Design Guideline for a Cantilever-Type MEMS Switch with High Contact Force

Micro Pub Date : 2023-12-20 DOI:10.3390/micro4010001

I. Uvarov, Igor A. Belozerov

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Abstract

Micromechanical switches are of significant interest for advanced radio frequency and microwave systems, but their practical implementation is limited by low reliability. Electrodes of a microscopic size develop weak contact force that leads to high and unstable contact resistance. The force is typically increased by using a sophisticated switch design with extended lateral dimensions, although a simple and compact cantilever is more preferable. The paper describes for the first time a comprehensive approach to enhance the force of an electrostatically actuated switch. The strategy is applied to a miniature device based on a 50 µm long cantilever. The contact force is increased from 10 to 112 µN, making the switch strong enough to achieve low and stable contact resistance. The restoring force is also enhanced in order to ensure reliable de-actuation. The growth of forces is accompanied by a reduction in the pull-in voltage. Connecting several cantilevers in parallel and manipulating the number and position of contact bumps additionally improves the force and mechanical stability of the switch. An optimal design contains a triple cantilever with two bumps. It provides 50% higher force per contact compared to the single-cantilever switch at the same pull-in voltage and keeps the advantages of a miniature device. The proposed design strategy may be used for building reliable MEMS switches.

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高接触力悬臂式 MEMS 开关设计指南

微机械开关对先进的射频和微波系统具有重大意义，但其实际应用却因可靠性低而受到限制。微小尺寸的电极会产生微弱的接触力，导致接触电阻大且不稳定。尽管简单、紧凑的悬臂更为理想，但通常通过使用具有扩展横向尺寸的复杂开关设计来增加接触力。本文首次介绍了一种增强静电驱动开关力的综合方法。该策略应用于基于 50 µm 长悬臂的微型装置。接触力从 10 微牛顿增加到 112 微牛顿，使开关的强度足以实现低而稳定的接触电阻。还增强了恢复力，以确保可靠的断开。力的增加伴随着拉入电压的降低。将多个悬臂并联，并调整触点凸块的数量和位置，可进一步提高开关的作用力和机械稳定性。最佳设计包括一个带有两个凸块的三悬臂。与单悬臂开关相比，在相同的拉入电压下，它能将每个触点的力提高 50%，并保持了微型装置的优势。所提出的设计策略可用于制造可靠的微机电系统开关。

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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Micro

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