Mechanical and thermal simulations of a microactuator for the Stimulation of the Perilymph

2010 11th International Thermal, Mechanical & Multi-Physics Simulation, and Experiments in Microelectronics and Microsystems (EuroSimE) Pub Date : 2010-04-26 DOI:10.1109/ESIME.2010.5464582

T. Creutzburg, H. Gatzen

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引用次数: 2

Abstract

The design of a microactuator serving as an implantable hearing aid to overcome ambylacousia was conducted by executing mechanical and thermal Finite Element Method (FEM) analyses using the ANSYS® software simulation tool. To do so, the deflection conditions to be fulfilled by the system were determined. The two challenges were to achieve a sufficiently high resonance frequency and to accommodate the physiological restrictions in the middle ear and the cochlea defining the maximal size of the microactuator. A model of the mechanical system was created and modal analyses were carried out. In the next step, the force required to deflect the membrane in the static case and under damping of the cochlea was simulated. In a last step, a 3-D thermal model of the complete system including the micromagnetics was created to investigate the temperature rise in the system. This is important with respect to the implantation of the actuator into the human body, avoiding a necrosis of the human tissue.

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微致动器对近地轨道刺激的力学和热模拟

利用ANSYS®软件仿真工具进行机械和热有限元分析，设计了一种用于克服耳聋的植入式助听器微致动器。为此，确定了系统要满足的挠度条件。两个挑战是实现足够高的共振频率，并适应中耳和耳蜗的生理限制，定义了微执行器的最大尺寸。建立了机械系统模型，并进行了模态分析。在接下来的步骤中，模拟了在静态情况下和耳蜗阻尼下使膜偏转所需的力。在最后一步，建立了包括微磁在内的完整系统的三维热模型，以研究系统中的温升。这对于将驱动器植入人体，避免人体组织坏死是很重要的。

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

2010 11th International Thermal, Mechanical & Multi-Physics Simulation, and Experiments in Microelectronics and Microsystems (EuroSimE)

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