Defect Detection in c-Si Photovoltaic Modules via Transient Thermography and Deconvolution Optimization

Q1 Engineering

Chinese Journal of Electrical Engineering Pub Date : 2023-12-06 DOI:10.23919/CJEE.2023.000043

Zekai Shen;Hanqi Dai;Hongwei Mei;Yanxin Tu;Liming Wang

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Abstract

Defects may occur in photovoltaic (PV) modules during production and long-term use, thereby threatening the safe operation of PV power stations. Transient thermography is a promising defect detection technology, however, its detection is limited by transverse thermal diffusion. This phenomenon is particularly noteworthy in the panel glasses of PV modules. A dynamic thermography testing method via transient thermography and Wiener filtering deconvolution optimization is proposed. Based on the time-varying characteristics of the point spread function, the selection rules of the first-order difference image for deconvolution are given. Samples with a broken grid and artificial cracks were tested to validate the performance of the optimization method. Compared with the feature images generated by traditional methods, the proposed method significantly improved the visual quality. Quantitative defect size detection can be realized by combining the deconvolution optimization method with adaptive threshold segmentation. For the same batch of PV products, the detection error could be controlled to within 10%.

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通过瞬态热成像和去卷积优化检测晶体硅光伏组件中的缺陷

光伏（PV）组件在生产和长期使用过程中可能会出现缺陷，从而威胁光伏发电站的安全运行。瞬态热成像是一种很有前途的缺陷检测技术，但其检测受到横向热扩散的限制。这种现象在光伏组件的面板玻璃上尤为明显。本文提出了一种通过瞬态热成像和维纳滤波解卷积优化的动态热成像检测方法。根据点扩散函数的时变特性，给出了用于解卷积的一阶差分图像的选择规则。为了验证优化方法的性能，测试了带有破碎网格和人工裂缝的样本。与传统方法生成的特征图像相比，所提出的方法显著提高了视觉质量。通过将去卷积优化方法与自适应阈值分割相结合，可以实现缺陷大小的定量检测。对于同一批光伏产品，检测误差可控制在 10% 以内。

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