发电厂地下 XLPE 220 千伏电力电缆产生的磁污染

Q3 Engineering

Diagnostyka Pub Date : 2023-12-21 DOI:10.29354/diag/177323

Ilies Rezzag Bara, Ayad Ahmed Nour El Islam, Wafa Krika, Omar Fezazi, Benyekhlef Larouci

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引用次数: 0

摘要

电网的扩张需要建设新的发电厂，并扩展架空和地下输配电系统。然而，XPLE 220 千伏等地下电力电缆会造成严重的电磁污染，尤其是在城市地区。本文主要通过分析、数值模拟（有限元分析）和实验测量来评估和预测此类磁辐射。本文旨在通过调整电缆的水平和垂直距离（x、y），最大限度地减少磁辐射，以此作为一种技术解决方案。此外，考虑到不同的负载和条件，研究还调查了不同大小和频率的故障的影响。模拟结果表明，有几个因素会导致磁污染升级。这些因素包括电缆之间的距离过近、故障和高电流强度....。然而，随着电缆之间水平和垂直距离的增加，磁场强度会降低，从而导致磁污染的减少。通过比较评估地下电缆的磁场辐射，发现测量值和计算值非常相似。最终，经过验证的模拟模型成为在不同故障条件和位置下评估、预测和减轻电磁污染的宝贵工具。

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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Magnetic pollution produced by underground XLPE 220 kV Power Cable in Power Plant

The expansion of the electrical network necessitates the construction of new power plants and the extension of overhead and underground power transmission and distribution systems. However, underground power cables, such as XPLE 220 kV, can cause significant electromagnetic pollution, particularly in urban areas. This paper focuses on the evaluation and prediction of such magnetic emissions using analytical, numerical simulation (the finite element analysis), and experimental measurement. The paper aim is to minimize the magnetic emissions through the adjustment of the horizontal and vertical distances (x, y) of cables, serving as a technical solution. Additionally, the study investigated the impact of faults with varying magnitude and frequency, considering different loads and conditions. The simulation results indicate that several factors contribute to the escalation of magnetic pollution. These factors include a close proximity between cables, faults, and high current intensities.... However, as the distance between cables increases both horizontally and vertically, the strength of the magnetic field decreases, leading to a reduction in magnetic pollution. A comparison was carried out to assess the magnetic emissions of the underground cable, revealing a notable resemblance between the measured and calculated values. Ultimately, the validated simulation model serves as a valuable tool for evaluating, predicting, and mitigating electromagnetic pollution under different fault conditions and positions.

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来源期刊

Diagnostyka Engineering-Mechanical Engineering

CiteScore

2.20

自引率

0.00%

发文量

期刊介绍： Diagnostyka – is a quarterly published by the Polish Society of Technical Diagnostics (PSTD). The journal “Diagnostyka” was established by the decision of the Presidium of Main Board of the Polish Society of Technical Diagnostics on August, 21st 2000 and replaced published since 1990 reference book of the PSTD named “Diagnosta”. In the years 2000-2003 there were issued annually two numbers of the journal, since 2004 “Diagnostyka” is issued as a quarterly. Research areas covered include: -theory of the technical diagnostics, -experimental diagnostic research of processes, objects and systems, -analytical, symptom and simulation models of technical objects, -algorithms, methods and devices for diagnosing, prognosis and genesis of condition of technical objects, -methods for detection, localization and identification of damages of technical objects, -artificial intelligence in diagnostics, neural nets, fuzzy systems, genetic algorithms, expert systems, -application of technical diagnostics, -diagnostic issues in mechanical and civil engineering, -medical and biological diagnostics with signal processing application, -structural health monitoring, -machines, -noise and vibration, -analysis of technical and civil systems.