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access icon free Modelling and calibration of microthermal sensor for underwater wall shear stress measurement

© The Institution of Engineering and Technology
Received 15/01/2014, Accepted 20/06/2014, Revised 16/04/2014, Published 24/07/2014

To measure underwater wall shear stress, a calibration method for a microthermal sensor is studied. In CC (constant current) mode, a mathematical model which quantitatively describes the relationship between the output of the thermal sensor and the wall shear stress is presented. A well-characterised water tunnel was set up to provide a series of known wall shear stresses in the range of 0–5 Pa. Calibration results prove the proposed model and characterise the thermal sensor precisely. The consistency of the parameters indicates that the performance of the thermal sensor keeps stable in water while driven by electricity. The R-squares in all calibrations exceed 0.995. The deviations between the predicted and the generated wall shear stress are about 5%.

Inspec keywords: calibration; microsensors; stress measurement

Other keywords: constant current mode; pressure 0 Pa to 5 Pa; well-characterised water tunnel; R-squares; microthermal sensor calibration method; microthermal sensor modelling; mathematical model; underwater wall shear stress measurement

Subjects: Microsensors and nanosensors; Mechanical variables measurement; Micromechanical and nanomechanical devices and systems; Measurement of mechanical variables

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