Interfacial Characterization of Positive Bias Voltage Degradation in PV Modules

2020 47th IEEE Photovoltaic Specialists Conference (PVSC) Pub Date : 2020-06-14 DOI:10.1109/PVSC45281.2020.9300934

Archana Sinha, S. Moffitt, K. Hurst, Jiadong Qian, David C. Miller, P. Hacke, L. Schelhas

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引用次数: 1

Abstract

Degradation from high system voltage is a prevailing failure mode in fielded photovoltaic modules, and the degradation mechanism is inherently dependent on the bias polarity. Here we report the effects of positive bias. Modules under positive bias demonstrated a significant photocurrent loss caused by two routes. First, delamination and discoloration of the silicon nitride layer, leading to optical loss determined by reflectance measurements. Second, chemical discoloration of the cell gridlines and encapsulant (EVA), which is linked to an electrochemical reaction at the silver electrodes. Chemical compositional analysis using X-ray photoemission spectroscopy demonstrated that the discoloration is attributed to Ag2S and/or Ag2O. Evidence of Ag ion migration from the cell grid into the encapsulant is observed after shallow depth profiling on the EVA surface. However, Ag was not detected at the EVA/glass interface, inferring limited Ag ion transport through the EVA. The source of sulfur is believed to be ambient air, which diffused into the module through the breathable backsheet.

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光伏组件中正偏置电压退化的界面表征

高系统电压导致的退化是光伏组件的主要失效模式，其退化机制本质上依赖于偏置极性。在这里，我们报告了正偏倚的影响。在正偏置下的模块显示出由两条路径引起的显著光电流损耗。首先，氮化硅层的分层和变色，导致通过反射率测量确定的光学损耗。其次，电池网格线和封装剂(EVA)的化学变色，这与银电极上的电化学反应有关。x射线光发射光谱分析表明，变色是由Ag2S和/或Ag2O引起的。在EVA表面的浅深度剖面上观察到Ag离子从细胞网格迁移到封装剂的证据。然而，在EVA/玻璃界面未检测到Ag，推断通过EVA的Ag离子传输有限。硫的来源被认为是周围的空气，它通过可呼吸的背板扩散到模块中。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 47th IEEE Photovoltaic Specialists Conference (PVSC)

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