Fatigue Behaviour of Lead-Free Solder Joints Under Combined Thermal and Vibration Loads

2019 IEEE 69th Electronic Components and Technology Conference (ECTC) Pub Date : 2019-05-01 DOI:10.1109/ECTC.2019.00082

Meier Karsten, Winkler Maria, L. David, D. Abhijit, Bock Karlheinz

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引用次数: 5

Abstract

The increasing demand for highly reliable electronic devices, even though they are exposed to harsh use conditions, is one of the main drivers for the development of electronic systems. System development process relies on the selection of materials, technologies and a proper design to meet the mission profile's demands. Among many others, the lead-free solder alloy SnAg1.0Cu0.5 (SAC105) is widely used for many electronic assemblies deployed for various applications. The fatigue behaviour of SAC105 under thermal loads (namely temperature cycling and shock testing) and drop testing has been covered extensively in the literature. Work on damage accumulation under vibration conditions has been accomplished but primarily at room temperature. Therefore, this work aims to expand knowledge of the fatigue behaviour of SAC105 under combined thermal and vibration loading. In this work, vibration durability experiments were conducted at temperatures from -40°C to +125°C and vibration peak-to-peak amplitudes from 0.6 mm to 1.6 mm. Currently, specimens have been subjected to tests with durations of 75x10E6 or 150x10E6 vibration cycles. Cross sections were analysed to relate damage locations and severity to stress conditions (temperature and vibration amplitude). As expected, damage levels were observed to increase with increasing temperatures and vibration amplitudes.

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热和振动复合载荷下无铅焊点的疲劳行为

对高可靠性电子设备的需求日益增长，即使它们暴露在恶劣的使用条件下，也是电子系统发展的主要驱动力之一。系统开发过程依赖于材料、技术的选择和适当的设计，以满足任务剖面的需求。其中，无铅焊料合金SnAg1.0Cu0.5 (SAC105)广泛用于各种应用的许多电子组件。SAC105在热载荷(即温度循环和冲击试验)和跌落试验下的疲劳行为已经在文献中得到了广泛的报道。已经完成了振动条件下损伤积累的研究，但主要是在室温下完成的。因此，这项工作旨在扩大SAC105在热和振动复合载荷下的疲劳行为的知识。在这项工作中，振动耐久性实验在-40°C至+125°C的温度下进行，振动峰对峰振幅为0.6 mm至1.6 mm。目前，试件已经接受了75 × 10e6或150 × 10e6振动周期持续时间的测试。对截面进行分析，将损伤位置和严重程度与应力条件(温度和振动幅度)联系起来。正如预期的那样，随着温度和振动幅度的增加，损伤程度也会增加。

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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来源期刊

2019 IEEE 69th Electronic Components and Technology Conference (ECTC)

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