Oblique particle–wall collisions in a liquid

G. G. JOSEPH; M. L. HUNT

doi:10.1017/S002211200400919X

Abstract

This paper presents experimental measurements of the approach and rebound of a particle colliding obliquely with a wall in a viscous fluid. Steel and glass particles 12.7 mm in diameter were used. The experiments were performed using a thick Zerodur wall (a glass-like material) with various mixtures of glycerol and water. Normal and tangential coefficients of restitution were defined from the ratios of the respective velocity components at the point of contact just prior to and after impact. These coefficients account for losses due to lubrication effects and inelasticity. A third parameter, a coefficient of sliding friction, provides a measure of the tangential force acting on the particle as it slides during a collision.

Oblique collisions in a fluid are qualitatively similar to oblique collisions in a dry system, with a lowered friction coefficient dependent on surface roughness. For smooth surfaces the friction coefficient is drastically reduced due to lubrication effects. A theoretical model that takes into account the dependence of viscosity on pressure is proposed to explain the observed tangential force acting on a smooth sphere during an oblique collision. The model relies on an inferred uniform temperature increase within the lubrication layer, a consequence of viscous heating during impact. The tangential force felt by the particle is expressed as a friction coefficient dependent on the viscosity within the lubrication layer. The viscosity increases owing to pressure effects and decreases owing to thermal effects. For rough surfaces the friction coefficient is comparable to that measured in dry systems, since the surface asperities may interact with each other through the lubrication layer.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Kantak, Advait A. Galvin, Janine E. Wildemuth, Douglas J. and Davis, Robert H. 2005. Low-velocity collisions of particles with a dry or wet wall. Microgravity - Science and Technology, Vol. 17, Issue. 1, p. 18.

Kantak, Advait A. and Davis, Robert H. 2006. Elastohydrodynamic theory for wet oblique collisions. Powder Technology, Vol. 168, Issue. 1, p. 42.

Yang, F.-L. and Hunt, M. L. 2006. Dynamics of particle-particle collisions in a viscous liquid. Physics of Fluids, Vol. 18, Issue. 12,

Locat, Jacques and Turmel, D. 2007. Submarine Mass Movements and Their Consequences. p. 139.

Marshall, J.S. 2007. Particle aggregation and capture by walls in a particulate aerosol channel flow. Journal of Aerosol Science, Vol. 38, Issue. 3, p. 333.

Seiden, G. Ungarish, M. and Lipson, S. G. 2007. Formation and stability of band patterns in a rotating suspension-filled cylinder. Physical Review E, Vol. 76, Issue. 2,

Eames, Ian Yang, Fu-Ling and Hunt, Melany L 2008. A mixed contact model for an immersed collision between two solid surfaces. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 366, Issue. 1873, p. 2205.

Lamb, Michael P. Dietrich, William E. and Sklar, Leonard S. 2008. A model for fluvial bedrock incision by impacting suspended and bed load sediment. Journal of Geophysical Research: Earth Surface, Vol. 113, Issue. F3,

ARDEKANI, A. M. and RANGEL, R. H. 2008. Numerical investigation of particle–particle and particle–wall collisions in a viscous fluid. Journal of Fluid Mechanics, Vol. 596, Issue. , p. 437.

Veeramani, C. Minev, P.D. and Nandakumar, K. 2009. Collision modeling between two non-Brownian particles in multiphase flow. International Journal of Thermal Sciences, Vol. 48, Issue. 2, p. 226.

ARDEKANI, A. M. JOSEPH, D. D. DUNN-RANKIN, D. and RANGEL, R. H. 2009. Particle-wall collision in a viscoelastic fluid. Journal of Fluid Mechanics, Vol. 633, Issue. , p. 475.

Kantak, A. A. Hrenya, C. M. and Davis, R. H. 2009. Initial rates of aggregation for dilute, granular flows of wet particles. Physics of Fluids, Vol. 21, Issue. 2,

Donahue, C. M. Hrenya, C. M. and Davis, R. H. 2010. Stokes’s Cradle: Newton’s Cradle with Liquid Coating. Physical Review Letters, Vol. 105, Issue. 3,

Feng, Zhi-Gang Michaelides, Efstathios E. and Mao, Shaolin 2010. A Three-Dimensional Resolved Discrete Particle Method for Studying Particle-Wall Collision in a Viscous Fluid. Journal of Fluids Engineering, Vol. 132, Issue. 9,

Turmel, Dominique and Locat, Jacques 2011. Numerical modeling of underwater rockfalls. Canadian Geotechnical Journal, Vol. 48, Issue. 1, p. 16.

Aguilar-Corona, Alicia Zenit, Roberto and Masbernat, Olivier 2011. Collisions in a liquid fluidized bed. International Journal of Multiphase Flow, Vol. 37, Issue. 7, p. 695.

Li, Xiaobai Hunt, Melany L. and Colonius, Tim 2012. A contact model for normal immersed collisions between a particle and a wall. Journal of Fluid Mechanics, Vol. 691, Issue. , p. 123.

Koos, Erin Linares-Guerrero, Esperanza Hunt, Melany L. and Brennen, Christopher E. 2012. Rheological measurements of large particles in high shear rate flows. Physics of Fluids, Vol. 24, Issue. 1,

Kempe, Tobias and Fröhlich, Jochen 2012. Collision modelling for the interface-resolved simulation of spherical particles in viscous fluids. Journal of Fluid Mechanics, Vol. 709, Issue. , p. 445.

Shaw, John B. Mohrig, David and Whitman, Spencer K. 2013. The morphology and evolution of channels on the Wax Lake Delta, Louisiana, USA. Journal of Geophysical Research: Earth Surface, Vol. 118, Issue. 3, p. 1562.

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Oblique particle–wall collisions in a liquid

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