6533b7d8fe1ef96bd12699e4
RESEARCH PRODUCT
Balance equation of generalised sub-grid scale (SGS) turbulent kinetic energy in a new tensorial dynamic mixed SGS model
Francesco GalleranoEnrico Napolisubject
PhysicsCauchy stress tensorTurbulenceScalar (physics)Turbulence modelingGeneral Physics and AstronomyMaxwell stress tensorMechanicsPhysics::Fluid DynamicsMechanics of MaterialsTurbulence kinetic energyGeneral Materials ScienceStatistical physicsTensorLarge eddy simulationdescription
A new dynamic model is proposed in which the eddy viscosity is defined as a symmetric second rank tensor, proportional to the product of a turbulent length scale with an ellipsoid of turbulent velocity scales. The employed definition of the eddy viscosity allows to remove the local balance assumption of the SGS turbulent kinetic energy formulated in all the dynamic Smagorinsky-type SGS models. Furthermore, because of the tensorial structure of the eddy viscosity the alignment assumption between the principal axes of the SGS turbulent stress tensor and the resolved strain-rate tensor is equally removed, an assumption which is employed in the scalar eddy viscosity SGS models. The proposed model is tested for a turbulent channel flow. Comparison with the results obtained with other dynamic SGS models (Dynamic Smagorinsky Model, Dynamic Mixed Model and Dynamic K-equation Model) shows that the tensorial definition of the eddy viscosity and the removal of the local balance assumption of the SGS turbulent kinetic energy considerably improves the agreement between results obtained with Large Eddy simulation (LES) and Direct Numerical Simulations (DNS), respectevely.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2000-07-01 |