Numerical modelling of gas-liquid flow in stirred tanks

Lane, G. L.; Schwarz, M. P.; Evans, G. M.

Title: Numerical modelling of gas-liquid flow in stirred tanks
Creator: Lane, G. L.; Schwarz, M. P.; Evans, G. M.
Relation: Chemical Engineering Science Vol. 60, Issue 8-9, p. 2203-2214
Publisher Link: http://dx.doi.org/10.1016/j.ces.2004.11.046
Publisher: Elsevier Ltd.
Resource Type: journal article
Date: 2005
Description: A numerical modelling method is presented for gas–liquid flow in mechanically stirred tanks. In this method, the tank is represented by a mesh which explicitly includes the impeller geometry, with impeller motion treated by the multiple frames of reference or sliding mesh methods. Gas–liquid flow is modelled using an ensemble-averaged form of the Eulerian two-fluid equations. This leads to an interfacial force term containing a turbulent dispersion force term, for which a closure expression is applied following the method proposed by Bel F’dhila and Simonin (Proceedings of the Sixth Workshop on Two-Phase Flow Prediction, Erlangen, Germany, pp. 264–273). An important consideration is the increase in drag coefficient on bubbles due to interaction between bubbles and turbulence. By analysing literature data, a new correlation is proposed to account for this increase in drag. Bubble size is also predicted through a bubble number density equation, which accounts for break-up and coalescence phenomena. However, the rapid coalescence near impeller blades is modelled through an algebraic equation, as a function of gas volume fraction, allowing prediction of gas cavities. The modelling method has been applied to a baffled tank stirred by a Rushton turbine, and simulation results are compared with the experimental measurements of Barigou and Greaves (Chem. Eng. Sci. 47(8) (1992) 2009; Trans. I. Chem. E. 74 (1996) 397) for bubble size and gas volume fraction. In comparison with this data, reasonable agreement is obtained over a range of operating conditions, and a significant improvement is demonstrated using the proposed correlation for drag in turbulent flow. The modelling method has also been applied to a tank stirred by a Lightnin A315 impeller. Again, improved results are obtained using the proposed correlation for drag in turbulent flow, and predicted gas holdup is in good agreement with experimental data.
Subject: bubble size; gas–liquid flow; mixing; multiphase flow; simulation; stirred tank
Identifier: http://hdl.handle.net/1959.13/27505
Identifier: uon:1739
Identifier: ISSN:0009-2509
Language: eng
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