Effects of geometric structure of hydrocyclone and operating conditions on the classification efficiency of particles are studied and discussed. A 10 mm-diameter hydrocyclone is installed for particle classification. Four kinds of particles with different size distributions and physical properties are used in experiments and in computational fluid dynamics (CFD) analyses. Experimental results show that an increase in pressure drops, split ratio, or suspension temperature or a decrease in feed concentration leads both the partial separation efficiency and overall separation efficiency to be increase. However, the effect of suspension temperature is trivial. The Fish-hook effect in partial separation efficiency occurs in all experimental results. The maximum deviation of the partial efficiency curve between the simulation results and experimental data is about 25%. The velocity and pressure profiles and the trajectories of particles in the hydrocyclone are simulated by computational fluid dynamics method and discussed. The simulation results show that the diameter and the feed position of particles play important roles on the particle trajectories in hydrocyclone. The flow pattern, the partial separation efficiency and the split ratio are strongly dependent on the geometric structure of hydrocyclone. Increasing the diameter of overflow pipe or decreasing the diameter of underflow pipe leads to a lower partial separation efficiency. A rectangular inlet which width exceeds height results in higher partial separation efficiency than one which height is longer.