5.7 A MEMS Coriolis Mass Flow Sensor with 300 μ g/h/√Hz Resolution and ± 0.8mg/h Zero Stability

2021 IEEE International Solid- State Circuits Conference (ISSCC) Pub Date : 2021-02-13 DOI:10.1109/ISSCC42613.2021.9365946
A. C. Oliveira, J. Groenesteijn, R. Wiegerink, K. Makinwa
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引用次数: 4

Abstract

Precision flow sensors are widely used in the pharmaceutical, food, and semiconductor industries to measure small amounts (<1 gram/hour) of liquids and gases. MEMS thermal flow sensors currently achieve state-of-the-art performance in terms of resolution, size, and power consumption [1, 3]. However, they only measure volumetric flow, and so must be calibrated for use with specific liquids [1] or gases [2, 3]. In contrast, Coriolis flow sensors measure mass flow and thus do not need calibration for specific fluids. Furthermore, their resonance frequency can be used as a measure of fluid density. These features enable significant size, cost, and complexity reductions in low-flow microfluidic systems. Although much progress has been made, miniature [4] and MEMS [5– 7] Coriolis mass flow sensors are still outperformed by their thermal counterparts, especially in terms of resolution and long-term stability.
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5.7具有300 μ g/h/√Hz分辨率和±0.8mg/h零稳定性的MEMS科里奥利质量流量传感器
精密流量传感器广泛用于制药,食品和半导体行业,以测量少量(<1克/小时)的液体和气体。MEMS热流传感器目前在分辨率、尺寸和功耗方面达到了最先进的性能[1,3]。然而,它们只能测量体积流量,因此必须经过校准才能用于特定的液体[1]或气体[2,3]。相比之下,科里奥利流量传感器测量的是质量流量,因此不需要对特定流体进行校准。此外,它们的共振频率可以用作流体密度的度量。这些特点使显著的尺寸,成本和复杂性降低在低流量微流体系统。尽管已经取得了很大的进展,但微型[4]和MEMS[5 - 7]科里奥利质量流量传感器的性能仍然优于热传感器,特别是在分辨率和长期稳定性方面。
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2021 IEEE International Solid- State Circuits Conference (ISSCC)
2021 IEEE International Solid- State Circuits Conference (ISSCC)
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