Failure of MEMS Microphones During Impact Tests: the Role of Anchor Imposed Motion

2021 22nd International Conference on Thermal, Mechanical and Multi-Physics Simulation and Experiments in Microelectronics and Microsystems (EuroSimE) Pub Date : 2021-04-19 DOI:10.1109/EuroSimE52062.2021.9410884

A. Ghisi, D. Faraci, S. Adorno, A. Corigliano

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引用次数: 1

Abstract

The causes of possible failures of MEMS microphones during guided free fall tests are investigated through top-down, multiscale finite element numerical simulations. Focusing at the micro-scale, the role of the travelling stress waves in the solid, transferred as relative displacement imposed motion histories at the microphone anchors, is clarified. The system including the thin silicon membrane (i.e. the microphone), a holed backplate and the substrate is modelled and studied by including the (different) motions at every support combined with the air over-pressure on the membrane, as captured by fluid dynamics analyses at the higher scale. We show that several failure mechanisms can alternatively occur, involving the membrane or (more likely) the backplate, depending on the phase balance between the two loading history signals. The numerical results help to get insight into the experimental behaviour during guided free fall tests, which instead would appear random and evidence only a rupture/not rupture output.

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MEMS麦克风在冲击试验中的失效:锚施加运动的作用

通过自顶向下的多尺度有限元数值模拟，研究了引导自由落体试验中MEMS传声器可能失效的原因。聚焦于微观尺度，在固体中行进的应力波的作用，作为相对位移施加的运动历史在麦克风锚，被澄清。该系统包括薄硅膜(即麦克风)、多孔背板和衬底，通过将每个支撑处的(不同)运动与膜上的空气超压结合起来进行建模和研究，如在更高尺度上的流体动力学分析所捕获的那样。我们表明，根据两个加载历史信号之间的相位平衡，几种失效机制可以交替发生，涉及膜或(更有可能)背板。数值结果有助于深入了解引导自由落体试验中的实验行为，而不是随机的，只证明了破裂/不破裂的输出。

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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来源期刊

2021 22nd International Conference on Thermal, Mechanical and Multi-Physics Simulation and Experiments in Microelectronics and Microsystems (EuroSimE)

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