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Rheology of sheared polyhedral granular materials in inclined flows

Jiahui Hao, Yu Guo

2023Physics of Fluids15 citationsDOI

Abstract

An investigation of frictional, Platonic solid-shaped particle flows on inclined planes is performed using the discrete element method, and the effects of particle angular shape on rheological properties are analyzed. Higher shear stresses at a specified depth of particle bed are obtained for more angular particles. As particle angularity increases, rapid surges in the coordination number and solid-phase stresses occur at a smaller critical solid volume fraction. The friction and dilatancy laws of polyhedral particle flows are significantly different from those of spherical particle flows, due to particle angularity. Nevertheless, by applying a specific rolling friction to the spherical particles, their rheological properties can match those of the polyhedral particles, indicating that the angular particle shape plays a similar role to the rolling friction in preventing particle rotation. Thus, the flows of spherical particles with a rolling friction incorporated can be used to mimic the flows of angular polyhedral particles. At last, a scaling law is adopted to describe rheological relations for various polyhedral particles based on a bulk friction coefficient, a dimensionless granular temperature, and an inertial number.

Topics & Concepts

RheologyParticle (ecology)Dimensionless quantityDilatantMechanicsPhysicsGranular materialDiscrete element methodAngular velocityShear (geology)Classical mechanicsMaterials scienceComposite materialThermodynamicsGeologyQuantum mechanicsOceanographyGranular flow and fluidized bedsLandslides and related hazardsParticle Dynamics in Fluid Flows
Rheology of sheared polyhedral granular materials in inclined flows | Litcius