Stabilizing multimachine power systems with fuzzy logic using artificial bee colonies

Q4 Energy

Renewable Energy and Power Quality Journal Pub Date : 2023-07-01 DOI:10.24084/repqj21.258

W. Hamanah, Abdullah Baraean, A. Hussein, M. A. Abido

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引用次数: 2

Abstract

Over the past few years, fuzzy logic systems have gained popularity due to their superiority over classical controllers when it comes to enhancing the transient stability of power systems. In this paper, a Fuzzy Logic Power System Stabilizer (FLPSS) is designed to damp local and inter-area oscillations following disturbances through the use of an Artificial Bee Colony Optimization Algorithm (ABC). The designed FLPSS is expected to significantly increase the robustness of power systems and ultimately improve the quality of power supply to end-users. This test system consists of two areas with four machines and eleven buses, with the purpose of evaluating the performance of the ABC-FLPSS under a variety of disturbances and loads. In order to optimize the scaling factors of FLPSSs, the Integral Squared Error (ISE) of rotor speed deviation is formulated as an objective function. Evaluation of the proposed controller involves simulating the test system under different conditions. These conditions range from small perturbations, such as changes in one of the system parameters, to large changes, such as removing a main transmission line, to determine its effectiveness. A comparison of ABC-FLPSS with FLPSS and Conventional Power System Stabilizer (CPSS) shows that the ABC-FLPSS controller is superior to FLPSS and CPSS.

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利用人工蜂群模糊逻辑稳定多机电力系统

在过去的几年里，模糊逻辑系统由于其在提高电力系统暂态稳定性方面优于经典控制器而得到了广泛的应用。本文设计了一种模糊逻辑电力系统稳定器(FLPSS)，通过使用人工蜂群优化算法(ABC)来抑制干扰后的局部和区域间振荡。所设计的FLPSS有望显著提高电力系统的鲁棒性，并最终改善终端用户的供电质量。该测试系统由两个区域、4台机器和11个母线组成，目的是评估ABC-FLPSS在各种干扰和负载下的性能。为了优化FLPSSs的标度因子，将转子转速偏差的积分平方误差(ISE)作为目标函数。对所提出的控制器的评估包括在不同条件下模拟测试系统。这些条件的范围从小的扰动，如系统参数之一的变化，到大的变化，如移除主传输线，以确定其有效性。将ABC-FLPSS与FLPSS和传统电力系统稳定器(CPSS)进行了比较，结果表明ABC-FLPSS控制器优于FLPSS和CPSS。

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

Renewable Energy and Power Quality Journal Energy-Energy Engineering and Power Technology

CiteScore

0.70

自引率

0.00%

发文量

147