We consider the instability properties of dense granular flow in inclined plane and plane shear geometries as tests for the compressible inertial-dependent rheology. The model, which is a recent generalisation of the incompressible π
π(I)
rheology, constitutes a hydrodynamical description of dense granular flow which allows for variability in the solids volume fraction. We perform a full linear stability analysis of the model and compare its predictions to existing experimental data for glass beads on an inclined plane and discrete element simulations of plane shear in the absence of gravity. In the case of the former, we demonstrate that the compressible model can quantitatively predict the instability properties observed experimentally, and, in particular, we find that it performs better than its incompressible counterpart. For the latter, the qualitative behaviour of the plane shear instability is also well captured by the compressible model.
History
Publication
Journal of Fluid Mechanics;864, pp. 1026-1057
Publisher
Cambridge University Press
Note
peer-reviewed
The full text of this article will not be available in ULIR until the embargo expires on the 14/08/2019
Other Funding information
SFI
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Language
English
Also affiliated with
MACSI - Mathematics Application Consortium for Science & Industry