Optimal coordination of overcurrent relays in microgrids using meta-heuristic algorithms NSGA-II and harmony search

IF 3.8 3区计算机科学 Q1 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE Sustainable Computing-Informatics & Systems Pub Date : 2024-07-14 DOI:10.1016/j.suscom.2024.101020

Gholamreza Abdi , Mehdi Ahmadi Jirdehi , Hasan Mehrjerdi

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Abstract

The emergence of distributed generation from renewable energy sources has led to the adoption microgrids as an alternative energy solution. However, implementing microgrids presents challenges, particularly in coordinating relay protection, due to factors like distributed generation sources, bidirectional power flow, variable short-circuit levels, and changes in network behavior. Although overcurrent relays (OCR) are frequently utilized in microgrid protection, a more adaptable strategy is needed as grid architectures transition from radial to non-radial. This paper proposes a new method to optimize the coordination of OCRs in microgrids by adjusting parameters like time multiplier settings (TMS), plug settings (PS), and characteristic curve selection. The study utilizes meta-heuristic techniques such as the harmony search algorithm (HSA) and the non-dominated sorting genetic algorithm-II (NSAGA-II) for optimal coordination. Simulations on a microgrid and bus test system demonstrate the effectiveness of the proposed approach in enhancing protection indicators like sensitivity, speed, selectivity, and reliability in microgrid operations. The results also indicate that the computation time of HSA is less than NSGA-II, but with an increase in DGs capacity, there is a continuous tendency to reduce the relay operation time.

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使用元启发式算法 NSGA-II 和和谐搜索优化微电网中的过流继电器协调

可再生能源分布式发电的出现促使人们采用微电网作为替代能源解决方案。然而，由于分布式发电源、双向电力流、可变短路水平和网络行为变化等因素，微电网的实施面临着挑战，尤其是在协调继电保护方面。虽然微电网保护中经常使用过流继电器 (OCR)，但随着电网架构从径向过渡到非径向，需要一种适应性更强的策略。本文提出了一种新方法，通过调整时间乘数设置 (TMS)、插头设置 (PS) 和特性曲线选择等参数来优化微电网中 OCR 的协调。该研究采用了元启发式技术，如和谐搜索算法（HSA）和非支配排序遗传算法-II（NSAGA-II）来优化协调。在微电网和总线测试系统上进行的仿真证明了所提方法在提高微电网运行中的灵敏度、速度、选择性和可靠性等保护指标方面的有效性。结果还表明，HSA 的计算时间少于 NSGA-II，但随着 DGs 容量的增加，继电器运行时间有持续缩短的趋势。

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来源期刊

Sustainable Computing-Informatics & Systems COMPUTER SCIENCE, HARDWARE & ARCHITECTUREC-COMPUTER SCIENCE, INFORMATION SYSTEMS

CiteScore

10.70

自引率

4.40%

发文量

142

期刊介绍： Sustainable computing is a rapidly expanding research area spanning the fields of computer science and engineering, electrical engineering as well as other engineering disciplines. The aim of Sustainable Computing: Informatics and Systems (SUSCOM) is to publish the myriad research findings related to energy-aware and thermal-aware management of computing resource. Equally important is a spectrum of related research issues such as applications of computing that can have ecological and societal impacts. SUSCOM publishes original and timely research papers and survey articles in current areas of power, energy, temperature, and environment related research areas of current importance to readers. SUSCOM has an editorial board comprising prominent researchers from around the world and selects competitively evaluated peer-reviewed papers.