Testing and analysis for lifetime prediction of crystalline silicon PV modules undergoing degradation by system voltage stress

P. Hacke, Ryan M. Smith, K. Terwilliger, S. Glick, D. Jordan, S. Johnston, M. Kempe, S. Kurtz
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引用次数: 58

Abstract

Acceleration factors are calculated for crystalline silicon photovoltaic modules under system voltage stress by comparing the module power during degradation outdoors with that in accelerated testing at three temperatures and 85% relative humidity. A lognormal analysis is applied to the accelerated lifetime test data, considering failure at 80% of the initial module power. Activation energy of 0.73 eV for the rate of failure is determined for the chamber testing at constant relative humidity, and the probability of module failure at an arbitrary temperature is predicted. To obtain statistical data for multiple modules over the course of degradation in situ of the test chamber, dark I–V measurements are obtained and transformed using superposition, which is found to be well suited for rapid and quantitative evaluation of potential-induced degradation. It is determined that shunt resistance measurements alone do not represent the extent of power degradation. This is explained with a two-diode model analysis that shows an increasing second diode recombination current and ideality factor as the degradation in module power progresses. Failure modes of the modules stressed outdoors are examined and compared with those stressed in accelerated tests.
系统电压应力退化的晶体硅光伏组件寿命预测测试与分析
通过对比三种温度和85%相对湿度下的组件在室外退化和加速测试时的功率,计算了系统电压应力下晶体硅光伏组件的加速系数。考虑到在初始模块功率的80%时失效,对加速寿命测试数据应用对数正态分析。在恒定相对湿度条件下,确定了模组失效率的激活能为0.73 eV,并预测了模组在任意温度下的失效概率。为了获得多个模块在测试室原位降解过程中的统计数据,使用叠加法获得暗I-V测量值并进行转换,发现该方法非常适合于对潜在诱导降解进行快速定量评估。可以确定的是,单独的并联电阻测量不能代表功率退化的程度。这是用一个双二极管模型分析来解释的,该分析显示,随着模块功率的下降,第二二极管的复合电流和理想因数也在增加。研究了构件在室外受力时的破坏模式,并与加速试验时的破坏模式进行了比较。
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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