Network reconfiguration and integration of distributed energy resources in distribution network by novel optimization techniques

IF 4.7 3区工程技术 Q2 ENERGY & FUELS

Energy Reports Pub Date : 2024-09-11 DOI:10.1016/j.egyr.2024.08.067

Muhammad Zubair Iftikhar, Kashif Imran

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引用次数: 0

Abstract

Nowadays, electrical load demand in radial distribution networks (RDN) is continuously growing, therefore RDNs are facing some serious challenges like voltage violation and line losses. Since modern RDNs have reconfiguration capabilities, optimal network reconfiguration is preferred over the costly construction of new lines and cables. In addition, the optimal integration of distributed energy resources (DER) helps to decrease above mentioned network challenges. This paper presents an improved version of the radiality maintenance algorithm (IRMA) to solve the optimal reconfiguration problem using a meta-heuristics algorithm. It also proposes two different schemes of algorithms by the blending of a Genetic algorithm (GA) and Teaching learning-based optimization (TLBO) to solve the optimal DER integration problem, where blending enhances the search space of each scheme which helps to find global minima in less iterations and time, while existing algorithms get stuck in local minima with same number of searching agents. The proposed problems are solved by minimizing active power loss by the single objective function and the sum of active power loss, reactive power loss, and voltage deviation index by multi-objective function using the weighted sum method where all objectives are equally dealt with, and their sum is used as single fitness function for the optimization algorithm. Four case studies are simulated using different DER technologies to improve each objective function. The efficiency of the proposed IRMA and two newly developed schemes of optimization algorithms, named GA-TLBO and TLBO-GA, are tested on two IEEE benchmark RDN of 33 and 69 buses. The results validate the efficiency of proposed algorithms that remarkably minimize a single objective from 210.9800 kW in the base case to 58.8768 kW, whereas existing algorithms like GWO and HHO were able to only reduce it to 72.7861 kW and 72.900 kW for IEEE 33 bus RDN, respectively. Similarly, for IEEE 69 bus system, single objective is reduced from base case of 224.9917 kW to 36.2543 kW, while existing algorithms like QOTLBO and QOSIMBO were only able to reduce it to 71.6250 kW and 71 kW, respectively. Furthermore, in multi-objective functions, reactive power losses and voltage deviation are also significantly improved from their base values. After that, the results of improved algorithms are compared with those of existing algorithms in the literature review for a comprehensive evaluation, which proves that proposed algorithm schemes are much more efficient and stable for the proposed problem as well as for standard benchmark optimization functions.

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通过新型优化技术实现配电网中的网络重组和分布式能源资源整合

如今，径向配电网络（RDN）中的电力负荷需求不断增长，因此 RDN 面临着电压违规和线路损耗等严峻挑战。由于现代 RDN 具有重新配置功能，因此优化网络重新配置比昂贵的新线路和电缆建设更受欢迎。此外，分布式能源资源（DER）的优化整合有助于减少上述网络挑战。本文提出了一种改进版的径向度维护算法（IRMA），使用元启发式算法来解决优化重新配置问题。本文还通过混合遗传算法（GA）和基于教学学习的优化（TLBO）提出了两种不同的算法方案，以解决最优 DER 集成问题，其中混合算法增强了每种方案的搜索空间，有助于以更少的迭代次数和时间找到全局最小值，而现有算法在搜索代理数量相同的情况下会陷入局部最小值。所提出的问题是通过单目标函数最小化有功功率损耗，以及多目标函数最小化有功功率损耗、无功功率损耗和电压偏差指数之和来解决的。使用不同的 DER 技术模拟了四个案例研究，以改善每个目标函数。在 33 和 69 总线的两个 IEEE 基准 RDN 上测试了提议的 IRMA 和两个新开发的优化算法方案（GA-TLBO 和 TLBO-GA）的效率。结果验证了所提算法的高效性，在 IEEE 33 总线 RDN 中，所提算法显著地将单一目标从基本情况下的 210.9800 kW 降至 58.8768 kW，而 GWO 和 HHO 等现有算法只能将其分别降至 72.7861 kW 和 72.900 kW。同样，对于 IEEE 69 总线系统，单一目标从基本情况下的 224.9917 kW 降至 36.2543 kW，而 QOTLBO 和 QOSIMBO 等现有算法只能分别将其降至 71.6250 kW 和 71 kW。此外，在多目标函数中，无功损耗和电压偏差也在基础值的基础上有了显著改善。随后，将改进算法的结果与文献综述中现有算法的结果进行了比较，以进行综合评估，结果证明，对于所提出的问题以及标准基准优化函数，所提出的算法方案更加高效和稳定。

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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来源期刊

Energy Reports Energy-General Energy

CiteScore

8.20

自引率

13.50%

发文量

2608

审稿时长

38 days

期刊介绍： Energy Reports is a new online multidisciplinary open access journal which focuses on publishing new research in the area of Energy with a rapid review and publication time. Energy Reports will be open to direct submissions and also to submissions from other Elsevier Energy journals, whose Editors have determined that Energy Reports would be a better fit.