Defect Analysis and Performance Evaluation of Photovoltaic Modules Using Quantitative Electroluminescence Imaging
Phuong Truong Le, Nguyen LietAbstract
This paper presents a defect analysis and performance evaluation of photovoltaic modules using quantitative electroluminescence imaging. The study analyzed three common PV technologies: thin-film, mono-crystalline silicon, and poly-crystalline silicon. Experimental results indicate that mono-crystalline silicon panels have the lowest degradation rate, ranging from 0.861% to 0.886%, compared to thin-film panels, which range from 1.39% to 1.53%, and poly- crystalline panels, which range from 1.32% to 1.62%. The primary defects in thin-film technology include the formation of small shunts that gradually accumulate, causing shading and obstructing current flow, thereby reducing efficiency. For mono-crystalline and poly-crystalline technologies, defects include oxidation leading to loss of connection, layer wrinkles causing shading, and the accumulation of dust and animal waste. The study also demonstrates the effectiveness of using electroluminescence to identify micro-defects with high accuracy. The comprehensive quantitative electroluminescence method not only assesses defects with high accuracy but also offers practical insights for improving maintenance strategies and performance in tropical climates.