Analysis of twelve-month degradation in three polycrystalline photovoltaic modules

Optics + Photonics for Sustainable Energy Pub Date : 2016-09-26 DOI:10.1117/12.2237527

T. Lai, B. G. Potter, K. Simmons-Potter

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引用次数: 5

Abstract

Polycrystalline silicon photovoltaic (PV) modules have the advantage of lower manufacturing cost as compared to their monocrystalline counterparts, but generally exhibit both lower initial module efficiencies and more significant early-stage efficiency degradation than do similar monocrystalline PV modules. For both technologies, noticeable deterioration in power conversion efficiency typically occurs over the first two years of usage. Estimating PV lifetime by examining the performance degradation behavior under given environmental conditions is, therefore, one of continual goals for experimental research and economic analysis. In the present work, accelerated lifecycle testing (ALT) on three polycrystalline PV technologies was performed in a full-scale, industrial-standard environmental chamber equipped with single-sun irradiance capability, providing an illumination uniformity of 98% over a 2 x 1.6m area. In order to investigate environmental aging effects, timedependent PV performance (I-V characteristic) was evaluated over a recurring, compressed day-night cycle, which simulated local daily solar insolation for the southwestern United States, followed by dark (night) periods. During a total test time of just under 4 months that corresponded to a year equivalent exposure on a fielded module, the temperature and humidity varied in ranges from 3°C to 40°C and 5% to 85% based on annual weather profiles for Tucson, AZ. Removing the temperature de-rating effect that was clearly seen in the data enabled the computation of normalized efficiency degradation with time and environmental exposure. Results confirm the impact of environmental conditions on the module long-term performance. Overall, more than 2% efficiency degradation in the first year of usage was observed for all thee polycrystalline Si solar modules. The average 5-year degradation of each PV technology was estimated based on their determined degradation rates.

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三种多晶光伏组件12个月退化分析

与单晶光伏组件相比，多晶硅光伏组件具有制造成本较低的优势，但与单晶光伏组件相比，多晶硅光伏组件通常表现出较低的初始组件效率和更显著的早期效率退化。对于这两种技术，功率转换效率的显著下降通常发生在使用的头两年。因此，通过检查给定环境条件下的性能退化行为来估计光伏寿命是实验研究和经济分析的持续目标之一。在目前的工作中，三种多晶光伏技术的加速生命周期测试(ALT)在一个配备单太阳辐照能力的全尺寸工业标准环境室中进行，在2 x 1.6m的区域内提供98%的照明均匀性。为了研究环境老化的影响，在一个重复的、压缩的昼夜周期中，对PV的时间依赖性性能(I-V特性)进行了评估，模拟了美国西南部的当地日日照，然后是黑暗(夜晚)时期。在不到4个月的总测试时间内，相当于一个现场模块一年的等效暴露时间，根据亚利桑那州图森的年度天气资料，温度和湿度的变化范围为3°C至40°C, 5%至85%。消除了数据中明显可见的温度退化效应，可以计算出随时间和环境暴露的标准化效率退化。结果证实了环境条件对模块长期性能的影响。总体而言，在使用的第一年，观察到所有三种多晶硅太阳能组件的效率下降超过2%。每种光伏技术的平均5年退化率是基于它们确定的退化率来估计的。

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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Optics + Photonics for Sustainable Energy

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