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用于不同网络中光伏分布式发电高效布局和容量确定的各种优化算法。

Various optimization algorithms for efficient placement and sizing of photovoltaic distributed generations in different networks.

作者信息

Diab Ahmed A Zaki, Mahmoud Fayza S, Sultan Hamdy M, El-Sayed Abou-Hashema M, Ismeil Mohamed A, Kamel Omar Makram

机构信息

Department of Electrical Engineering, Faculty of Engineering, Minia University, Minia, Egypt.

Minia National University, Minia, Egypt.

出版信息

PLoS One. 2025 Apr 2;20(4):e0319422. doi: 10.1371/journal.pone.0319422. eCollection 2025.

DOI:10.1371/journal.pone.0319422
PMID:40173203
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11964283/
Abstract

Recent research has concentrated on emphasizing the significance of incorporating renewable distributed generations (RDGs), like photovoltaic (PV) and wind turbines (WTs), into the distribution system to address issues related to distributed generation (DG) allocation. The key implications of integrating RDGs include the improvement of voltage profiles and the minimization of power losses. Various optimization techniques, namely Salp Swarm Algorithm (SSA), Marine Predictor Algorithm (MPA), Grey Wolf Optimizer (GWO), Improved Grey Wolf Optimizer (IGWO), and Seagull Optimization Algorithm (SOA), have been applied to achieve optimal allocation and sizing of RDGs in radial distributed systems (RDS). The present paper is structured in two phases. In the initial phase, the Loss Sensitivity Factor (LSF) is employed to identify the most suitable nodes for integrating RDGs. In the second phase, within the selected candidate nodes from the first phase, the optimal location and capacity of RDGs are determined. Additionally, a comprehensive comparison of the proposed optimization methods is conducted to select the most effective solutions for the allocation of units of RDGs. The efficacy of the utilized techniques is validated through testing on two distinct networks, namely the IEEE 33 and 69 buses RDS in MATLAB, with attainments compared against other techniques. Moreover, a larger RDS system of 118- bus IEEE system has been considered in order to enhance its power quality indices. Moreover, a real case of study from Egypt of 15 bus has been considered and evaluated with considering the applied techniques. The results show the enhancement of the voltage profile and decreasing the power losses of the tested system with the DG systems with the superiority of the MPA and SSA algorithms.

摘要

近期的研究集中于强调将可再生分布式发电(RDG),如光伏(PV)和风力涡轮机(WT),并入配电系统以解决与分布式发电(DG)分配相关问题的重要性。整合RDG的关键意义包括改善电压分布和使功率损耗最小化。各种优化技术,即鹈鹕群算法(SSA)、海洋预测算法(MPA)、灰狼优化器(GWO)、改进灰狼优化器(IGWO)和海鸥优化算法(SOA),已被应用于在辐射状分布式系统(RDS)中实现RDG的最优分配和容量确定。本文分为两个阶段。在初始阶段,采用损耗灵敏度因子(LSF)来确定最适合并入RDG的节点。在第二阶段,在从第一阶段选定的候选节点内,确定RDG的最优位置和容量。此外,对所提出的优化方法进行了全面比较,以选择用于RDG单元分配的最有效解决方案。通过在MATLAB中的两个不同网络,即IEEE 33和69节点RDS上进行测试,验证了所采用技术的有效性,并将成果与其他技术进行了比较。此外,还考虑了一个更大的118节点IEEE系统的RDS,以提高其电能质量指标。此外,还考虑并评估了埃及一个15节点的实际案例研究,并考虑了所应用的技术。结果表明,采用DG系统可改善测试系统的电压分布并降低功率损耗,其中MPA和SSA算法表现出优越性。

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4
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