Design and development of maximum power point tracking (MPPT) for 100 watt solar panel base on buck boost converter

Q4 Engineering
Sukarno Budi Utomo, I. Setiawan, B. Fajar, S. H. Winoto
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引用次数: 1

Abstract

Photovoltaic systems produce energy that is not constant and is very dependent on weather conditions. Factors that can affect the output produced by solar panels always experience changes in the amount of sunlight intensity and working temperature of solar panels. To optimize the power of solar cells, Maximum Power Point (MPP) is usually used. This research design presents the implementation of Perturb and Observe algorithms for Maximum Power Point Tracker (MPPT) as a controller for solar power generators. The synchronous buck boost DC-DC converter circuit is used as a lowering voltage controller which is controlled using the P & O algorithm. The maximum power point (MPP) is the point in the VI curve or VP curve on the solar panel at which point the solar panel works in maximum efficiency that can produce the most output power. In designing the Maximum Power Point Tracking (MPPT) algorithm that is used to find and make the working points of solar panels always in the MPPT area, Perturb and Observe are needed to get the right optimization results.Photovoltaic systems produce energy that is not constant and is very dependent on weather conditions. Factors that can affect the output produced by solar panels always experience changes in the amount of sunlight intensity and working temperature of solar panels. To optimize the power of solar cells, Maximum Power Point (MPP) is usually used. This research design presents the implementation of Perturb and Observe algorithms for Maximum Power Point Tracker (MPPT) as a controller for solar power generators. The synchronous buck boost DC-DC converter circuit is used as a lowering voltage controller which is controlled using the P & O algorithm. The maximum power point (MPP) is the point in the VI curve or VP curve on the solar panel at which point the solar panel works in maximum efficiency that can produce the most output power. In designing the Maximum Power Point Tracking (MPPT) algorithm that is used to find and make the working points of solar panels always in the MPPT area, Perturb and Observe are nee...
基于降压升压变换器的100瓦太阳能电池板最大功率点跟踪(MPPT)的设计与开发
光伏系统产生的能量不是恒定的,而且非常依赖于天气条件。影响太阳能电池板输出的因素总是经历太阳能电池板的日照强度和工作温度的变化。为了优化太阳能电池的功率,通常使用最大功率点(Maximum power Point, MPP)。本研究设计提出了最大功率点跟踪器(MPPT)的Perturb和Observe算法的实现,作为太阳能发电机的控制器。采用同步降压升压DC-DC转换电路作为降压控制器,采用P & O算法控制。最大功率点(MPP)是太阳能电池板上的VI曲线或VP曲线上的点,在该点上太阳能电池板的工作效率最高,可以产生最大的输出功率。在设计最大功率点跟踪(MPPT)算法时,为了找到并使太阳能电池板的工作点始终处于最大功率点跟踪区域,需要使用Perturb和Observe来获得正确的优化结果。光伏系统产生的能量不是恒定的,而且非常依赖于天气条件。影响太阳能电池板输出的因素总是经历太阳能电池板的日照强度和工作温度的变化。为了优化太阳能电池的功率,通常使用最大功率点(Maximum power Point, MPP)。本研究设计提出了最大功率点跟踪器(MPPT)的Perturb和Observe算法的实现,作为太阳能发电机的控制器。采用同步降压升压DC-DC转换电路作为降压控制器,采用P & O算法控制。最大功率点(MPP)是太阳能电池板上的VI曲线或VP曲线上的点,在该点上太阳能电池板的工作效率最高,可以产生最大的输出功率。在设计最大功率点跟踪(MPPT)算法时,需要使用Perturb和Observe来查找并使太阳能电池板的工作点始终在最大功率点跟踪区域内。
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
Journal of Electrical and Electronics Engineering
Journal of Electrical and Electronics Engineering Engineering-Electrical and Electronic Engineering
CiteScore
0.90
自引率
0.00%
发文量
0
审稿时长
16 weeks
期刊介绍: Journal of Electrical and Electronics Engineering is a scientific interdisciplinary, application-oriented publication that offer to the researchers and to the PhD students the possibility to disseminate their novel and original scientific and research contributions in the field of electrical and electronics engineering. The articles are reviewed by professionals and the selection of the papers is based only on the quality of their content and following the next criteria: the papers presents the research results of the authors, the papers / the content of the papers have not been submitted or published elsewhere, the paper must be written in English, as well as the fact that the papers should include in the reference list papers already published in recent years in the Journal of Electrical and Electronics Engineering that present similar research results. The topics and instructions for authors of this journal can be found to the appropiate sections.
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