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基于光伏电源的气球效应辨识器支持的蝙蝠算法在微电网中的高级负荷频率控制。

Advanced load frequency control of microgrid using a bat algorithm supported by a balloon effect identifier in the presence of photovoltaic power source.

机构信息

Department of Electrical Engineering, Faculty of Energy Engineering, Aswan University, Aswan, Egypt.

Electrical Engineering Department, Faculty of Engineering, Jazan University, Jazan, Saudi Arabia.

出版信息

PLoS One. 2023 Oct 20;18(10):e0293246. doi: 10.1371/journal.pone.0293246. eCollection 2023.

DOI:10.1371/journal.pone.0293246
PMID:37862365
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10588904/
Abstract

Due to the unpredictability of the majority of green energy sources (GESs), particularly in microgrids (μGs), frequency deviations are unavoidable. These factors include solar irradiance, wind disturbances, and parametric uncertainty, all of which have a substantial impact on the system's frequency. An adaptive load frequency control (LFC) method for power systems is suggested in this paper to mitigate the aforementioned issues. For engineering challenges, soft computing methods like the bat algorithm (BA), where it proves its effectiveness in different applications, consistently produce positive outcomes, so it is used to address the LFC issue. For online gain tuning, an integral controller using an artificial BA is utilized, and this control method is supported by a modification known as the balloon effect (BE) identifier. Stability and robustness of analysis of the suggested BA+BE scheme is investigated. The system with the proposed adaptive frequency controller is evaluated in the case of step/random load demand. In addition, high penetrations of photovoltaic (PV) sources are considered. The standard integral controller and Jaya+BE, two more optimization techniques, have been compared with the suggested BA+BE strategy. According to the results of the MATLAB simulation, the suggested technique (BA+BE) has a significant advantage over other techniques in terms of maintaining frequency stability in the presence of step/random disturbances and PV source. The suggested method successfully keeps the frequency steady over I and Jaya+BE by 61.5% and 31.25%, respectively. In order to validate the MATLAB simulation results, real-time simulation tests are given utilizing a PC and a QUARC pid_e data acquisition card.

摘要

由于大多数绿色能源 (GES) 的不可预测性,特别是在微电网 (μGs) 中,频率偏差是不可避免的。这些因素包括太阳辐照度、风干扰和参数不确定性,所有这些都对系统频率有重大影响。本文提出了一种适用于电力系统的自适应负荷频率控制 (LFC) 方法,以解决上述问题。对于工程挑战,像蝙蝠算法 (BA) 这样的软计算方法,在不同的应用中都证明了其有效性,始终产生积极的结果,因此被用于解决 LFC 问题。对于在线增益调整,使用人工 BA 的积分控制器被采用,并且这种控制方法得到了称为气球效应 (BE) 标识符的修改的支持。对所提出的 BA+BE 方案的稳定性和鲁棒性进行了分析。在所提出的自适应频率控制器的系统中,评估了在阶跃/随机负载需求的情况下。此外,还考虑了高渗透率的光伏 (PV) 源。与所提出的 BA+BE 策略相比,标准积分控制器和 Jaya+BE 这两种更优化的技术已经进行了比较。根据 MATLAB 仿真的结果,所提出的技术 (BA+BE) 在存在阶跃/随机干扰和 PV 源的情况下,在保持频率稳定性方面具有显著优势。所提出的方法成功地使频率保持稳定,相对于 I 和 Jaya+BE,分别稳定了 61.5%和 31.25%。为了验证 MATLAB 仿真结果,利用 PC 和 QUARC pid_e 数据采集卡进行了实时仿真测试。

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