Size dependent flow behaviors of particles in hydrocyclone based on multiphase simulation

To investigate the flow behaviors of different size particles in hydrocyclone, a designed process was numerically simulated by the transient solver, where the quartz particles possessing a size distribution were injected into a 100 mm diameter hydrocyclone with the steady water field and air core inside. A lab experimental work has validated the chosen models in simulation by comparing the classification efficiency results. The simulated process shows that the 25 mu m quartz particles, close to the cut size, need much more time than the finer and coarser particles to reach the steady flow rate on the outlets of hydrocyclone. For the particles in the inner swirl, with the quartz size increasing from 5 to 25 mu m, the particles take more time to enter the vortex finder. The 25 mu m quartz particles move outward in the radial direction when they go up to the vortex finder, which is contrary to the quartz particles of 5 mu m and 15 mu m as they are closely surrounding the air core. The studies reveal that the flow behaviors of particles inside the hydrocyclone depend on the particle size.