A calculation model for determination of impedance of power high voltage single-core cables with polymer insulation

EngRN: Power Engineering (Topic) Pub Date : 2021-06-25 DOI:10.20998/2074-272x.2021.3.08

G. Bezprozvannych, I. Kostiukov

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引用次数: 2

Abstract

Introduction. The wave parameters of power cables with polymer insulation differ significantly from the parameters of overhead lines and power transformers. As a result, there are more and more objects in electrical networks for which the occurrence of complex multi frequency transients, accompanied by dangerous overvoltages, should be expected. Purpose. To develop a computational model of the complex impedance of high-voltage single-core power cables of coaxial design required to determine the frequency dependencies of the active resistance and inductance of the conductive core and metal shield, taking into account the surface effect and proximity effect. Methodology. The method is based on solving a system of linear algebraic Kirchhoff equations (SLAE) for magnetically coupled contours. SLAE can be used to calculate conductors taking into account the skin effect and proximity effect. Practical value. The developed model is the basis for determining the characteristic impedance of high-voltage single-core power cables in a wide range of frequencies required to establish adequate criteria for evaluating the parameters of high-frequency effects critical for cross linked polyethylene insulation.

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聚合物绝缘高压单芯电力电缆阻抗测定的计算模型

介绍。聚合物绝缘电力电缆的波动参数与架空线路和电力变压器的波动参数有很大的不同。因此，电网中越来越多的对象可能出现复杂的多频瞬变，并伴有危险的过电压。目的。为了建立同轴设计高压单芯电力电缆复杂阻抗的计算模型，需要考虑表面效应和邻近效应，确定导电芯线和金属屏蔽的有源电阻和电感的频率依赖关系。方法。该方法基于求解磁耦合轮廓线的线性代数Kirchhoff方程(SLAE)系统。SLAE可以用来计算导体，同时考虑到集肤效应和接近效应。实用价值。所开发的模型是确定高压单芯电力电缆在宽频率范围内的特性阻抗的基础，需要建立足够的标准来评估交联聚乙烯绝缘的关键高频效应参数。

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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EngRN: Power Engineering (Topic)

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