Drag of Two Cylindrical Intruders in a Two-Dimensional Granular Environment

Abstract

The drag of two cylindrical intruders in a two-dimensional granular environment is numerically studied by the discrete element method. We find the yield force, below which the intruders cannot move because of interactions with the surrounding particles. Above the yield force, on the other hand, the intruders can move at a constant speed. We investigate the relationship between the drag force and the steady speed of the intruders, where the speed becomes higher as the distance between the intruders decreases. We confirm that the origin of the yield is the Coulombic friction between the particles and the bottom plate by changing the value of the friction coefficient. We also find that the yield force is almost proportional to the friction coefficient, which means that the number of particles determining the yield force is almost constant. On the other hand, the two-dimensional elasticity is applicable to determine the stress fields around the intruders. We confirm that fields asymmetric with respect to the drag direction are reproduced by using the information of the stresses on the surfaces of the intruders by introducing bipolar coordinates.