Capturing turbulent density flux effects in variable density flow by an explicit algebraic model

The explicit algebraic Reynolds stress model of Grigoriev et al. [“A realizable explicit algebraic Reynolds stress model for compressible turbulent flow with significant mean dilatation,” Phys. Fluids 25, 105112 (2013)] is extended to account for the turbulent density flux in variable density flows....

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Bibliographic Details
Published in:Physics of fluids (1994) 2015-04, Vol.27 (4)
Main Authors: Grigoriev, I. A., Wallin, S., Brethouwer, G., Johansson, A. V.
Format: Article
Language:English
Subjects:
Algebra
Anisotropy
Approximate solution
Compressibility
Computational fluid dynamics
Computer simulation
Constraint modelling
Cyclone separators
Density
Explicit algebraic models
Explicit algebraic reynolds stress models
Fluid dynamics
Fluid flow
Fluxes
Nozzle flow
Nozzles
Parameters
Physics
Pipe flow
Production components
Quasi-one dimensional
Rapid pressure-strain correlation
Reynolds number
Reynolds stress
Reynolds stress tensors
Stretching
Tensors
Three dimensional flow
Three dimensional models
Turbulent flow
Variable-density flows
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Summary:The explicit algebraic Reynolds stress model of Grigoriev et al. [“A realizable explicit algebraic Reynolds stress model for compressible turbulent flow with significant mean dilatation,” Phys. Fluids 25, 105112 (2013)] is extended to account for the turbulent density flux in variable density flows. The influence of the mean dilatation and the variation of mean density on the rapid pressure-strain correlation are properly accounted for introducing terms balancing a so-called “baroclinic” production in the Reynolds stress tensor equation. Applying the weak-equilibrium assumption leads to a self-consistent formulation of the model. The model together with a K − ω model is applied to a quasi-one-dimensional plane nozzle flow transcending from subsonic to supersonic regimes. The model remains realizable with constraints put on the model parameters. When density fluxes are taken into account, the model is less likely to become unrealizable. The density variance coupled with a “local mean acceleration” also can influence the model acting to increase anisotropy. The general trends of the behaviour of the anisotropy and production components under the variation of model parameters are assessed. We show how the explicit model can be applied to two- and three-dimensional mean flows without previous knowledge of a tensor basis to obtain the general solution. Approaches are proposed in order to achieve an approximate solution to the consistency equation in cases when analytic solution is missing. In summary, the proposed model has the potential to significantly improve simulations of variable-density flows.
ISSN:1070-6631
1089-7666
1089-7666
DOI:10.1063/1.4917278