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Turbulent CFD Simulation of Two Rotor-Stator Agitators for High Homogeneity and Liquid Level Stability in Stirred Tank

Cuicui Yin, Kaihong Zheng, Jiazhen He, Yongnan Xiong, Zhuo Tian, Yingfei Lin, Danfeng Long

2022Materials12 citationsDOIOpen Access PDF

Abstract

Good solid-liquid mixing homogeneity and liquid level stability are necessary conditions for the preparation of high-quality composite materials. In this study, two rotor-stator agitators were utilized, including the cross-structure rotor-stator (CSRS) agitator and the half-cross structure rotor-stator (HCSRS) agitator. The performances of the two types of rotor-stator agitators and the conventional A200 (an axial-flow agitator) and Rushton (a radial-flow agitator) in the solid-liquid mixing operations were compared through CFD modeling, including the homogeneity, power consumption and liquid level stability. The Eulerian–Eulerian multi-fluid model coupling with the RNG k–ε turbulence model were used to simulate the granular flow and the turbulence effects. When the optimum solid-liquid mixing homogeneity was achieved in both conventional agitators, further increasing stirring speed would worsen the homogeneity significantly, while the two rotor-stator agitators still achieving good mixing homogeneity at the stirring speed of 600 rpm. The CSRS agitator attained the minimum standard deviation of particle concentration σ of 0.15, which was 42% smaller than that achieved by the A200 agitators. Moreover, the average liquid level velocity corresponding to the minimum σ obtained by the CSRS agitator was 0.31 m/s, which was less than half of those of the other three mixers.

Topics & Concepts

AgitatorHomogeneity (statistics)TurbulenceStatorImpellerMechanicsMaterials scienceComputational fluid dynamicsPaddleRushton turbineRotor (electric)EngineeringMechanical engineeringMathematicsPhysicsComposite materialStatisticsFluid Dynamics and MixingFluid Dynamics and Heat TransferFluid Dynamics Simulations and Interactions