Simulating dense granular flow using the $\mu$($I$)-rheology within a space-time framework

TL;DR

This paper presents a space-time numerical framework for simulating dense granular flows using the $s$($I$)-rheology, capturing complex behaviors and interface dynamics in two-phase flow experiments.

Contribution

It introduces a novel space-time discretization approach for dense granular flow simulation using $s$($I$)-rheology within a two-phase flow model.

Findings

The space-time framework effectively captures interface dynamics.

Mesh refinement improves simulation accuracy near interfaces.

Both flat and simplex space-time discretizations are validated.

Abstract

A space-time framework is applied to simulate dense granular flow. Two different numerical experiments are performed: a column collapse and a dam break on an inclined plane. The experiments are modeled as two-phase flows. The dense granular material is represented by a constitutive model, the $\mu$($I$)-rheology, that is based on the Coulomb's friction law, such that the normal stress applied by the pressure is related to the tangential stress. The model represents a complex shear thinning viscoplastic material behavior. The interface between the dense granular material and the surrounding light fluid is captured with a level set function. Due to discontinuities close to the the interface, the mesh requires a sufficient resolution. The space-time approach allows unstructured meshes in time and, therefore a well refined mesh in the temporal direction around the interface. In this study, results and performance of a flat and a simplex space time discretization are verified and analyzed.