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LIGHTNING ELECTROMAGNETIC FIELDS AROUND TRANSMISSION LINES USING FDTD

The 19th International Symposium on High Voltage Engineering, Pilsen, Czech Republic, August, 23 – 28, 2015 • 2015
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Publication Information
Authors Samy M. Ghania
Keywords Lightning electromagnetic field, Transmission lines, FDTD
Journal The 19th International Symposium on High Voltage Engineering, Pilsen, Czech Republic, August, 23 – 28, 2015
Publisher The 19th International Symposium on High Voltage Engineering, Pilsen, Czech Republic, August, 23 – 28, 2015
Volume The 19th International Symposium on High Voltage Engineering, Pilsen, Czech Republic, August, 23 – 28, 2015
Issue The 19th International Symposium on High Voltage Engineering, Pilsen, Czech Republic, August, 23 – 28, 2015
Pages The 19th International Symposium on High Voltage Engineering, Pilsen, Czech Republic, August, 23 – 28, 2015
publication.type International
Paper Link Not Available
Supplementary Materials Not Available
Abstract
For proper design of the transmission and distribution insulation systems, it is
necessary to fully clarify the lightning phenomena characteristics. In this paper, two typical
power transmission lines (500 kV and 220 kV) are modeled to compute the lightning
electromagnetic fields around the transmission lines. The lightning electromagnetic fields
around the different power lines are calculated using the finite difference time domain
(FDTD) method with Maxwell’s equations. Two selected zones are used to capture the
electromagnetic fields while lightning strike. The first zone is around the insulators and the
second is at the ground level underneath the power line at 1 m above ground and at the
power line right of way (ROW). The correlation between the induced magnetic and electric
fields is verified in the free space inside the two selected zones. The induced
electromagnetic fields at different positions of each power line phases are evaluated. The
obtained results show that while lightning strikes the conductor, the waveforms of
electromagnetic field obtained at the selected monitoring points are the same as the
lightning current's waveform. The amplitude of the electromagnetic field intensities exhibits
a stabile linear relationship with the lightning currents as the free air intrinsic impedance.