posted on 2009-07-07, 13:33authored byJolius Gimbun, Chris Rielly, Zoltan NagyZoltan Nagy
A combined computational fluid dynamics (CFD) and population balance model (PBM)
approach has been applied to the simulation of gas-liquid stirred tanks agitated by (i) a Rushton
turbine or (ii) a CD-6 impeller, operating at aeration numbers from 0.017 to 0.038. The multiphase
simulations were realised via an Eulerian-Eulerian two-fluid model and the drag coefficient of
spherical and distorted bubbles was modelled using the Ishii-Zuber equations. The effect of the void
fraction on the drag coefficient was modelled using the correlation by Behzadi et al. (2004). The local
bubble size distribution was obtained by solving the PBM using the quadrature method of moments
(QMOM). The local kLa was estimated using both the Higbie penetration theory and the surface
renewal model. The predicted gas-liquid hydrodynamics, local bubble sizes and dissolved oxygen
concentration were in good agreement with experimental measurements reported in the literature. A
slight improvement in the prediction of the aerated power number was obtained using the non-uniform
bubble size distribution resulting from the coupled CFD-PBM simulation. Evaluation of the
prospective scale-up approaches indicates a higher probability of maintaining a similar level of mass
transfer in a larger tanks by keeping the Pg/V and VVM constant. Considering its predictive
capability, the method outlined in this work can provide a useful scale-up evaluation of gas-liquid
stirred tanks.
History
School
Aeronautical, Automotive, Chemical and Materials Engineering
Department
Chemical Engineering
Citation
GIMBUN, J., RIELLY, C.D. and NAGY, Z.K., 2009. Modelling of mass transfer in gas-liquid stirred tanks agitated by Rushton turbine and CD-6 impeller: a scale-up study. Chemical Engineering Research and Design, 87 (4), pp. 437-451