Maximum power point tracking techniques using improved incremental conductance and particle swarm optimizer for solar power generation systems

Q2 Engineering Energy Harvesting and Systems Pub Date : 2023-05-10 DOI:10.1515/ehs-2022-0120
Akwasi Amoh Mensah, Xie Wei, Duku Otuo-Acheampong, Tumbiko Mbuzi
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引用次数: 1

Abstract

Abstract The generation of power from solar energy by using Photovoltaic (PV) systems to convert the irradiation of the sun into electricity has been adopted over the past years. However, the PV system’s P–V and I–V characteristics become unstable when solar irradiation and temperature change. In this paper, the incremental conductance (INC) has been improved using signals to measure the current and voltage from the PV systems directly which quickly changes with the environmental conditions, and the conventional particle swarm optimization (PSO) is modified so that under multiple shaded peak PV array curves with fast-changing solar irradiance and temperature, more power is extracted at a faster rate without any tracking failure at high-speed tracking of both individual maximum power point (IMPP) and global maximum power point (GMPP) under varying solar irradiance and temperature at a longer distance to enhance the power generated. The individual and global coefficients are also improved to change with multiple shaded peak PV array curves with fast-changing solar irradiance and temperature. DC-DC converter converts DC power from one circuit to another and DC-AC inverter converts DC power to AC power. Simulation was carried out in MATLAB Simulink with different solar irradiance and temperature whereby the conventional INC and PSO were compared with the proposed INC and PSO. An experiment was carried out for a whole day from 8 am to 5 pm to test the validity of the proposed algorithm and compared it with the conventional INC and PSO by using the solar irradiance and temperature received. From both the simulation and experimental results, the proposed INC and PSO performed better by attaining high power and tracking speed with stable output results than the conventional INC and PSO.
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基于改进增量电导和粒子群优化器的太阳能发电系统最大功率点跟踪技术
摘要利用光伏(PV)系统将太阳的辐照转化为电能,利用太阳能发电已被广泛采用。然而,PV系统的P-V和I-V特性在太阳辐照和温度变化时变得不稳定。本文利用光伏系统的电流和电压随环境条件快速变化的信号,对增量电导(INC)进行了改进,并对传统的粒子群优化(PSO)进行了改进,使得在太阳辐照度和温度快速变化的多阴影峰光伏阵列曲线下,在更远的距离上,在不同太阳辐照度和温度下,对单个最大功率点(IMPP)和全局最大功率点(GMPP)进行高速跟踪,以更快的速度提取更多的功率,而不会出现任何跟踪故障,以增强发电量。个体系数和整体系数也得到了改进,可以随着太阳辐照度和温度的快速变化而随多个阴影峰PV阵列曲线变化。DC-DC变换器将直流电源从一个电路转换到另一个电路,DC-AC逆变器将直流电源转换成交流电源。在不同太阳辐照度和温度条件下,利用MATLAB Simulink进行了仿真,并将传统INC和PSO与所提出的INC和PSO进行了比较。从上午8点到下午5点进行了一整天的实验,测试了所提出算法的有效性,并利用接收到的太阳辐照度和温度与传统的INC和PSO进行了比较。仿真和实验结果表明,与传统的同步控制和粒子群算法相比,该算法具有较高的功率和跟踪速度,输出结果稳定等优点。
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 Harvesting and Systems
Energy Harvesting and Systems Energy-Energy Engineering and Power Technology
CiteScore
2.00
自引率
0.00%
发文量
31
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