提高接地极散流效率的冲击接地降阻分析

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (671 KB)
输出: BibTeX | EndNote (RIS)

摘要提高简单结构接地极的冲击散流效率可达到降低其冲击接地电阻的目的, 对输电线路防雷具有重要意义, 为此, 从提高接地极的冲击散流效率、改善其冲击散流不均匀度的角度, 对接地极上添加“针刺”的降阻效果进行研究。本文通过冲击接地模拟试验, 分别测量了13种接地极的冲击散流分布规律及其冲击接地电阻。利用本文建立的冲击散流不均匀度计算式, 计算上述接地极的冲击散流不均匀度, 分别分析了“针刺”长度及其位置对接地极散流不均匀度和冲击接地电阻的影响规律。规律表明, 通过在接地极上的合适位置布置“针刺”状短导体能够起到增强其冲击散流均匀度, 降低其冲击接地电阻的作用, 且当“针刺”位于接地极中部而非端部时, 降阻效果更明显。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	袁涛
	雷超平
	司马文霞
	杨庆
	骆玲
	艾琳丰

关键词 ：接地极, 冲击接地模拟试验, 不均匀度, 冲击接地电阻, 端部效应

Abstract：Impulse resistance of simple configuration grounding device, which is significant for lightning performance of transmission lines, would reduce if current leakage efficiency of which is enhanced. Thereby, study on impulse resistance of grounding devices is carried out in order to improve current leakage efficiency. Impulse current leakage regulation as well as impulse resistance of 13 grounding devices are measured via impulse simulation experiment. Current leakage unhomogeneous degree of grounding devices are calculated by using computation formula of unhomogeneous degree which established in this paper. Impact of the “needle” length and location upon current leakage unhomogeneous degree as well as impulse grounding resistance are analyzed respectively. The results show that impulse current leakage become more unhomogeneous by adding needle shaped conductor to the proper location of grounding devices. Furthermore, impulse resistance of grounding devices are reduced. In addition, effect of resistance reduction is more obvious while needle shaped conductor is added at middle of the grounding device than other cases.

Key words： Grounding device impulse grounding simulation experiment unhomogeneous degree impulse grounding resistance end effect

收稿日期: 2011-11-08 出版日期: 2014-03-20

PACS:

TM72

基金资助:国家创新研究群体基金(51021005), 国家重点基础研究发展计划(973计划)(2009CB724504)和国家自然科学基金(51107153)资助项目。

作者简介: 袁涛男, 1976年生, 博士, 主要从事电力系统过电压及接地技术研究。雷超平男, 1987年生, 硕士研究生, 研究方向为防雷与接地技术。

引用本文:

袁涛, 雷超平, 司马文霞, 杨庆, 骆玲, 艾琳丰. 提高接地极散流效率的冲击接地降阻分析[J]. 电工技术学报, 2012, 27(11): 278-284. Yuan Tao, Lei Chaoping, Sima Wenxia, Yang Qing, Luo Ling, Ai Linfeng. Analysis of Grounding Resistance Reduction Effect Based on Enhancing Impulse Current Leakage Efficiency. Transactions of China Electrotechnical Society, 2012, 27(11): 278-284.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2012/V27/I11/278

[1] 何金良, 曾嵘. 电力系统接地技术[M]. 北京: 科学出版社, 2007.
[2] 彭岳林, 王坚强. 均匀地质水平接地网参数计算[J]. 电工技术学报, 1995, 10(1):75-77, 80.
Peng Yuelin, Wang Jianqiang. The Parameter calculation of a horizontal ground grid in homogeneous medium[J]. Transactions of China Electrotechnica Society, 1995, 10(1):75-77, 80.
[3] Yang Caiwei, Sima Wenxia, Yuan Tao, et al. Experimental analysis on shielding effect of the grounding electrodes under impulse-current[J].High Voltage Engineering, 2008, 34(12): 2609-2614.
[4] 杨财伟. 接地装置冲击特性的模拟试验及有限元分析方法研究[D]. 重庆: 重庆大学, 2010.
[5] 黄文武, 文习山, 谢俊. 接地网轴向电流分布的模拟试验[J]. 高电压技术, 2005, 31(06): 76-77.
Huang Wenwu, Wen Xishan, Xie Jun. Simulation experiment of the current distribution along axial direction of the grounding network[J]. High Voltage Engineering, 2005, 31(6): 76-77.
[6] Dawalibi F, Mukhedkar D, Bensted D. Measured and computed current densities in buried ground conductors[J]. IEEE Transactions on Power Apparatus and Systems, 1981, PAS-100(8): 4083-4092.
[7] Sekioka S, Hayashida H, Hara T, et al. Measurements of grounding resistances for high impulse currents[J]. IEE Proceedings: Generation, Transmission and Distribution, 1998, 145(6): 693-699.
[8] Chowdhuri P. Impulse impedance tests on laboratory model ground electrodes[J]. IEE Proceedings: Generation, Transmission and Distribution, 2003, 1 50(4): 427-433.
[9] He Jinliang, Zeng Rong, Tu Youping, et al. Laboratory investigation of impulse characteristics of transmission tower grounding devices[J]. IEEE Transactions on Power Delivery, 2003, 18(3): 994-1001.
[10] Gatta F, Geri A, Lauria S, et al. Backflashover simulation of HV transmission lines with enhanced counterpoise groundings[J]. Electric Power Systems Research, 2009, 79(7): 1076-1084.
[11] Geri A, Veca GM, Garbagnati E, et al. Non-linear behaviour of ground electrodes under lightning surge currents: computer modelling and comparison with experimental results[J]. IEEE Transactions on magnetics, 1992, 28(2): 1442-1445.
[12] Haddad A, Griffiths H, Ahmeda M, et al. Experimental investigation of the impulse characteristics of practical ground electrode systems[C]. Proceedings of the 2010 International Conference on High Voltage Engineering and Application, New Orleans, United States, 2010: 469-472.
[13] Gao Y, He J, Zou J, et al. Fractal simulation of soil breakdown under lightning current[J]. Journal of Electrostatics, 2004, 61(3-4): 197-207.
[14] 项立群. 概率论与数理统计[M]. 北京:北京大学出版社, 2011.
[15] QX/T 84-2007. 气象低速风洞性能测试规范[S].
[16] Grcev L. Impulse efficiency of simple grounding electrode arrangements[C]. Proceedings of the 8th International Zurich Symposium on Electromagnetic Compatibility, Munich, Germany, 2007, 325-328.
[17] 杨琳, 吴广宁, 田晓菲. 基于EMTP的水平接地体冲击时-频特性分析[J]. 电工技术学报, 2011, 26(6): 194-198.
Yang Lin, Wu Guangning, Tian Xiaofei. Analysis of impulse characteristic grounding electrode in frequency and time domain based on EMTP[J]. Transactions of China Electrotechnical Society, 2011, 26(6): 194-198.
[18] Mousa AM. The soil ionization gradient associated with discharge of high currents into concentrated electrodes[J]. IEEE Transactions on Power Delivery, 1994, 9(3): 1669-1677.
[19] Nor N, Haddad A, Griffiths H. Characterization of ionization phenomena in soils under fast impulses[J]. IEEE Transactions on Power Delivery, 2005, 21(1): 353-361.
[20] Liew AC, Darveniza M. Dynamic model of impulse characteristics of concentrated earths[J]. Proceedings of the Institution of Electrical Engineers, 1974, 121(2): 123-135.