Optimal Protection Relay Placement in Microgrids

2020 IEEE Kansas Power and Energy Conference (KPEC) Pub Date : 2020-07-01 DOI:10.1109/KPEC47870.2020.9167553

Benjamin Reimer, T. Khalili, A. Bidram, M. Reno, Ronald Matthews

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引用次数: 9

Abstract

This paper proposes an optimal relay placement approach for microgrids. The proposed approach considers both grid-connected and islanded microgrid modes. The algorithm separately calculates the System Average Interruption Frequency Index (SAIFI) of a microgrid in each operating mode. Then, two weighting factors corresponding to different operating modes are used to calculate the overall SAIFI of the microgrid. The objective is to find the optimal relay locations such that the microgrid overall SAIFI is minimized. The power electronics interfaces associated with distributed energy resources may be classified as grid following or grid forming. As opposed to grid-following distributed energy resources (DERs) such as typical solar inverters, grid-forming inverters are able to control the microgrid voltage and frequency at the point of their interconnection. Therefore, these DERs can facilitate the formation of sub-islands in the microgrid when the protective relays isolate a portion of the microgrid. If there is at least one grid-forming DER available in a sub-island, that sub-island can continue supplying its local load. The exchange market algorithm (EMA) is used for optimizing functions. The effectiveness of the proposed optimal relay placement approach is verified using an 18-bus microgrid and IEEE 123-bus test system.

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微电网中保护继电器的优化配置

提出了一种微电网继电器优化布放方法。该方法考虑了并网微电网和孤岛微电网两种模式。该算法分别计算微电网在各运行模式下的系统平均中断频率指数(SAIFI)。然后，采用不同运行模式对应的两个权重因子计算微网的整体SAIFI。目标是找到最佳的继电器位置，使微电网的总体SAIFI最小化。与分布式能源相关联的电力电子接口可分为跟随电网或形成电网。与典型的太阳能逆变器等电网跟随分布式能源(DERs)不同，并网逆变器能够在其互连点控制微电网的电压和频率。因此，当保护继电器隔离微电网的一部分时，这些der可以促进微电网中子岛的形成。如果在子岛中至少有一个形成网格的DER可用，则该子岛可以继续提供其本地负载。采用EMA (exchange market algorithm)算法对函数进行优化。采用18总线微电网和IEEE 123总线测试系统验证了所提出的继电器优化布置方法的有效性。

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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2020 IEEE Kansas Power and Energy Conference (KPEC)

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