Investigations on advanced soldering mechanisms for transient liquid phase soldering (TLPS) in power electronics

Proceedings of the 5th Electronics System-integration Technology Conference (ESTC) Pub Date : 2014-11-24 DOI:10.1109/ESTC.2014.6962773

A. Syed-Khaja, J. Franke

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引用次数: 14

Abstract

This paper gives an overview of the optimization of the present state-of-the-art soldering technologies for diffusion soldering in power electronics, in particular for Transient liquid phase soldering (TLPS) with enhancements in process conditions to reduce the void percentage in the interconnections and at the same time accelerate the rate of intermetallic phase (IMP) formation. Addressing the difficulties in realizing a void-free TLPS joint in large-area die-attach in power electronics, the variations in soldering process parameters like temperature, pressure and time are discussed. The complete transformation of thin Sn-Cu solder interlayers (15-20μm) into Cu6Sn5 and Cu3Sn IMPs and related void information for varying solder profile variants have been explained. To evaluate the potential for TLPS process, the advanced reflow soldering mechanisms like vacuum vapor-phase soldering and over-pressure convection soldering have been investigated. Depending on the void percentages and IMP formation rate, an optimized interconnection process has been introduced which is capable of realizing TLPS joints with convectional electronic production equipment.

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电力电子瞬态液相焊接(TLPS)先进焊接机制的研究

本文概述了目前最先进的焊接技术的优化，用于电力电子器件的扩散焊接，特别是瞬态液相焊接(TLPS)，通过改进工艺条件来减少互连中的空隙率，同时加快金属间相(IMP)的形成速度。针对电力电子领域大面积贴装中实现无空洞TLPS接头的困难，讨论了焊接工艺参数如温度、压力和时间的变化。解释了薄Sn-Cu钎料中间层(15-20μm)完全转变为Cu6Sn5和Cu3Sn IMPs以及不同钎料形状变化的相关空洞信息。为了评估TLPS工艺的潜力，研究了真空气相焊和超压对流焊等先进的回流焊机制。根据空穴率和IMP形成速率的不同，提出了一种优化的连接工艺，可以实现传统电子生产设备的TLPS接头。

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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Proceedings of the 5th Electronics System-integration Technology Conference (ESTC)

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