TURBULENCE CLOSURE MODELING OF TWO-PHASE FLOWS

1 August 1984

journal article
research article
Published by Taylor & Francis in Chemical Engineering Communications

Vol. 29 (1-6) , 291-310
https://doi.org/10.1080/00986448408940164

Abstract

A second order turbulence closure model is developed for the numerical prediction of isothermal non-reacting, two-phase turbulent shear flows. This model is based on the two-equation (k - ∊) model but treats the continuous (gas) phase and (solid) particulate phase as separate interacting continua. The presence of the particles will increase the dissipation rate in the gas phase and additional terms based on the particle size and loading are added to the traditional k and ∊ equations. The model is tested by making predictions of the spreading rate and velocity decay in the developing region of the two-phase axisymmetric jet. The predictions agree favorably with available experimental data in this region.

Keywords

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