Gas-solid separation performance and structure optimization in 3D printed guide vane cyclone separator

Abstract

• A 3D printed guide vane cyclone separator was designed. • Theory, experiment, and simulation were used to study the separation performance. • The pressure, velocity, energy, and particle movement were discussed. • The tangential velocity was the major influence of separating. • The optimized cyclone had higher separation performance and lower pressure drop. Low separation efficiency and large pressure drop are two common problems of cyclones. In this paper, a 3D printed guide vane cyclone separator was designed to study the separation efficiency, turbulent kinetic energy, and particle movement of particle group by experiment and simulation. The results shown that the tangential velocity was the major influence of separating. The bottom of the exhaust pipe was the main region of gas–solid separation and pressure drop. The separation efficiency and pressure drop were positively correlated with the inlet velocity and the particle radius of the fluid. The distribution of turbulent kinetic energy that leaded to the pressure drop loss was concentrated on the inlet of the exhaust pipe. The swirl has external and internal two directions. The optimized cyclone has a longer and narrower blade flow path to obtain higher separation efficiency, especially at low inlet velocity.