Towards Validation of Advanced Accelerated Stress Testing Protocols through Failure Analysis and Materials Characterization

2020 47th IEEE Photovoltaic Specialists Conference (PVSC) Pub Date : 2020-06-14 DOI:10.1109/pvsc45281.2020.9301012

L. Schelhas, Michael Owen‐Bellini, S. Moffitt, Ashley M. Maes, James Y. Hartley, Todd Karin, Donald R. Jenket, Archana Sinha, J. Tracy, David C. Miller, P. Hacke

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引用次数: 1

Abstract

As the lifetime of photovoltaic modules increases toward the goal of 50 years, accelerated stress testing is critical to assessing the viability of newer, improved, and often cheaper materials in the field. However, the validation of accelerated testing to reproduce field failure has remained elusive. The recent developments of more advanced stress testing protocols utilizing sequential and combined stressors have provided another opportunity for validation. Using a suite of mechanical, chemical, and structural characterization methods we report the development of our approach using a known bad backsheet “AAA.” We then apply this approach to PVDF-based backsheets to further confirm the generalizability of this approach. The outcome of this work is two-fold: (1) validation of advanced accelerated testing protocols which will enable the prediction of field failures in new materials, and (2) deeper insights into the degradation mechanisms observed through the extensive characterization allowing for improved materials engineering and development.

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通过失效分析和材料表征来验证先进的加速应力测试方案

随着光伏组件的寿命向50年的目标增长，加速压力测试对于评估该领域更新，改进和通常更便宜的材料的可行性至关重要。然而，加速测试重现现场故障的有效性仍然难以捉摸。最近更先进的压力测试协议的发展利用顺序和组合压力源提供了另一个验证的机会。使用一套机械、化学和结构表征方法，我们报告了使用已知坏背板“AAA”的方法的发展。然后，我们将该方法应用于基于pvdf的背板，以进一步确认该方法的通用性。这项工作的结果是双重的:(1)验证先进的加速测试协议，这将使新材料的现场故障预测成为可能;(2)通过广泛的表征来深入了解降解机制，从而改进材料工程和开发。

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2020 47th IEEE Photovoltaic Specialists Conference (PVSC)

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