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A hybrid particle-geometric scaling approach for elasto-plastic adhesive DEM contact models

M. Javad Mohajeri, Rudy Helmons, Cees van Rhee, Dingena Schott

2020Powder Technology35 citationsDOIOpen Access PDF

Abstract

The computation time of Discrete Element Method (DEM) simulations increases exponentially when particle size is reduced or the number of particles increased. This critical challenge limits the use of DEM simulation for industrial applications, such as powder flow in silos. Scaling techniques can offer a solution to reduce computation time. In this paper, we have developed a hybrid particle-geometric scaling approach with a focus on Elasto-Plastic Adhesive contact models. It established relationships between particle scaling factors and DEM contact input parameters. The isolated effects of varying particle size and geometric dimensions on bulk properties were also evaluated using uniaxial consolidation, static angle of repose, and ring shear tests. This paper shows how the particle scaling can be applied together with geometric scaling to incorporate two important aspects of bulk materials, their Elasto-Plastic behaviour and their cohesive forces.

Topics & Concepts

Discrete element methodScalingComputationAngle of reposeMechanicsContact forceMaterials scienceParticle (ecology)Granular materialConsolidation (business)AdhesiveStatistical physicsGeometryMathematicsClassical mechanicsComposite materialPhysicsAlgorithmGeologyAccountingBusinessLayer (electronics)OceanographySoil Mechanics and Vehicle DynamicsGranular flow and fluidized bedsFluid Dynamics Simulations and Interactions
A hybrid particle-geometric scaling approach for elasto-plastic adhesive DEM contact models | Litcius