28(5):96-97.
6邹程.避雷装置具有引雷作用[J].安徽消防,1996(9):23-23.
7冯德开.探讨高压线路雷击杆塔感应过电压的仿真技术[J].广东科技,2008,17(18):92-93.
8庄乾隆,王芳,肖玉刚,王振庆.矿山企业35kV线路的防雷措施[J].电世界,2012,53(10):11-11. 被引量：1
9Aiko Takahara,Ryoji Oshiro,Eiji Kaneko.Lightning Induced Surge on the Distribution Lines in the House near by the Lightning Point[J].Journal of Energy and Power Engineering,2012,6(5):840-844.
10邓应烈.广播电视防雷技术[J].有线电视技术,2002,9(19):73-75. 被引量：4

高电压技术

2013年第10期

浏览历史

内容加载中请稍等...

Research on Lightning Protection of Overhead Power Distribution Lines 被引量：2

参考文献41

同被引文献19

引证文献2

二级引证文献9

相关作者

相关机构

相关主题

浏览历史