光伏退化气候带

Todd Karin, C. B. Jones, Anubhav Jain
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引用次数: 13

摘要

先前的大量研究表明,气候影响光伏(PV)的退化,包括稳定的功率损失和危险的故障。然而,气候压力源的地理分布尚未得到系统的表征。最典型的是,Köppen-Geiger分类方案用于比较不同气候条件下PV的降解。然而,Köppen-Geiger使用温度和降雨来开发与植物学相关的区域,并且缺乏基于与PV降解更相关的气候压力源来区分位置的能力。先前的研究表明,特定的压力源(如高温、温度循环、湿热、风应力和紫外线暴露)会诱发多种PV降解模式,如焊锡键降解、水分侵入腐蚀、风致电池开裂、封装剂变色等。我们引入了一个专门针对光伏的气候带分类系统,即光伏气候带(PVCZ-2019或PVCZ),该系统根据光伏辐射源强度的地理分布来定义气候带。该气候带方案提供了每个气候带所经历的气候压力的定量阈值,可以为未来气候对光伏退化和失效的影响的工作提供基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Photovoltaic Degradation Climate Zones
A large body of previous research indicates that climate affects photovoltaic (PV) degradation both in terms of steady power loss and hazardous failures. However, the geographic distribution of climate stressors has not yet been characterized in a systematic way. Most typically the Köppen-Geiger classification scheme is used for comparing PV degradation across different climates. However, Köppen-Geiger uses temperature and rainfall to develop zones relevant for botany and lacks the ability to distinguish locations based on climate stressors more relevant to PV degradation. Prior work has shown that specific stressors (e.g. high temperature, temperature cycling, damp heat, wind stress and UV exposure) induce multiple PV degradation modes such as solder bond degradation, corrosion by moisture intrusion, wind-induced cell cracking, encapsulant discoloration and others. We introduce a climate zone classification system specific to PV, PhotoVoltaic Climate Zones (PVCZ-2019 or PVCZ) that defines zones based on the geographic distribution in PV stressor intensity. This climate zone scheme provides quantitative thresholds on the climate stress experienced in each zone which can provide a basis for future work on the impact of climate on PV degradation and failure.
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