Numerical Analysis of Effects of Specularity Coefficient and Restitution Coefficient on the Hydrodynamics of Particles in a Rotating Drum

Various simulations have been conducted to understand the macroscopic behavior of particles in the solid-gas flow in rotating drums in the past. In these studies, the no-slip wall boundary condition and fixed restitution coefficient between particles were usually adopted. The paper presents a numerical study of the gas-solid flow in a rotating drum to understand the effect of the specularity coefficient and restitution coefficient on the hydrodynamic behavior of particles in the segregation process. The volume fraction, granular pressure, granular temperature and their relationships are examined in detail. The boundary conditions of the no-slip and specularity coefficient of 1 are compared. In the simulations, two different sizes of particles with the same density are considered and the Eulerian-Eulerian multiphase model and the kinetic theory of granular flow (KTGF) are used. The results reveal that the hydrodynamical behavior of the particles in the rotating drum is affected by the boundary condition and restitution coefficient. In particular, the increase of specularity coefficient can increase the active region depth, angle repose, granular pressure for both small and large particles and granular temperature for large particles. With increasing restitution coefficient, the angle of repose decreases and granular pressure and temperature increase at the same volume fraction for both small and large particles.

Automated summary

This paper presents a numerical study on the gas-solid flow in a rotating drum to investigate the influence of specularity coefficient and restitution coefficient on the hydrodynamic behavior of particles during the segregation process. The results reveal that the boundary condition and restitution coefficient have significant effects on the hydrodynamics of the particles, with an increase in specularity coefficient leading to increased depth of the active region, angle of repose, granular pressure, and granular temperature. With an increasing restitution coefficient, the angle of repose decreases while the granular pressure and temperature increase at the same volume fraction for both small and large particles.