On velocity profiles and stresses in sheared and vibrated granular systems under variable gravity

Document Type

Article

Publication Date

1-1-2006

Abstract

We employ discrete element three-dimensional simulations that include realistic modeling of physical system boundaries to determine the influence of gravity on velocity profiles and stresses for frictional inelastic particles that are confined in an angular Couette cell, and sheared by a rotated upper wall. In addition to Earth gravity, we consider other gravitational fields, in particular those of the Moon and Mars. The computational techniques are based on hard-sphere simulations of polydisperse particles at relatively high volume fraction (50-55%). We find that the presence of gravity induces significant changes of the velocity profiles and stresses. One important nondimensional parameter in the problem is shown to be IΩ=γ̇d/ √Pg/ρs where γ̇ is the imposed shear rate, Pg is the weight of the system per unit area due to gravity, and ρs is the solid density. We also consider systems that are vibrated in addition to being sheared, since vibrations are one of several important methods for agitating (e.g., fluidizing and/or unjamming) granular systems. We find that the introduction of nondimensional acceleration Γ=a(2πf)2g, where a,f,g are the amplitude and frequency of oscillations, and the acceleration of gravity, explains novel features that develop in these complex granular systems. © 2006 American Institute of Physics.

Identifier

33846074350 (Scopus)

Publication Title

Physics of Fluids

External Full Text Location

https://doi.org/10.1063/1.2397007

ISSN

10706631

Issue

12

Volume

18

Grant

NNC04GA98G

Fund Ref

National Aeronautics and Space Administration

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