Pore-scale Modeling of Viscous Flow and Induced Forces in Dense Sphere
  Packings

A.V. Oostreom; Andrea Cortis; B. Chareyre; Bruno Chareyre; Emanuele Catalano; Eric Barthélemy; F. Aurenhammer; F. Calvetti; H. Edelsbrunner; H. Knudsen; J.-D. Boissonnat; K. Bagi; K.D. Kafui; K.E. Thompson; L. Scholtes; M. Hassanizadeh; M. Hilpert; M. Piri; M. Zeghal; M.J. Niebling; M.S. Valavanides; N. Mortensen; P. Cundall; P. Øren; R. Glowinski; S. Bakke; S. Bryant; S. Bryant; S. Bryant; S. McNamara; S. Whitaker; T. Abichou; T. Kawaguchi; T. Patzek; V. Joekar-Niasar; V.A. Luchnikov; Y. Liu

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Pore-scale Modeling of Viscous Flow and Induced Forces in Dense Sphere Packings

Authors: A.V. Oostreom
Andrea Cortis
B. Chareyre
Bruno Chareyre
Emanuele Catalano
Eric Barthélemy
F. Aurenhammer
F. Calvetti
H. Edelsbrunner
H. Knudsen
J.-D. Boissonnat
K. Bagi
K.D. Kafui
K.E. Thompson
L. Scholtes
M. Hassanizadeh
M. Hilpert
M. Piri
M. Zeghal
M.J. Niebling
M.S. Valavanides
N. Mortensen
P. Cundall
P. Øren
R. Glowinski
S. Bakke
S. Bryant
S. Bryant
S. Bryant
S. McNamara
S. Whitaker
T. Abichou
T. Kawaguchi
T. Patzek
V. Joekar-Niasar
V.A. Luchnikov
Y. Liu
Publication date: 15 May 2013
Publisher: 'Springer Science and Business Media LLC'
Doi

Abstract

We propose a method for effectively upscaling incompressible viscous flow in large random polydispersed sphere packings: the emphasis of this method is on the determination of the forces applied on the solid particles by the fluid. Pore bodies and their connections are defined locally through a regular Delaunay triangulation of the packings. Viscous flow equations are upscaled at the pore level, and approximated with a finite volume numerical scheme. We compare numerical simulations of the proposed method to detailed finite element (FEM) simulations of the Stokes equations for assemblies of 8 to 200 spheres. A good agreement is found both in terms of forces exerted on the solid particles and effective permeability coefficients

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info:doi/10.1007%2Fs11242-011-...

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