Testing and multi-scale modeling of drop and impact loading of complex MEMS microphone assemblies

2012 13th International Thermal, Mechanical and Multi-Physics Simulation and Experiments in Microelectronics and Microsystems Pub Date : 2012-04-16 DOI:10.1109/ESIME.2012.6191726

J. Meng, T. Mattila, A. Dasgupta, M. Sillanpaa, R. Jaakkola, K. Andersson, E. Hussa

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引用次数: 14

Abstract

Failure under dynamic mechanical stresses caused by impact and drop loading is a critical concern for reliability of surface mount components in portable electronic products. This study focuses on drop-induced failures in system-in-package (SIP) COTS Micro-Electro-Mechanical Systems (MEMS) components that are mounted on PWAs. In particular, we are interested in the effects of secondary impacts that can occur between the PWB and neighboring structures (such as the product case, battery packs, displays or other adjacent PWBs) in portable electronic products. Drop tests are conducted under highly accelerated drop conditions with ultra-high accelerations (10,000-30,000 Gs) that generate stress levels well beyond those expected in actual use, or in conventional qualification tests. Furthermore, secondary impacts are allowed between the test specimen and the fixture, resulting in additional amplifications of stress and accelerations. Due to the geometric complexity, a hierarchical, multi-scale global-local modeling approach is used to assess the stress levels at critical failure sites in the MEMS. The modeling is based on 3D transient Finite element analysis (FEA).

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复杂MEMS麦克风组件跌落和冲击载荷的测试和多尺度建模

冲击和跌落载荷引起的动态机械应力失效是影响便携式电子产品表面贴装元件可靠性的关键问题。本研究的重点是安装在pwa上的系统级封装(SIP) COTS微机电系统(MEMS)组件的跌落故障。特别是，我们对便携式电子产品中PWB和相邻结构(如产品外壳，电池组，显示器或其他相邻PWB)之间可能发生的二次冲击的影响感兴趣。在超高加速度(10,000-30,000 g)的高加速跌落条件下进行跌落测试，产生的应力水平远远超出实际使用或常规鉴定测试的预期。此外，在试样和夹具之间允许二次冲击，导致应力和加速度的额外放大。由于几何复杂性，采用分层、多尺度全局-局部建模方法来评估MEMS关键失效部位的应力水平。该模型基于三维瞬态有限元分析(FEA)。

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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2012 13th International Thermal, Mechanical and Multi-Physics Simulation and Experiments in Microelectronics and Microsystems

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