Simulation Analysis of the Impact Characteristic of Grounding Electrode Based on the Current Shielding Effect
Yuan Tao1, Tang Yan1, Sima Wenxia1, Yang Qing1, Jiang Wendong2, Cao Jiong2
1.State Key Laboratory of Power Transmission Equipment & System Security and New Technology Chongqing University Chongqing 400044 China; 2. Zhejiang Power Company Hangzhou 310007 China
Abstract:The existing engineering application of practical and impact grounding test research show that the radial horizontal grounding electrode on the proper position after adding short conductors can make time-varying electric field tended to distribute more evenly around the grounding body. The paper hereby is aimed at the arrangement of short conductor using the skill of difference time domain method and multiple physical field direct coupling analysis software (COMSOL). The single horizontal grounding electrode and grounding electrodes adding short conductors are the research objects. This paper analyzes the influence of the impact characteristic of seven kinds of grounding electrodes from the view of current shielding effect. The results show that the short conductor arrangement exist weak shielding area in a specific horizontal grounding electrode and outside the weak shielding area short conductors are greatly influenced by end effect. The shielding effect increases with the increase of injection current amplitude for the same structure. In the cases of the short conductor length and horizontal grounding electrode length ratio of 1/30, the proportion of central diffuser value of grounding electrode is bigger and shielding effect is weaker than that of other structure when adjacent short conductors spacing and horizontal grounding electrode length ratio between 10%~15%.
袁涛, 唐妍, 司马文霞, 杨庆, 姜文东, 曹炯. 短导体对水平接地极冲击特性的影响[J]. 电工技术学报, 2015, 30(1): 177-185.
Yuan Tao, Tang Yan, Sima Wenxia, Yang Qing, Jiang Wendong, Cao Jiong. Simulation Analysis of the Impact Characteristic of Grounding Electrode Based on the Current Shielding Effect. Transactions of China Electrotechnical Society, 2015, 30(1): 177-185.
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2015, Vol. 30 
