高温石英晶体微天平热弹性行为的有限元模拟

2023 IEEE 10th International Workshop on Metrology for AeroSpace (MetroAeroSpace) Pub Date : 2023-06-19 DOI:10.1109/MetroAeroSpace57412.2023.10190026

Chiara Martina, B. Saggin, E. Palomba, E. Zampetti, Maria Aurora Mancuso, D. Scaccabarozzi

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引用次数: 0

摘要

这项工作的重点是研究用于太空的高温微天平，探索达到相对较高工作温度(即高达300°C)的可行性。所研究的微天平基于石英晶体传感器，在晶体表面安装了集成加热器，为传感器提供局部加热，从而比使用外部加热器更有效地达到工作温度。建立了晶体组件的有限元模型，并在真空室中进行了热测试，以确定等效热阻，同时验证了晶体组件在高温下加热时的机械阻力。调整后的模型可以评估晶体上的热弹性应力状态，表明所获得的工作条件对石英晶体的机械阻力至关重要。

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Finite element modelling of thermoelastic behavior for high-temperature quartz crystal microbalance

This work focuses on the study of high-temperature microbalances to be used in space, exploring the feasibility of reaching relatively high working temperatures, i.e up to 300°C. The studied microbalance, based on a quartz crystal sensor, is equipped with an integrated heater on the crystal surface that provides localized heating on the sensor, thus achieving the operative temperature more efficiently than by using external heaters. A finite element model of the crystal assembly was developed and tuned by thermal testing in a vacuum chamber aimed to identify equivalent thermal resistance and at the same time, verify the mechanical resistance of the crystal assembly when heated at high temperatures. The tuned model allowed evaluation of the thermo-elastic stress state on the crystal, showing that the achieved operative condition is critical for the quartz crystal mechanical resistance.

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2023 IEEE 10th International Workshop on Metrology for AeroSpace (MetroAeroSpace)

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