Abstract
Comprehensive knowledge of hydrodynamics inside a reactor is crucial for the design and scale-up of bubble columns. Fractional gas holdup (αg) is an important parameter that should be obtained for the design of bubble column reactors. The estimation of this parameter depends mainly on experimental procedures. Drift-flux theory is one of the most practical and accurate models for calculating the gas holdup. Although many researchers have studied bubble column reactors, because of the limits of the experimental setting, there are few studies that have operated over a wide range of superficial gas velocities. In this work, a transient 3-D numerical simulation of upward air-water flow in the bubble column was performed over a wide range of superficial gas velocities (0.025-0.4 m/s) using the Eulerian-Eulerian model. The effect of the superficial gas velocity on the flow pattern was simulated, and two-phase flow regimes were classified into homogeneous, transition and heterogeneous regimes. Considering the importance of the drift-flux model, the values of the distribution parameter and the drift velocity were computed according to their definitions using the cross-sectional gas holdup and velocity profiles obtained via computational flow dynamic simulation. The results were verified against the experimental data, and a correlation is proposed for predicting the gas holdup.
Highlights
Bubble column reactors are used extensively in industrial operations, due to their relatively low investment requirements; this is in addition to low operating and maintenance costs, ease of operation and good heat and mass transfer
Fractional gas holdup can be defined as a volumetric or cross-sectional void fraction which is referred to the fraction of the volume/area occupied by the gas
Gas holdup plays a significant role in the design and scale-up of bubble column reactors
Summary
Bubble column reactors are used extensively in industrial operations, due to their relatively low investment requirements; this is in addition to low operating and maintenance costs, ease of operation and good heat and mass transfer. For the purpose of scale-up and designing continuous bubble column reactors, many researchers have studied this phenomena experimentally and theoretically They have investigated the effects of various parameters such as gas holdup, superficial gas and liquid velocity, gas-liquid interfacial area, interfacial heat and mass transfer coefficients and sparger design [9,10,11,12,13,14,15,16]. Considering phenomena in an application, there is almost no analytical solution for all aforementioned equations; we resort to numerical analysis using CFD. This tool equips us to analyze different scenarios that are extremely difficult to obtain through experiments. CFD can effectively bridge the gap between large-scale commercialized and lab-scale bubble column reactors and provide a qualitative (and sometimes even quantitative) prediction of velocity, concentration, temperature and pressure profiles
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