摘要
Simulations of the gas fluidization of a cohesive powder were performed usingthe Stokesian Dynamics method and an agglomeration-deagglomeration model to investigate methods ofimproving the fluidizability of fine powders. Three techniques (a) high gas velocity (b)vibration-assisted fluidization and (c) tapered fluidizer were used in the simulations whichprovided detailed information on the bed microscopy such as the motion of 100 particles in afluidizing vessel along with the formation and destruction of cohesive bonds during collisions.While all three techniques were found to effectively improve the fluidizability of a stronglycohesive powder, we suggest a combination of high velocity fluidization assisted by externalvibration of the fluidized bed to minimize entrainment of particles.
Simulations of the gas fluidization of a cohesive powder were performed usingthe Stokesian Dynamics method and an agglomeration-deagglomeration model to investigate methods ofimproving the fluidizability of fine powders. Three techniques (a) high gas velocity (b)vibration-assisted fluidization and (c) tapered fluidizer were used in the simulations whichprovided detailed information on the bed microscopy such as the motion of 100 particles in afluidizing vessel along with the formation and destruction of cohesive bonds during collisions.While all three techniques were found to effectively improve the fluidizability of a stronglycohesive powder, we suggest a combination of high velocity fluidization assisted by externalvibration of the fluidized bed to minimize entrainment of particles.
