Lightning strikes to elevated structures: influence grounding conditions on currents and electromagnetic fields

2005 International Symposium on Electromagnetic Compatibility, 2005. EMC 2005. Pub Date : 2005-10-03 DOI:10.1109/ISEMC.2005.1513543

E. Petrache, F. Rachidi, D. Pavanello, W. Janischewskyj, A. Hussein, M. Rubinstein, V. Shostak, W. Chisholm, J. Chang

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引用次数: 33

Abstract

This paper presents an analysis of lightning return strokes to tall structures. The interaction of lightning with a tall structure is modeled using the antenna theory. The finite ground conductivity as well as the buried grounding system of the tall structure are taken into account in the analysis. It is shown that the current waveform, in sections of the tower close to ground, is somewhat affected by a finite ground conductivity. However, for sections further up the tower, it is not significantly influenced. Furthermore, our simulations show that some fine structure associated with current waveforms measured on the Toronto CN tower can be attributed to the finite ground conductivity. It is also shown that the current path down the tower structure is notably subjected to the skin effect. The current distribution along the buried grounding structure of the tower is also presented, illustrating the dispersion effect as a function of the ground conductivity. Finally, the lightning return-stroke generated electric and magnetic fields computed at a distance of 2 km from the tower are presented. It is shown that some late-time subsidiary peaks are smoothed out by the effect of the propagation along a finitely-conducting ground.

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雷击对高架结构的影响:电流和电磁场的接地条件

本文对高层建筑物的雷电回击进行了分析。利用天线理论建立了闪电与高层结构相互作用的模型。在分析中考虑了有限接地电导率和高层结构的埋地接地系统。结果表明，在塔靠近地面的部分，电流波形受到有限的地面电导率的一定影响。然而，对于塔上更远的部分，它没有明显的影响。此外，我们的模拟表明，与多伦多CN塔上测量到的电流波形相关的一些精细结构可以归因于有限的地面电导率。结果还表明，当前的塔结构下行路径明显受到集肤效应的影响。本文还给出了塔内接地结构的电流分布，说明了分散效应随接地电导率的变化。最后给出了距离铁塔2 km处的雷击返击产生的电场和磁场。结果表明，由于沿有限导地线传播的影响，一些后期辅峰被平滑。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2005 International Symposium on Electromagnetic Compatibility, 2005. EMC 2005.

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