基于光致发光成像的光伏电池缺陷检测与性能评估研究

doi:10.3964/j.issn.1000-0593(2025)12-3508-06

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摘要： EL成像和PL成像是常用的光伏行业检测技术。其中EL成像具备较高的空间分辨率，但需外接电源，增加了检测难度；PL成像不需要电接触，通过PL光源照射光伏电池后，在光伏电池上产生光致发光信号，再通过使用高灵敏度相机采集信号，可以非接触方式得到高分辨率的图像信息，用于检测缺陷。为验证PL成像方法是否能应用于光伏电池的缺陷检测及光伏电池的表征，基于一套自研PL成像实验平台建立了相应的实验方法和测试流程，通过调节LED激励光源输入电流的方法得到了光伏电池在不同激发条件下的PL图像，并以IV测量结果得到的开路电压作为参考，用PL图像根据广义普朗克方程计算得到电压差，进而验证PL成像的定量分析能力。研究表明，PL成像能够清楚地显示光伏电池中的划痕及材料导致的缺陷；由PL成像计算得出的电压差与IV测量的电压差具有良好的线性关系；PL成像在没有电接触的情况下即可完整地对整个光伏电池成像且在空间分辨率上可达到与EL成像相当的程度，可采用协同激发的方式检测多类型的缺陷。

关键词：光致发光；电致发光；光伏电池；缺陷检测

Abstract：EL imaging and PL imaging are commonly used detection technologies in the photovoltaic industry. EL imaging has high spatial resolution, but requires an external power supply, which increases the difficulty of detection; PL imaging does not require electrical contact. After illuminating the photovoltaic cell with a PL light source, a photoluminescence signal is generated on the photovoltaic cell. By using a high-sensitivity camera to collect the signal, high-resolution image information can be obtained non-contact for defect detection. To verify whether the PL imaging method can be applied to the defect detection of photovoltaic cells and the characterization of photovoltaic cells, this paper establishes the corresponding experimental methods and test processes based on a set of self-developed PL imaging experimental platform, obtains PL images of photovoltaic cells under different excitation conditions by adjusting the input current of LED excitation light source, and uses the open circuit voltage obtained from IV measurement results as a reference, calculates the voltage difference with PL images according to the generalized Planck equation, and then verifies the quantitative analysis capability of PL imaging. The research shows that PL imaging can clearly show scratches and defects caused by materials in photovoltaic cells; The voltage difference calculated by PL imaging has a good linear relationship with the voltage difference measured by IV; PL imaging can completely image the entire photovoltaic cell without electrical contact, and its spatial resolution can reach the same level as EL imaging. Multiple defect types can be detected using coexcitation.

Key words：Photoluminescence; Electroluminescence; Photovoltaic (PV) cell; Defect detection

收稿日期: 2025-03-13 修订日期: 2025-09-22

中图分类号:

TM914.4

基金资助: 国家自然科学基金联合基金重点支持项目（U2141239），江苏省研究生科研与实践创新计划项目（KYCX23_0432）资助

通讯作者: 钱芸生，孙晓飞 E-mail: yshqian@njust.edu.cn；sunxiaofei18@mails.ucas.edu.cn

作者简介: 潘文文，女，1987年生，南京理工大学电子工程与光电技术学院讲师 e-mail: panwenwen@njust.edu.cn

引用本文:

潘文文，钱芸生，刘雅成，孙晓飞. 基于光致发光成像的光伏电池缺陷检测与性能评估研究[J]. 光谱学与光谱分析, 2025, 45(12): 3508-3513.
PAN Wen-wen, QIAN Yun-sheng, LIU Ya-cheng, SUN Xiao-fei. Research on Photovoltaic Cell Defect Detection and Performance Evaluation Based on Photoluminescence Imaging. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(12): 3508-3513.

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