Thermal processes driving laser-welding for module interconnection

2015 IEEE 42nd Photovoltaic Specialist Conference (PVSC) Pub Date : 2015-06-14 DOI:10.1109/PVSC.2015.7356432

H. Schulte‐Huxel, S. Kajari-Schroder, R. Brendel

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Abstract

Laser welding of thin Al layers offers a silver-free and highly flexible option for the interconnection of Al metallized solar cells. Welding requires the melting of the Al layers in order to form a reliable electrical contact. Here, we investigate the process driving the melt front of the Al towards the interface between the two Al layer. In experiments we observe two different mechanisms depending on the thickness of the irradiated layer. In the case of Al layers thinner than 5 μm a melt-through of the Al-layer is observed, whereas for thicker layers thermal expansion causes a breakage of the surface and ejection of molten Al, which enables the contact formation. Using simulations based on finite element method we instigate the mechanisms leading to the different behavior. The simulations match the experimental results with the experimental measurement uncertainty. In case of thin layers, the simulation show that the process is limited by thermal diffusion. For thicker Al layers the onset of melting on the front side initiates the breakage of the surface and the ejection of the aluminum.

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驱动模块互连激光焊接的热过程

薄铝层的激光焊接为铝金属化太阳能电池的互连提供了一种无银和高度灵活的选择。焊接需要熔化铝层，以形成可靠的电接触。在这里，我们研究了驱动铝的熔体前沿向两个铝层之间的界面移动的过程。在实验中，我们观察到两种不同的机制取决于辐照层的厚度。对于厚度小于5 μm的铝层，可以观察到铝层的熔透现象，而对于厚度较厚的铝层，热膨胀会导致表面断裂和熔融铝的喷射，从而形成接触。采用基于有限元的仿真方法，研究了导致不同行为的机理。模拟结果与实验测量不确定度吻合。在薄层情况下，模拟结果表明该过程受到热扩散的限制。对于较厚的铝层，正面熔化的开始引起表面的破裂和铝的喷出。

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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2015 IEEE 42nd Photovoltaic Specialist Conference (PVSC)

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