一种微谐振加速度传感器，包括硅支架与温度隔离器和石英双端音叉

The 9th IEEE International Conference on Nano/Micro Engineered and Molecular Systems (NEMS) Pub Date : 2014-04-13 DOI:10.1109/NEMS.2014.6908823

Cun Li, Yulong Zhao, Rongjun Cheng

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引用次数: 3

摘要

提出了一种基于石英双端音叉频移的微谐振加速度传感器。DETF的两个刚性端分别安装在硅支架的防质量和温度隔离结构上。在谐振梁的四个表面涂覆电极，激发反相位振动模型以平衡内部应力和扭矩。当证明质量作用于加速度时，DETF梁中的应力会发生位移，从而改变DETF的共振频率。为了减小石英与硅的热膨胀系数差异对热应力的影响，设计了隔温器结构。基于本体微加工技术制备了硅支架和DETF。还设计了自激电路来激发DETF。所提出的传感器被简单地封装用于测量。该传感器利用石英和硅材料的优势，实现了一个简单处理的微型谐振传感器，用于数字加速度测量。

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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A micro resonant acceleration sensor comprising silicon support with temperature isolator and quartz doubled ended tuning fork

We present a micro resonant acceleration sensor based on the frequency shift of quartz double ended tuning fork (DETF). The two stiff ends of DETF are mounted on proof mass and temperature isolator structure of silicon support, respectively. Electrodes are coated on the four surfaces of the resonant beam to excite anti-phase vibration model to balance inner stress and torque. Stress in DETF beam shifts when the proof mass is applied to acceleration, which changes resonance frequency of DETF. The temperature isolator structure is designed to reduce the impact of thermal stress due to the difference of thermal expansion coefficient between quartz and silicon. The silicon support and DETF are fabricated based on the bulk micromachining technology. Self-excited circuit is also designed to excite DETF. The proposed sensor is simply packaged for measurement. The sensor takes advantages of both quartz and silicon materials to achieve a micro resonant sensor with simple processing for digital acceleration measurements.

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The 9th IEEE International Conference on Nano/Micro Engineered and Molecular Systems (NEMS)

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