湿度和温度对常压和气体稀释微束谐振器品质因数的影响

Nguyen Chi Cuong, T. X. Thang, Lam Minh Thinh, Vuong Dinh Duy Phuc, Phan Minh Duc Truong, Truong Huu Ly, Ngo Vo Ke Thanh, Le Quoc Cuong
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引用次数: 0

摘要

在大气压力(p=101325 Pa)下,湿度和温度对潮湿空气的影响在讨论微悬臂和微桥谐振器的品质因数时变得非常重要。挤压膜阻尼(SFD)问题是微梁谐振器的主要阻尼源,在特征值问题中使用改进的分子气体润滑(MMGL)方程和有限元建模(FEM)对其进行建模。MMGL 公式根据潮湿空气的有效粘度 (μeff) 进行了修改,以考虑湿度和温度的影响。还计算了其他阻尼源,如热弹性阻尼 (TED) 和微梁谐振器的支撑损耗。然后讨论了微梁谐振器在大气压力和气体稀释条件下的各种温度和相对湿度水平下的品质因数。结果表明,在大气压力和气体稀释条件下,微悬臂和微桥谐振器的品质因数会随着湿度和温度的升高而增加。此外,在大气压力和气体稀释条件下,微桥谐振器的品质因数随湿度和温度的变化明显高于微悬臂谐振器。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effects of humidity and temperature on quality factor of micro-beam resonators in atmospheric pressure and gas rarefaction
At atmospheric pressure (p=101325 Pa), the effects of humidity and temperature on moist air become important when discussing the quality factor of micro-cantilever and micro-bridge resonators. The squeeze film damping (SFD) problem, the dominant damping source for micro-beam resonators, is modelled using the modified molecular gas lubrication (MMGL) equation with finite element modelling (FEM) in the eigenvalue problem. The MMGL equation is modified with the effective viscosity of moist air (μeff) to account for the effects of humidity and temperature. Other damping sources, such as thermoelastic damping (TED) and the support loss of micro-beam resonators, are also calculated. The quality factor of micro-beam resonators is then discussed over a wide range of temperatures and relative humidity levels at atmospheric pressure and gas rarefaction. The results show that the quality factor of micro-cantilever and micro-bridge resonators increases as both humidity and temperature rise in atmospheric pressure and gas rarefaction. Furthermore, the quality factor of a micro-bridge resonator with changes in humidity and temperature is significantly higher than that of a micro-cantilever resonator in atmospheric pressure and gas rarefaction.
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