Third-moment closure of turbulence for predictions of separating and reattaching shear flows: A study of Reynolds-stress closure model
Abstract
A numerical study of computations in backward-facing steps with flow separation and reattachment, using the Reynolds stress closure is presented. The highlight of this study is the improvement of the Reynold-stress model (RSM) by modifying the diffusive transport of the Reynolds stresses through the formulation, solution and subsequent incorporation of the transport equations of the third moments, bar-u(i)u(j)u(k), into the turbulence model. The diffusive transport of the Reynolds stresses, represented by the gradients of the third moments, attains greater significance in recirculating flows. The third moments evaluated by the development and solution of the complete transport equations are superior to those obtained by existing algebraic correlations. A low-Reynolds number model for the transport equations of the third moments is developed and considerable improvement in the near-wall profiles of the third moments is observed. The values of the empirical constants utilized in the development of the model are recommended. The Reynolds-stress closure is consolidated by incorporating the equations of k and e, containing the modified diffusion coefficients, and the transport equations of the third moments into the Reynolds stress equations. Computational results obtained by the original k-e model, the original RSM and the consolidated and modified RSM are compared with experimental data. Overall improvement in the predictions is seen by consolidation of the RMS and a marked improvement in the profiles of bar-u(i)u(j)u(k) is obtained around the reattachment region.
- Publication:
-
Final Report Wisconsin Univ
- Pub Date:
- September 1986
- Bibcode:
- 1986wisc.reptR....A
- Keywords:
-
- Backward Facing Steps;
- Boundary Layer Flow;
- Computational Fluid Dynamics;
- Flow Equations;
- Reattached Flow;
- Reynolds Stress;
- Separated Flow;
- Shear Flow;
- Turbulence Models;
- Turbulent Flow;
- Convergence;
- Differential Equations;
- Iterative Solution;
- K-Epsilon Turbulence Model;
- Reynolds Number;
- Shear Layers;
- Fluid Mechanics and Heat Transfer