EHV Shunt Capacitor Bank Design and Transient Analysis - A Case Study

2021 IEEE/IAS 57th Industrial and Commercial Power Systems Technical Conference (I&CPS) Pub Date : 2021-04-27 DOI:10.1109/ICPS51807.2021.9416616

Xuan Wu, Kiril Andov, Benjamin B. Leece, Michael L. Skidmore, Matthew R. Louderback, D. J. Meisner, Thomas E. Momme, Kenneth R. Posey

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引用次数: 2

Abstract

Shunt capacitor banks are important for the voltage stability of transmission and distribution networks. In addition, they increase the efficiency of real power transfer. These benefits are amplified in an extra-high-voltage (EHV) system built from longer transmission lines, with expectations for higher reliability. Therefore, a reliable and practical design of EHV shunt capacitor banks is significantly needed. American Electric Power Company (AEP) developed a high-margin, EHV shunt capacitor bank design and protection scheme to reduce the number of failures and ensure proper protection of equipment. In addition, shunt capacitor bank switching may cause transients that can result in damage and misoperations of the capacitor and nearby equipment. This paper describes the design of the EHV (i.e., 345 kV) shunt capacitor bank equipment, protection scheme and transient response and mitigation - with the goal of improving the capacitor's availability and the system's reliability. The findings from this case study may be useful for other similar projects in the industry.

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超高压并联电容器组设计与暂态分析-一个案例研究

并联电容器组对输配网电压稳定具有重要意义。此外，它们还提高了实际功率传输的效率。这些优势在超高压(EHV)系统中得到了放大，该系统由更长的输电线路组成，具有更高的可靠性。因此，可靠实用的超高压并联电容器组设计显得尤为重要。美国电力公司(AEP)开发了一种高利润的超高压并联电容器组设计和保护方案，以减少故障次数，确保设备得到适当的保护。此外，并联电容器组开关可能会引起瞬变，从而导致电容器和附近设备的损坏和误操作。本文介绍了超高压(即345 kV)并联电容器组设备的设计、保护方案和暂态响应与缓解，旨在提高电容器的可用性和系统的可靠性。本案例研究的结果可能对行业中其他类似项目有用。

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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2021 IEEE/IAS 57th Industrial and Commercial Power Systems Technical Conference (I&CPS)

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