Integrated Pressure Sensing Using Capacitive Coriolis Mass Flow Sensors
Dennis AlveringhRemco J. WiegerinkJoost Conrad Lötters
Abstract
The cross-sectional shape of microchannels is, dependent on the fabrication method, never perfectly circular. Consequently, the channels deform with the pressure, which is a non-ideal effect in flow sensors, but may be used for pressure sensing. Multiple suspended channels with different lengths were modeled, fabricated, and characterized to verify the use and the scalability of this effect for pressure sensing. Furthermore, it is shown that the pressure dependence can be distinguished from the Coriolis effect in microfabricated Coriolis mass flow sensors, enabling the measurement of the pressure next to flow and density with only the flow sensor itself. In addition, this allows for further improvement in the accuracy of the flow measurement by correcting for the small pressure dependence.
Metrics
Citation History
Topics
Related Documents
Resistive pressure sensors integrated with a coriolis mass flow sensor
Dennis AlveringhThomas SchutRemco J. WiegerinkWouter SparreboomJoost Conrad Lötters
Micro Coriolis Mass Flow Sensor with Integrated Capacitive Readout
Jeroen HaneveldT.S.J. LammerinkMeint J. de BoerRemco J. Wiegerink
Improved capacitive detection method for Coriolis mass flow sensors enabling range/sensitivity tuning
Dennis AlveringhJarno GroenesteijnRemco J. WiegerinkJoost Conrad Lötters
An integrated optical method to readout µ-Coriolis mass flow sensors
Anneirudh SundarararjanRemco J. WiegerinkRemco G.P. SandersQihui YuJoost Conrad Lötters
A Novel Capacitive Detection Principle for Coriolis Mass Flow Sensors Enabling Range/Sensitivity Tuning
Dennis AlveringhJarno GroenesteijnKechun MaRemco J. WiegerinkJoost Conrad Lötters