Hydrodynamics and mass transfer study of oil-water micro-emulsion in a three phase external loop airlift reactor

Packing size effects on the fluid dynamics in an external-loop packed bubble column with Raschig rings of three different effective diameters (4.9, 14.1, and 40.7 mm) in the riser were investigated. The overall gas holdup, liquid circulating velocity and gas-liquid mass transfer coefficient were respectively measured by volume expansion, tracer-response, and dynamic oxygen-absorption techniques. CFD simulation with the Euler-Euler two-fluid method was used to predict the liquid circulating velocity by treating the packing as a porous medium. Compared to the empty column, the gas holdup was found to increase in the presence of packing, however, the liquid circulating velocity and gas-liquid mass transfer coefficient are rather complicated.Specifically, the gas holdup increases with the decrease of packing size, while the liquid circulating velocity is on the contrary, and the maximal gas-liquid mass transfer coefficient is achieved under packing diameter of 14.1 mm.

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Packing size effects on the liquid circulation property in an external‐loop packed bubble column

Tang

Luo

Cheng

2022

AIChE Journal

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Large scale preparation of microbubbles by multi‐channel ceramic membranes: Hydrodynamics and mass transfer characteristics

et al. 2017

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Microbubbles have potential applications in chemical engineering, water treatment, and medicine. By designing multi‐channel ceramic membrane distributors, large scale preparation of microbubbles is achieved in a co‐current bubble column. Oxygen and water are used as interacting gas‐liquid phases. Gas holdup, bubble size distribution, and mass transfer rate are influenced by the membrane pore size, superficial gas velocity, and cross flow velocity. The empirical correlations for gas holdup and volumetric mass transfer coefficient are formulated and good agreement with experimental data is obtained. The multi‐channel ceramic membranes can successfully produce a lot of microbubbles, resulting in larger values of gas holdup, volumetric mass transfer coefficient, and equilibrium dissolved oxygen concentrations as compared to the conventional gas sparger. These findings will aid the development of gas‐liquid reactors with high performances.

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Predominant mode of diesel uptake: Direct interfacial versus emulsification in multiphase bioreactor

Angeles

Medina-Moreno

Jiménez-González

et al. 2017

Chemical Engineering Science

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Hydrodynamics and mass transfer study of oil-water micro-emulsion in a three phase external loop airlift reactor

Cited by 3 publications

References 24 publications

Packing size effects on the liquid circulation property in an external‐loop packed bubble column

Packing size effects on the liquid circulation property in an external‐loop packed bubble column

Large scale preparation of microbubbles by multi‐channel ceramic membranes: Hydrodynamics and mass transfer characteristics

Predominant mode of diesel uptake: Direct interfacial versus emulsification in multiphase bioreactor

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