Taking the Heat: IEEE Standard 80 and Bimetallic Conductors

2022 IEEE IAS Petroleum and Chemical Industry Technical Conference (PCIC) Pub Date : 2022-09-26 DOI:10.1109/PCIC42668.2022.10181259

R. Southey, Jeffrey T. Jordan, F. Dawalibi

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Abstract

IEEE Standard 80-2013 provides the substation grounding system designer with simple formulae and tabulated data for the estimation of the maximum fault current that can flow through various types and sizes of conductor, for a given duration, before failure due to fusing occurs. Copper conductors are given exhaustive and reasonably accurate treatment. Other types of conductors, however, are given short thrift. Copper-clad steel (CCS) conductors, whose steel cores provide an effective heat sink, appear not to have been studied at all. As a result, the standard provides only an unrealistic simplified methodology based on fixed physical constants to be used for the calculation of CCS current-carrying limits. Computer modeling and lab testing have demonstrated that the highly non-linear heat absorption characteristics of the CCS core, when properly considered, yield considerably different fault current-carrying capacity than IEEE Standard 80-2013 would lead design engineers to expect. A theoretical framework for the calculation of these values is presented. Computed values are compared with those obtained by an independent accredited high voltage test laboratory.

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承受热量:IEEE标准80和双金属导体

IEEE标准80-2013为变电站接地系统设计人员提供了简单的公式和表格数据，用于估计在发生熔断故障之前，在给定时间内可以流过各种类型和尺寸的导体的最大故障电流。对铜导体进行了详尽而合理的精确处理。然而，其他类型的导体被赋予了短暂的节俭。铜包钢(CCS)导体，其钢芯提供有效的散热器，似乎根本没有被研究过。因此，该标准仅提供了一种不切实际的基于固定物理常数的简化方法，用于计算CCS载流限值。计算机建模和实验室测试表明，CCS芯线的高度非线性吸热特性，在适当考虑的情况下，产生的故障载流能力与IEEE 80-2013标准所期望的大不相同。给出了计算这些值的理论框架。计算值与独立认可的高压测试实验室获得的值进行了比较。

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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2022 IEEE IAS Petroleum and Chemical Industry Technical Conference (PCIC)

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