Simulation of bubble column reactors using CFD coupled with a population balance model

doi:10.1007/s11705-009-0267-5

Front Chem Sci Eng

2011, Vol. 5

Issue (2) : 162-172 https://doi.org/10.1007/s11705-009-0267-5

REVIEW ARTICLE

Simulation of bubble column reactors using CFD coupled with a population balance model

Tiefeng WANG(

)

Beijing Key Laboratory of Green Reaction Engineering and Technology, Department of Chemical Engineering, Tsinghua University, Beijing 100084, China

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Abstract

Bubble columns are widely used in chemical and biochemical processes due to their excellent mass and heat transfer characteristics and simple construction. However, their fundamental hydrodynamic behaviors, which are essential for reactor scale-up and design, are still not fully understood. To develop design tools for engineering purposes, much research has been carried out in the area of computational fluid dynamics (CFD) modeling and simulation of gas-liquid flows. Due to the importance of the bubble behavior, the bubble size distribution must be considered in the CFD models. The population balance model (PBM) is an effective approach to predict the bubble size distribution, and great efforts have been made in recent years to couple the PBM into CFD simulations. This article gives a selective review of the modeling and simulation of bubble column reactors using CFD coupled with PBM. Bubble breakup and coalescence models due to different mechanisms are discussed. It is shown that the CFD-PBM coupled model with proper bubble breakup and coalescence models and interphase force formulations has the ability of predicting the complex hydrodynamics in different flow regimes and, thus, provides a unified description of both the homogeneous and heterogeneous regimes. Further study is needed to improve the models of bubble coalescence and breakup, turbulence modification in high gas holdup, and interphase forces of bubble swarms.

Keywords bubble column computational fluid dynamics bubble breakup and coalescence population balance model bubble size distribution

Corresponding Author(s): WANG Tiefeng,Email:wangtf@tsinghua.edu.cn

Issue Date: 05 June 2011

Cite this article:

Tiefeng WANG. Simulation of bubble column reactors using CFD coupled with a population balance model[J]. Front Chem Sci Eng, 2011, 5(2): 162-172.

URL:

https://academic.hep.com.cn/fcse/EN/10.1007/s11705-009-0267-5
https://academic.hep.com.cn/fcse/EN/Y2011/V5/I2/162

Fig.1 Bubble breakup and coalescence due to different mechanism

Tab.1 Daughter size distribution models in the literature

Fig.2 Influence of the mother bubble size and energy dissipation rate on the breakup rate for an air-water system ( = 0.0725 N/m, = 0.01, /λ = 31.4)

Tab.2 Models of bubble breakup and coalescence

Fig.3 Influence of the mother bubble size on daughter bubble size distribution for an air-water system []
( = 0.0725 N/m, = 0.01, / = 31.4)

Fig.4 Simulation of gas-liquid mass transfer with the framework of the CFD-PBM coupled model []

Tab.3 Governing equations of the two-fluid model

Fig.5 Comparison of measured and simulated average gas holdup [,]
(Parameters of the simulated column: i.d. = 0.19 m, = 2.4 m. The results are for height of 2.0 m)

Fig.6 Radial profiles of the gas holdup in a gas-liquid cocurrent upward flow []

Fig.7 Bubble size distributions at different radial positions and superficial gas velocities []

Fig.8 Prediction of the variation of volume fraction of small bubbles with superficial gas velocity []

Fig.9 Comparison of the predicted and measured volumetric mass transfer coefficients []

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