Stokes flow about a slip arbitrary-shaped particle

A. Sellier

Stokes flow about a slip arbitrary-shaped particle

A. Sellier

Research output: Contribution to journal › Review article › peer-review

Abstract

A new approach is proposed to accurately compute at a reasonable cpu time cost the hydrodynamic net force and net torque exerted on a slip and arbitrarily-shaped solid particle experiencing a prescribed slow rigid-body migration in a quiescent Newtonian liquid. The advocated method appeals to a boundary formulation which makes it possible to reduce the task to the treatment of a relevant regularized boundary-integral equation on the particle slipping surface. This integral equation is numerically inverted by implementing a boundary element collocation method. In addition to benchmark tests against analytical and numerical results available in the literature, numerical results for volume-equivalent ellipsoids and open torus are given and discussed.

Original language	English
Pages (from-to)	157-176
Number of pages	20
Journal	CMES - Computer Modeling in Engineering and Sciences
Volume	87
Issue number	2
Publication status	Published - 19 Dec 2012

Keywords

Boundary Element Method
Boundary-integral equation
Navier slip condition
Slip particle
Stokes flow

Cite this

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title = "Stokes flow about a slip arbitrary-shaped particle",

abstract = "A new approach is proposed to accurately compute at a reasonable cpu time cost the hydrodynamic net force and net torque exerted on a slip and arbitrarily-shaped solid particle experiencing a prescribed slow rigid-body migration in a quiescent Newtonian liquid. The advocated method appeals to a boundary formulation which makes it possible to reduce the task to the treatment of a relevant regularized boundary-integral equation on the particle slipping surface. This integral equation is numerically inverted by implementing a boundary element collocation method. In addition to benchmark tests against analytical and numerical results available in the literature, numerical results for volume-equivalent ellipsoids and open torus are given and discussed.",

keywords = "Boundary Element Method, Boundary-integral equation, Navier slip condition, Slip particle, Stokes flow",

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T1 - Stokes flow about a slip arbitrary-shaped particle

AU - Sellier, A.

PY - 2012/12/19

Y1 - 2012/12/19

N2 - A new approach is proposed to accurately compute at a reasonable cpu time cost the hydrodynamic net force and net torque exerted on a slip and arbitrarily-shaped solid particle experiencing a prescribed slow rigid-body migration in a quiescent Newtonian liquid. The advocated method appeals to a boundary formulation which makes it possible to reduce the task to the treatment of a relevant regularized boundary-integral equation on the particle slipping surface. This integral equation is numerically inverted by implementing a boundary element collocation method. In addition to benchmark tests against analytical and numerical results available in the literature, numerical results for volume-equivalent ellipsoids and open torus are given and discussed.

AB - A new approach is proposed to accurately compute at a reasonable cpu time cost the hydrodynamic net force and net torque exerted on a slip and arbitrarily-shaped solid particle experiencing a prescribed slow rigid-body migration in a quiescent Newtonian liquid. The advocated method appeals to a boundary formulation which makes it possible to reduce the task to the treatment of a relevant regularized boundary-integral equation on the particle slipping surface. This integral equation is numerically inverted by implementing a boundary element collocation method. In addition to benchmark tests against analytical and numerical results available in the literature, numerical results for volume-equivalent ellipsoids and open torus are given and discussed.

KW - Boundary Element Method

KW - Boundary-integral equation

KW - Navier slip condition

KW - Slip particle

KW - Stokes flow

M3 - Review article

AN - SCOPUS:84871085098

SN - 1526-1492

VL - 87

SP - 157

EP - 176

JO - CMES - Computer Modeling in Engineering and Sciences

JF - CMES - Computer Modeling in Engineering and Sciences

IS - 2

ER -

Stokes flow about a slip arbitrary-shaped particle

Abstract

Keywords

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