Thermo-mechanical challenges of advanced solar cell modules

2011 12th Intl. Conf. on Thermal, Mechanical & Multi-Physics Simulation and Experiments in Microelectronics and Microsystems Pub Date : 2011-04-18 DOI:10.1109/ESIME.2011.5765822

Mario Gonzalez, J. Govaerts, R. Labie, I. De Wolf, K. Baert

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引用次数: 12

Abstract

This paper firstly summarizes the process flow developed at IMEC to integrate and interconnect thin back-contact solar cells into modules. Secondly, the process flow is simulated by Finite Element Modelling to determine critical process steps that may lead to early failures. A virtual Design of Experiment (DOE) is used to determine the best geometry and materials properties in order to minimise the induced stresses in the cells and the interconnections. The variables of this DOE are the silicon, the glue and the encapsulant thickness and the Elastic Modulus of the glue and encapsulant. The results of this DOE are presented in forms of Response Surface Models and it is observed that Young's Modulus of encapsulant and the thickness of the solar cells are the mayor contributors to the stresses in the silicon cells. Furthermore, an analysis of the changes in distance between adjacent cells at different temperatures indicates that the stiffness of the encapsulant material will play an important role on the mechanical behavior of the metallic solar cells interconnections.

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先进太阳能电池组件的热机械挑战

本文首先总结了IMEC开发的将薄背接触太阳能电池集成和互连成组件的工艺流程。其次，通过有限元建模对工艺流程进行模拟，确定可能导致早期故障的关键工艺步骤。虚拟实验设计(DOE)用于确定最佳几何形状和材料性能，以最小化单元和互连中的诱导应力。该DOE的变量是硅、胶和封装剂的厚度以及胶和封装剂的弹性模量。该DOE的结果以响应面模型的形式呈现，并观察到封装剂的杨氏模量和太阳能电池的厚度是硅电池中应力的主要贡献者。此外，对不同温度下相邻电池间距离变化的分析表明，封装材料的刚度将对金属太阳能电池互连的力学行为起重要作用。

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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2011 12th Intl. Conf. on Thermal, Mechanical & Multi-Physics Simulation and Experiments in Microelectronics and Microsystems

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