Improved Electrogeometric Model Suitable for EHV and UHV Transmission Lines Developed through Breakdown Testing for Long Air Gaps

As a type of engineering model used for solving lightning-shielding problems, the electrogeometric model has been widely used for assessing lightning-shielding failure in high-voltage and extra-high-voltage transmission lines. However, with the increase of voltage levels in ultra-high-voltage lines...

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Bibliographic Details
Published inEnergies (Basel) Vol. 10; no. 3; p. 333
Main Authors Deng, Yeqiang, Wang, Yu, Li, Zhijun, Dai, Min, Wen, Xishan, Lan, Lei, An, Yunzhu, E, Shenglong
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.03.2017
Subjects
Electric power
Electricity distribution
electrogeometric model
Electrogeometric models
Engineering
High voltages
Lightning strikes
lightning-shielding failure
Mathematical models
negative switching surge discharge tests of long air gaps
Polarity
Probability distribution
Return strokes (lightning)
Shielding
striking distance
Transmission lines
ultra-high-voltage transmission line
Velocity
Velocity distribution
Voltage
Japan
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Summary:As a type of engineering model used for solving lightning-shielding problems, the electrogeometric model has been widely used for assessing lightning-shielding failure in high-voltage and extra-high-voltage transmission lines. However, with the increase of voltage levels in ultra-high-voltage lines and the growth of the air gap, the results previously yielded by the electrogeometric model are no longer consistent with those observed. Therefore, this study corrected the equation for the relationship between lightning current and striking distance, by using data on a negative polarity 50% discharge voltage from the rod-rod gap −20/2500 μs switching impulse test wherein an air gap of up to 10 m was first tested. Subsequently, the return stroke velocity distribution observed by Idone was newly applied. In addition, the correction factor for the ground was corrected in this study. Thus, an improved electrogeometric model for application in EHV and UHV transmission lines is proposed in this paper. By employing the improved electrogeometric model to calculate the frequency of lightning strikes of 500 and 1000 kV transmission lines in Japan and a 1000 kV transmission line in China, we found that the results calculated using the improved electrogeometric model were closer to the actual observations in Japan than was the original electrogeometric model. The improved electrogeometric model provides a more reliable foundation for lightning-shielding design of extra-high-voltage and ultra-high-voltage transmission lines.
ISSN:1996-1073
1996-1073
DOI:10.3390/en10030333