3D DEM simulations of monotonic interface behaviour between cohesionless sand and rigid wall of different roughness

The paper deals with three-dimensional simulations of a monotonic quasi-static interface behaviour between cohesionless sand and a rigid wall of different roughness during wall friction tests in a parallelly guided direct shear test under constant normal stress. Numerical modelling was carried out by the discrete element method (DEM) using spheres with contact moments to approximately capture a non-uniform particle shape. The varying wall surface topography was simulated by a regular mesh of triangular grooves (asperities) along the wall with a different height, distance and inclination. The calculations were carried out with different initial void ratios of sand and vertical normal stress. The focus was to quantify the effect of wall roughness on the evolution of mobilized wall friction and shear localization, also to specify the ratios between slip and rotation and between shear stress/force and couple stress/moment in the sand at the wall. DEM simulations were generally in good agreement with reported experimental results for similar interface roughness. The findings presented in this paper offer a new perspective on the understanding of the wall friction phenomenon in granular bodies.

Automated summary

This paper presents three-dimensional simulations of the interface behavior between cohesionless sand and a rigid wall of different roughness during wall friction tests. The study quantifies the effect of wall roughness on mobilized wall friction and shear localization, as well as the ratios between slip/rotation and shear stress/couple stress in the sand at the wall. The findings offer a new perspective on understanding the wall friction phenomenon in granular bodies.