Impacts of Earthing Arrangement on Lightning Protection Efficiency of Grid Connected PV System

中国防雷 Pub Date : 2021-09-20 DOI:10.1109/ICLPandSIPDA54065.2021.9627347

Z. M. Khurshid, C. Gomes

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引用次数: 5

Abstract

This paper investigates the potential and current distribution of a grid-connected (PV) system with surge protective devices connected according to the European Commission for Electrotechnical Standardization (CENELEC) under various values of grounding resistance for isolated and integrated AC and DC earthing systems. A 400 kW PV system is implemented using PSCAD/EMTDC software, where the system is connected to a 33 kV grid through a boost transformer. The simulation results were obtained for negative subsequent lightning stroke (50% value), developed by Heidler function. The current was injected separately into both the DC and the AC sides of the PV inverter. The values of resistance of the earthing systems have been varied over a set of combinations. The results show that when the AC and DC sides are separately earthed for non-zero values of resistance, the line potentials reach very high values posing a severe risk of a system to earth arcing. The situation is worse when the lightning strikes the DC side and when the DC side earth resistance has high values. The situation improves significantly when the earthing systems are integrated. It is advisable to achieve an earth resistance below 5 Ω for the integrated earthing system.

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接地布置对并网光伏系统防雷效率的影响

本文研究了根据欧洲电工标准化委员会(CENELEC)的要求，在隔离和集成交流和直流接地系统的不同接地电阻值下，带有浪涌保护装置的并网(PV)系统的电位和电流分布。采用PSCAD/EMTDC软件实现了一个400 kW的光伏系统，该系统通过升压变压器连接到33 kV电网。模拟结果为负后续雷击(50%值)，采用Heidler函数发展。将电流分别注入光伏逆变器的直流侧和交流侧。在一组组合中，接地系统的电阻值发生了变化。结果表明，当交流侧和直流侧分别为非零阻值接地时，线路电位达到非常高的值，对系统造成严重的接地弧风险。当雷电击中直流侧和直流侧接地电阻较大时，情况更糟。当接地系统集成后，这种情况明显改善。综合接地系统接地电阻宜低于5 Ω。

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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中国防雷

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