实际接地系统的冲击特性试验研究(英文) 被引量：4

Experimental Investigation of Impulse Characteristics of Practical Ground Electrode Systems

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摘要 In this work,the results of an experimental study of the impulse characteristic of practical ground electrodes consisting of horizontal conductors of various lengths and full-scale tower footings were reported.These electrodes were installed at an outdoor test site having nonuniform soil,with equipment facilities for generating low-and high-magnitude impulse currents.The tests on the horizontal electrode were used to determine the effective length,the voltage and current distribution along the electrode length and the effect of the injection point along the electrode.The tests on the tower footings were used to determine impulse resistance and demonstrate its non-linear variation with current magnitude.Computer simulations of the test electrodes using the electromagnetic field method showed good agreement with the measured result. In this work, the results of an experimental study of the impulse characteristic of practical ground electrodes consisting of horizontal conductors of various lengths and full-scale tower footings were reported. These electrodes were installed at an outdoor test site having non-uniform soil, with equipment facilities for generating low- and high- magnitude impulse currents. The tests on the horizontal electrode were used to determine the effective length, the voltage and current distribution along the electrode length and the effect of the injection point along the electrode. The tests on the tower footings were used to determine impulse resistance and demonstrate its non-linear variation with current magnitude. Computer simulations of the test electrodes using the electromagnetic field method showed good agreement with the measured result.

作者 N.Harid M.Ahmeda H.Griffiths A.Haddad

机构地区 High Voltage Energy System Group.School of Engineering

出处《高电压技术》 EI CAS CSCD 北大核心 2011年第11期2721-2726,共6页 High Voltage Engineering

关键词 ground electrode impulse current ground impedance effective length horizontal electrode tower footing soil ionisation impulse resistance ground electrode impulse current ground impedance effective length horizontal electrode tower footing soil ionisation impulse resistance

分类号 TM866 [电气工程—高电压与绝缘技术]

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参考文献21

1Mazetti C, Veca G M. Impulse behavior of grounding electrodes [J]. IEEE Transactions on Power Apparatus and Systems, 1983, 102(9): 3148-3154.
2Jinliang He, Yanqing Gao, Rong Zeng, et al. Effective length of counterpoise wire under lightning current[J]. IEEE Transac- tions on Power Delivery, 2005, 20(2): 1585-1591.
3Mishra A K, Ametani A, Nagaoka N, et al. Non-uniform char acteristics of a horizontal grounding electrode[J]. IEEE Trans- actions on Power Delivery, 2007, 22(4):2327-2334.
4Grcev L. Modelling of grounding electrodes under lightning cur- rents[J]. IEEE Transactions on Electromagnetic Compatibility, 2009, 51(3): 559-571.
5Takeushi M, Yasuda Y, Fukuzono H, et al. Impulse character- istics of a 500 kV transmission tower footing base with various grounding electrodes[C]// 24th International Conference on Lighting Protection. Birmingham, UK:[s. n.], 1998" 513- 517.
6Cherney E A, Ringler K G, Kolcio N, et al. 5tep and tOUCh po- tentials at faulted transmission towers[J]. IEEE Transactions on Power Apparatus and Systems, 1981, 100(7) : 3312-3320.
7Dawalibi F P, Donoso F. Integrated analysis software for grounding, EMF and EMI[J], IEEE Computer Applications in Power, 1993, 6(2):19-24,.
8Lorentzou M I, Hatziargriou N D. Modelling ot long grounding conductors using EMTP[C]// International Conference on Pow- er System Transients. Athens, Greece: [s. n.], 1999: 20-24.
9Liu Y, Theethayi N, Thottappillil R. An engineering model for transient analysis of grounding system under lightning strikes: non-uniform transmission line approach[J]. IEEE Transactions on Power Delivery, 2005, 20(2): 722-730.
10Liu Y, Theethayi N, Thottappillil R. Investigating the validity of existing definitions and empirical equations of effective length/area of grounding wire/grid for transient studies[J]. Journal of Electrostatics, 2007, 65(5/6): 329-335.

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2包玉树.对变压器局放试验典型接地问题的探讨[J].高压电器,2004,40(4):315-316. 被引量：4
3刘晓亮,蔡水利,赵树平,许跟承.特高压交流油纸电容式套管的研究[J].电瓷避雷器,2007(2):1-6. 被引量：17
4海特维西李远.电感计算[M].北京:国防工业出版社,1960.5-10.
5DL/T621-1997.交流电气装置的接地[S].[S].,1997..
6GB/T7252-2001 变压器油中溶解气体分析和判断导则[S],2001.
7DL560-1995电业安全工作规程(高压试验室部分)[S],1995.
8Motoyama H. Electromagnetic transient response of buried bare wire and ground grid[J]. IEEE Transactions on Power Delivery, 2007, 22(3): 1673-1679.
9Papalexopoulos A D, Meliopoulos A P. Frequency dependent characte- ristics of grounding systems[J]. IEEE Transactions on Power Delivery, 1087, 2(4): 1073-1081.
10Menter F E, Grcev L. EMTP-based model for grounding system anal- ysis[J]. I EEE Transactions on Power Delivery, 1994, 9(4): 1838-1849.

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实际接地系统的冲击特性试验研究(英文) 被引量：4

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