Simultaneous Distribution Network Reconfiguration and Optimal Placement of Distributed Generation

Journal of Applied Materials and Technology Pub Date : 2019-09-25 DOI:10.31258/jamt.1.1.46-53

A. Kunya, G. Shehu, U. M. Hassan, Abdurrahman Umar Lawal

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Abstract

A reliable, eco- and nature-friendly operation has been the major concern of modern power system (PS). To improve the PS reliability and reduce the adverse environmental effect of conventional thermal generation facilities, renewable energy based distributed generation (RDG) are being enormously integrated to low and medium voltage distribution networks (DN). However, if these systems are not properly deployed, the reliability and stability of the PS will be endangered and its quality can be dreadfully jeopardized. Among the measures taken to avoid such is optimizing the location and size of each RDG unit in the DNs. These networks are generally operated in a radial configuration, though they can be reconfigured to other topologies to achieve certain objectives. Both RDG placement/sizing and DN reconfiguration are highly non-linear, multi-objective, constrained and combinatorial optimization problems. In this study, a hybrid of Particle Swarm Optimization (PSO) and real-coded Genetic Algorithm (GA) techniques is employed for DN reconfiguration and optimal allocation (size and location) of multiple RDG units in primary DNs simultaneously. The objectives of the proposed technique are active power loss reduction, voltage profile (VP) and feeder load balancing (LB) improvement. It is carried out subject to some technical constraints, with the search space being the set of DN branches, DG sizes and potential locations. To ascertain the effectiveness of the technique, it is implemented on standard IEEE 16-bus, 33-bus and 69-bus test DNs. The proposed algorithm is implemented in MATLAB and MATPOWER environments. It is observed the power loss, voltage deviation and LB are found to be reduced by 32.84%, 12.33% and 24.03% of their respective inherent values in the biggest system when the system is reconfigured only. With the optimized RDGs placed in the reconfigured systems, a further reductions of 46.27%, 25.92% and 36.65% are observed respectively.

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同步配电网重构与分布式发电优化配置

可靠、环保、自然的运行已成为现代电力系统的主要关注点。为了提高PS的可靠性和减少传统火力发电设施对环境的不利影响，可再生能源分布式发电(RDG)正在大量集成到中低压配电网(DN)中。然而，如果这些系统部署不当，将危及PS的可靠性和稳定性，并可能严重损害PS的质量。为避免这种情况，采取的措施之一是优化各区域内RDG单元的位置和大小。这些网络通常在径向配置中运行，尽管它们可以重新配置为其他拓扑以实现某些目标。RDG放置/大小和DN重构都是高度非线性、多目标、约束和组合优化问题。本研究采用粒子群优化(PSO)和实数编码遗传算法(GA)相结合的方法，同时对主DNs中的多个RDG单元进行DN重构和优化配置(大小和位置)。该技术的目标是降低有功功率损耗，改善电压分布(VP)和馈线负载平衡(LB)。它的执行受到一些技术限制，搜索空间是DN分支，DG大小和潜在位置的集合。为了验证该技术的有效性，在标准的IEEE 16总线、33总线和69总线测试dn上实现了该技术。该算法在MATLAB和MATPOWER环境下实现。观察发现，仅对系统进行重新配置时，最大系统的功率损耗、电压偏差和LB分别比其固有值降低了32.84%、12.33%和24.03%。将优化后的rdg放置在重新配置的系统中，可以分别进一步降低46.27%、25.92%和36.65%。

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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Journal of Applied Materials and Technology

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