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使用增强型人工蜂鸟算法在重构的辐射状配电网中优化分布式发电机、电容器和电动汽车充电站的布局。

Optimized placement of distributed generators, capacitors, and EV charging stations in reconfigured radial distribution networks using enhanced artificial hummingbird algorithm.

作者信息

Sahay Sumeet, Biswal Saubhagya Ranjan, Shankar Gauri, Jha Amitkumar V, Appasani Bhargav, Srinivasulu Avireni, Nsengiyumva Philibert

机构信息

Department of Electrical Engineering, Indian Institute of Technology (ISM), Dhanbad, Jharkhand, India.

Vignan's Foundation for Science Technology and Research, Guntur, Andhra Pradesh, India.

出版信息

Sci Rep. 2025 Apr 1;15(1):11144. doi: 10.1038/s41598-025-89089-8.

DOI:10.1038/s41598-025-89089-8
PMID:40169734
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11962167/
Abstract

This study presents an assessment of concurrently identifying the best location and size of distributed generators (DGs), shunt capacitors (SCs), and electric vehicle charging stations (EVCSs) in optimally reconfigured radial distribution networks (RDNs). A comprehensive literature review indicates that this multi-unit combination has the potential to enhance RDN performance significantly, but it remains an underexplored area of research. Therefore, further in-depth investigation is necessary to understand and fully maximize the benefits of this method. The optimal placement and sizing (OPS) of the mentioned multi-unit in RDNs is realized by employing a metaheuristic optimization technique subject to the fulfillment of a well-defined fuzzified-objective function comprising of line losses reduction, power factor improvement, voltage deviation reduction, and DG penetration limit. Employing the concept of centroid-based oppositional learning (COL), an improved version of the artificial hummingbird algorithm (AHA), named COLAHA, is proposed to decipher the adopted issue. The results achieved utilizing the offered approach are matched with those of the additional innovative algorithms such as the basic AHA, arithmetic optimization algorithm, genetic algorithm, and whale optimization algorithm. By evaluating it against several benchmark functions, the effectiveness of the proposed COLAHA is established. The performance of the aforementioned studied algorithms is further tested to find the OPS of DGs, SCs and EVCSs in the standard IEEE 69- and 118-bus RDNs. Results obtained conclude that the COLAHA has offered quick convergence and the best results over the others for all the studied combinations of the multi-unit model.

摘要

本研究对在优化重构的辐射状配电网(RDN)中同时确定分布式发电机(DG)、并联电容器(SC)和电动汽车充电站(EVCS)的最佳位置和容量进行了评估。全面的文献综述表明,这种多单元组合有潜力显著提高RDN的性能,但它仍是一个未被充分探索的研究领域。因此,有必要进行进一步深入研究,以理解并充分最大化这种方法的益处。通过采用一种元启发式优化技术,在满足由降低线路损耗、提高功率因数、降低电压偏差和DG穿透极限组成的明确模糊目标函数的前提下,实现了上述多单元在RDN中的最优布局和容量确定(OPS)。利用基于质心的对立学习(COL)概念,提出了一种改进版的人工蜂鸟算法(AHA),即基于质心对立学习的人工蜂鸟算法(COLAHA)来解决所采用的问题。利用所提供方法获得的结果与其他创新算法(如基本AHA、算术优化算法、遗传算法和鲸鱼优化算法)的结果进行了匹配。通过针对几个基准函数对其进行评估,确定了所提出的COLAHA的有效性。进一步测试了上述研究算法的性能,以找到标准IEEE 69节点和118节点RDN中DG、SC和EVCS的OPS。获得的结果表明,对于多单元模型的所有研究组合,COLAHA都具有快速收敛性,并且比其他算法取得了更好的结果。

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本文引用的文献

1
Enhancement of distribution system performance with reconfiguration, distributed generation and capacitor bank deployment.通过重新配置、分布式发电和电容器组部署提高配电系统性能。
Heliyon. 2024 Feb 17;10(7):e26343. doi: 10.1016/j.heliyon.2024.e26343. eCollection 2024 Apr 15.
2
Mathematical and experimental analyses of oppositional algorithms.对立算法的数学和实验分析。
IEEE Trans Cybern. 2014 Nov;44(11):2178-89. doi: 10.1109/TCYB.2014.2303117.