Interfacial friction factor determination using CFD simulations in a horizontal stratified two-phase flow

Interfacial friction factor determination using CFD simulations in a horizontal stratified two-phase flow

Stratified two-phase gas–liquid flow in three-dimensional (3D) is challenging because of the difficulty in determining the shear stresses at the walls and at the gas–liquid interface. The study is simplified by considering only the gas and the gas–liquid interface. The gas flows between the fixed wa...

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Bibliographic Details
Published in:Chemical engineering science Vol. 65; no. 18; pp. 5160 - 5169
Main Authors: Sidi-Ali, Kamel, Gatignol, Renée
Format: Journal Article
Language:English
Published: Elsevier Ltd 15-09-2010
Subjects:
Computational fluid dynamics
Computer simulation
Friction factor
Gas–liquid interface
Horizontal
Liquids
Mathematical analysis
Mathematical models
Shear stress
Stratified flow
Two-phase flow
Velocity profile
Walls
Velocity profile
Shear stress
Friction factor
Gas–liquid interface
Two-phase flow
Stratified flow
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Summary:Stratified two-phase gas–liquid flow in three-dimensional (3D) is challenging because of the difficulty in determining the shear stresses at the walls and at the gas–liquid interface. The study is simplified by considering only the gas and the gas–liquid interface. The gas flows between the fixed wall of the pipe and the interface, which is regarded as wall moving at liquid velocity. It is shown, using a CFD code, that one can determine the correct horizontal and vertical profiles of the longitudinal velocity of the gas. Seven experiments done by Strand (1993) for a horizontal stratified gas–liquid flow are simulated. The simulation results are compared with experimental results, and also to the numerical results of Meknassi et al. (2000). We deduce from these comparisons that the approach suggested in this work is very valuable. Then expressions for calculating the gas–wall friction factor, and the gas–liquid interface friction factor are presented. These factors are crucial for evaluating the shear stresses. It appears, after comparison with the experimental values that the correlation proposed for calculating the friction factor at the interface, in the present work, agree with the experimental values better than that given by Taitel and Duckler (1976a, b).
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ISSN:0009-2509
1873-4405
DOI:10.1016/j.ces.2010.06.015