Abstract :
In this paper, we report precision viscosity measurements using suspended microchannel resonators (SMRs). Two different methods are developed and applied to glycerol-water binary mixtures having various weight ratios. First, open loop frequency sweep and harmonic oscillator fitting is employed to extract the quality factor (Q-factor) of an SMR. Second, closed loop feedback operation is employed while the vibration amplitude is continuously monitored. Both the Q-factor and vibration amplitude increase with increasing viscosity for the tested SMR and they agree well after rescaling. Viscosity measurements using the Q-factor change are compared with measurements using a bench-top tuning fork viscometer. While the bench-top tuning fork viscometer measures static viscosity thus always requires density correction, the SMR Q-factor measurement provides dynamic viscosity directly. In addition, SMR measurements require sample volume of ~50 μL while the bench-top viscometer requires ~10 mL per each measurement.
Keywords :
Q-factor; closed loop systems; feedback; harmonic oscillators; microchannel flow; micromechanical resonators; mixtures; suspensions; vibrations; viscometers; viscosity measurement; Q-factor measurement; SMR; closed loop feedback; density correction; glycerol water binary mixture; harmonic oscillator fitting; open loop frequency sweep; quality factor; suspended microchannel resonator; vibration amplitude; viscosity measurement; Density measurement; Frequency measurement; Q factor; Resonant frequency; Vibration measurement; Vibrations; Viscosity; Quality factor; Suspended microchannel resonator; Viscosity;
