部分遮荫条件下光伏综合电学特性的通用模型

IF 13 Q1 ENERGY & FUELS Advances in Applied Energy Pub Date : 2023-02-01 DOI:10.1016/j.adapen.2022.100118
Fuxiang Li , Wentao Dong , Wei Wu
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引用次数: 4

摘要

部分遮阳条件(PSC)导致光伏(PV)系统性能不佳、不可靠和火灾风险。准确估计PV行为对基本理解和进一步缓解至关重要。然而,目前的建模方法缺乏对物理行为、系统复杂性和遮阳模式多样性的充分考虑,分析粗糙、简单。本文提出了一种基于高性能算法的创新建模方法来同时解决这些挑战。在严格分析的基础上,分别在单元级、模块级和阵列级建立了考虑反向偏置行为、系统复杂性和阴影模式多样性的物理模型。然后,通过测量数据进行严格和渐进的验证,以证明所开发方法的有效性。该方法适用于市场上的主流光伏技术,可以很好地预测电池行为和组件电气特性。值得注意的是,在模拟相同的光伏阵列时,该方法的计算效率高于Simulink。最后,为了证明其独特的优势,进行了两个案例研究。局部功耗可以量化。观察到的能量损失证明了反向偏态行为和高分辨率模拟的必要性。该方法可以在任何开发环境中进行编码,为分析光伏系统提供了一种高效而全面的工具。
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A general model for comprehensive electrical characterization of photovoltaics under partial shaded conditions

Partial shading condition (PSC) causes underperformance, unreliability, and fire risks in photovoltaic (PV) systems. Accurate estimation of PV behaviors is crucial to fundamental understanding and further mitigation. However, current modeling methods lack full consideration of the physical behaviors, system complexities, and shading pattern diversities, ending in coarse and simple analysis. Herein, an innovative modeling approach with high-performance algorithms is proposed to address these challenges simultaneously. Based on rigorous analysis, physics models considering the reverse-biased behaviors, the system complexities, and shading pattern diversities, are developed at the cell, module, and array levels, respectively. Then, a strict and progressive validation via measurement data is conducted to justify the effectiveness of the developed method. The method is valid for mainstream PV technologies in the market and can predict cell behaviors and module electrical characteristics perfectly. Notably, the proposed method is more computationally efficient than Simulink when simulating the same PV array. Lastly, to demonstrate its exclusive advantages, two case studies are conducted. The localized power dissipation can be quantified. The observed energy loss justifies the necessity of reverse biased behaviors and high-resolution simulation. This method can be coded in any development environment, providing an efficient and comprehensive tool to analyze PV systems.

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来源期刊
Advances in Applied Energy
Advances in Applied Energy Energy-General Energy
CiteScore
23.90
自引率
0.00%
发文量
36
审稿时长
21 days
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