Second-order closure models for supersonic turbulent flows
Abstract
Recent work on the development of a second-order closure model for high-speed compressible flows is reviewed. This turbulent closure is based on the solution of modeled transport equations for the Favre-averaged Reynolds stress tensor and the solenoidal part of the turbulent dissipation rate. A new model for the compressible dissipation is used along with traditional gradient transport models for the Reynolds heat flux and mass flux terms. Consistent with simple asymptotic analyses, the deviatoric part of the remaining higher-order correlations in the Reynolds stress transport equations are modeled by a variable density extension of the newest incompressible models. The resulting second-order closure model is tested in a variety of compressible turbulent flows which include the decay of isotropic turbulence, homogeneous shear flow, the supersonic mixing layer, and the supersonic flat-plate turbulent boundary layer. Comparisons between the model predictions and the results of physical and numerical experiments are quite encouraging.
- Publication:
-
NASA STI/Recon Technical Report N
- Pub Date:
- January 1991
- Bibcode:
- 1991STIN...9118390S
- Keywords:
-
- Isotropic Turbulence;
- Mathematical Models;
- Reynolds Stress;
- Shear Flow;
- Stress Tensors;
- Supersonic Flow;
- Turbulent Flow;
- Dissipation;
- Heat Flux;
- High Speed;
- Mixing Layers (Fluids);
- Supersonic Boundary Layers;
- Turbulence;
- Turbulent Boundary Layer;
- Fluid Mechanics and Heat Transfer