Force on a Small Particle Attached to a Plane Wall in a Hiemenz Straining Flow

The force acting on a spherical particle fixed to a wall and immersed in an axisymmetric straining flow is examined for small Reynolds numbers. The steady, incompressible flow field is computed using an axisymmetric finite-volume method over conditions spanning five decades in the Reynolds number. T...

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Veröffentlicht in:	Journal of fluids engineering 2012-11, Vol.134 (11), p.1-5
Hauptverfasser:	Maynard, A. B, Marshall, J. S
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Atmospheric pollution Axisymmetric Computational fluid dynamics Exact sciences and technology Fluid flow General processes of purification and dust removal Incompressible flow Planes Pollution Prevention and purification methods Reynolds number Walls Wedges
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description	The force acting on a spherical particle fixed to a wall and immersed in an axisymmetric straining flow is examined for small Reynolds numbers. The steady, incompressible flow field is computed using an axisymmetric finite-volume method over conditions spanning five decades in the Reynolds number. The flow is characterized by the formation of a vortex ring structure in the wedge region formed between the particle lower surface and the plane wall. A power law expression for the dimensionless particle force is obtained as a function of the Reynolds number, which is found to hold with excellent accuracy for Reynolds numbers below about 0.1.
doi_str_mv	10.1115/1.4007742
format	Article
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subjects	Applied sciences Atmospheric pollution Axisymmetric Computational fluid dynamics Exact sciences and technology Fluid flow General processes of purification and dust removal Incompressible flow Planes Pollution Prevention and purification methods Reynolds number Walls Wedges
title	Force on a Small Particle Attached to a Plane Wall in a Hiemenz Straining Flow
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