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用于限制部分阴影现象影响的光伏系统架构的比较与分类

Comparison and classification of photovoltaic system architectures for limiting the impact of the partial shading phenomenon.

作者信息

Assiene Mouodo Luc Vivien, Ali AbdeL-Hamid Mahamat, Olivier Thierry Sosso Mayi, Moteyo Alvine Donfang, Gaston Tamba Jean, Axaopoulos Petros

机构信息

Douala University, Laboratory of modeling Materials and Methods of the National Higher Polytechnic School, BP 2701, Douala, Cameroon.

The National Higher Institute of MAO, INSPEM, BP4377, N'DJAMENA, Chad.

出版信息

Heliyon. 2024 Aug 23;10(17):e36670. doi: 10.1016/j.heliyon.2024.e36670. eCollection 2024 Sep 15.

DOI:10.1016/j.heliyon.2024.e36670
PMID:39263101
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11388733/
Abstract

This article proposes a comparison and classification of PV system architectures with the aim of limiting the impact of the partial shading phenomenon which remains one of the most harmful defects during the production of electrical energy with significant consequences on output power, current and voltage. the methodological approach used consists of analyzing in depth the main most recent architectures developed in the current literature with their advantages and disadvantages; then define five partial shading scenarios for different irradiance levels (1000W/m2; 900W/m2; 700W/m2; 500W/m2; 300W/m2), which will then be immediately applied to five other proposed architectures: SP (serial-parallel), BL (Bridge-Link); HC (Honey Comb); TCT (Total-Cross-Tied); TSPL (Triple Series Parallel Ladder); the values obtained at the output with each of its architectures will be used for an in-depth descriptive analysis with PCA (principal component analysis) in statistics but to carry out a comparative analysis between the architectures. All with a Matlab Simulink 2022.b software environment. The results obtained offer a strong positive correlation for TCP and TSPL architectures with better weight compared to other architectures. All in accordance with the IEEE-519-2022 standard. This work is therefore positioned as a contribution to the optimization of the performance of electrical energy production through the use of PV systems which today represent widely used alternatives in the renewable energy register.

摘要

本文提出了光伏系统架构的比较与分类,目的是限制部分阴影现象的影响,该现象仍是电能生产过程中最有害的缺陷之一,对输出功率、电流和电压有重大影响。所采用的方法包括深入分析当前文献中最新开发的主要架构及其优缺点;然后为不同辐照度水平(1000W/m²;900W/m²;700W/m²;500W/m²;300W/m²)定义五种部分阴影场景,随后将其立即应用于其他五种提议的架构:SP(串并联)、BL(桥接链路)、HC(蜂巢型)、TCT(全交叉连接)、TSPL(三串并联梯形);每种架构在输出端获得的值将用于在统计学中使用主成分分析(PCA)进行深入的描述性分析,以便对各架构进行比较分析。所有分析均在Matlab Simulink 2022.b软件环境中进行。与其他架构相比,所获得的结果表明TCP和TSPL架构具有更强的正相关性和更好的权重。所有这些均符合IEEE - 519 - 2022标准。因此,这项工作旨在通过使用光伏系统来优化电能生产性能,如今光伏系统在可再生能源领域是广泛使用的替代方案。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6e40/11388733/eee6a7d67a8f/gr11.jpg
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Heliyon. 2023 Jul 20;9(8):e18434. doi: 10.1016/j.heliyon.2023.e18434. eCollection 2023 Aug.