Design and Optimization of Gas–Liquid Vortex Unit Using Computational Fluid Dynamics (CFD) Simulation

Abstract: Due to the exceptional multiphase mixing and mass transfer performance, gas–liquid vortex units (GLVUs) have great potential for solvent-based applications such as CO2 capture. The high gas flow rates needed to provide the energy input for creating the centrifugal field negatively influence the contact between phases and the efficiency of the GLVU. To address this issue, computational fluid dynamics (CFD) simulations are used to optimize the design of the GLVU geometry and its operating conditions. The gas–liq… Show more

“…The use of CFD significantly accelerates the optimization of design of units for subsequent manufacturing. Ouyang et al 11 applied CFD research to optimize the geometric design of gas−liquid vortex units and their operating conditions. The results demonstrated that gas−liquid contact time of the optimized unit increased by more than three times compared to the base unit, while energy consumption was reduced by 85%.…”

Multiphase Transportation, Conversion, & Utilization of Energy in Chemical Engineering: A Special Issue for MTCUE-2022

“…The use of CFD significantly accelerates the optimization of design of units for subsequent manufacturing. Ouyang et al 11 applied CFD research to optimize the geometric design of gas−liquid vortex units and their operating conditions. The results demonstrated that gas−liquid contact time of the optimized unit increased by more than three times compared to the base unit, while energy consumption was reduced by 85%.…”

Multiphase Transportation, Conversion, & Utilization of Energy in Chemical Engineering: A Special Issue for MTCUE-2022

Enhancing CO2 capture efficiency: Computational fluid dynamics investigation of gas-liquid vortex reactor configurations for process intensification

A numerical scale-up study of annular fluidized bed reactor with high centrifugal acceleration