生物医学植入物静电能量采集器的设计与仿真

2021 Symposium on Design, Test, Integration & Packaging of MEMS and MOEMS (DTIP) Pub Date : 2021-08-25 DOI:10.1109/dtip54218.2021.9568675

F. Ambía, Jhordan Chavez, M. Lallart, X. Leroux, É. Lefeuvre

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引用次数: 2

摘要

介绍了一种用于医用植入物的静电MEMS能量采集器的设计。研究了约束可移动部件在一个方向上运动的解决方案，并提出了一种创新的弹簧结构。事实上，限制可移动部件的运动是必不可少的，以避免梳状电极之间的不必要的接触。在由旋转和平移的复杂组合引起机械振动的环境中，这一点尤为重要。该装置的目标是利用心跳运动产生的机械能为下一代无铅起搏器供电。这种解决方案将大大增加植入物的使用寿命，并减少患者的更换手术次数，对患者非常有益。基于解析建模和模拟心跳运动的加速度信号的数值模拟能够分析系统在各种条件下的响应，显示了所提出方法的兴趣和优势。

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Design and Simulation of an Electrostatic Energy Harvester for Biomedical Implants

This paper presents the design of an electrostatic MEMS energy harvester for medical implant application. It examines solutions for constraining the motion of the mobile part in one direction and proposes an innovative spring architecture. Indeed, constraining the mobile part motion is essential to avoid undesired contact between comb electrodes. It is particularly important in environments in which mechanical vibrations result from complex combination of rotations and translations. The objective of the considered device is to power the next generation of leadless pacemakers using mechanical energy generated by heartbeat motion. Such solution would dramatically increase the lifetime of implants and would be very beneficial for the patients by reducing the number of replacement surgical operations. Numerical simulations based on analytical modelling and acceleration signal mimicking heartbeat motion enabled to analyze the system response in various condition, showing the interest and benefits of the proposed approach.

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2021 Symposium on Design, Test, Integration & Packaging of MEMS and MOEMS (DTIP)

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