A new approach for the flashover voltage prediction using an arc propagation reproduction on a high-voltage insulator

COMPEL Pub Date : 2024-02-26 DOI:10.1108/compel-11-2023-0569
Dyhia Doufene, Samira Benharat, Abdelmoumen Essmine, Oussama Bouzegaou, Slimane Bouazabia
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Abstract

Purpose

This paper aims to introduce a new numerical model that predicts the flashover voltage (FOV) value in the presence of polluted air surrounding a high-voltage insulator. The model focuses on simulating the propagation of arcs and aims to improve the accuracy and reliability of FOV predictions under these specific conditions.

Design/methodology/approach

This arc propagation method connecting the high voltage fitting and the grounded insulator cap involves a two-step process. First, the electric field distribution in the vicinity of the insulator is obtained using finite element method analysis software. Subsequently, critical areas with intense electric field strength are identified. Random points within these critical areas are then selected as initial points for simulating the growth of electric arcs.

Findings

by increasing the electric voltage applied to the insulator fittings, the arc path is, step by step, generated until a breakdown occurs on the polluted air surrounding the insulator surface, and thus a prediction of the FOV value.

Practical implications

The proposed model for the FOV prediction can be a very interesting alternative to dangerous and costly experimental tests requiring an investment in time and materials.

Originality/value

Some works were done trying to reproduce discharge propagation but it was always with simplified models such as propagation in one direction from a point to a plane. The difficulty and the originality of the present work is the geometry complexity of the insulator with arc propagation in three distinct directions that will require several proliferation conditions.

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利用高压绝缘体上的电弧传播再现预测闪络电压的新方法
目的 本文旨在介绍一种新的数值模型,用于预测高压绝缘子周围存在污染空气时的闪络电压(FOV)值。该模型重点模拟电弧的传播,旨在提高这些特定条件下闪络电压预测的准确性和可靠性。设计/方法/途径这种连接高压接头和接地绝缘子帽的电弧传播方法包括两个步骤。首先,使用有限元法分析软件获得绝缘子附近的电场分布。随后,确定具有强烈电场强度的临界区域。结果通过增加施加在绝缘体配件上的电压,电弧路径一步步产生,直到绝缘体表面周围的污染空气发生击穿,从而预测出 FOV 值。实用意义所提出的 FOV 预测模型是一种非常有趣的替代方法,可以替代需要投入时间和材料的危险而昂贵的实验测试。本研究的难点和独创性在于绝缘体几何形状的复杂性,电弧在三个不同方向的传播需要多个扩散条件。
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