Critical shear rate and torque stability condition for a particle resting on a surface in a fluid flow

Abstract

We advance a quantitative description of the critical shear rate γc needed to dislodge a spherical particle resting on a surface with a model asperity in laminar and turbulent fluid flows. We have built a cone-plane experimental apparatus which enables measurement of γc over a wide range of particle Reynolds number Rep from 10-3 to 1.5 × 103. The condition to dislodge the particle is found to be consistent with the torque balance condition, which yields a lower γc compared with force balance because of the torque component due to drag about the particle center. The data for Rep < 0.5 is in good agreement with analytical calculations of the drag and lift coefficients in the Rep → 0 limit. For higher Rep, where analytical results are unavailable, the hydrodynamic coefficients are found to approach a constant for Rep > 1000. We show that a linear combination of the hydrodynamic coefficients found in the viscous and inertial limits can describe the observed γc as a function of the particle and fluid properties.