Analysis of subgrid models using direct and large-eddy simulations of isotropic turbulence
Abstract
Direct and large eddy simulations of forced and decaying isotropic turbulence have been performed using a pseudospectral and a finite-difference code. Subgrid models that include a one-equation subgrid kinetic energy model with and without a stochastic backscatter forcing term and a new scale similarity model have been analyzed in both Fourier space and physical space. The Fourier space analysis showed that the energy transfer across the cutoff wavenumber k(sub c) is dominated by local interaction. The correlation between the exact and the modeled (by a spectral eddy viscosity) nonlinear terms and the subgrid energy transfer in physical space was found to be quite low. In physical space, a similar correlation analysis was carried out using top hat filtering. Results show that the subgrid stress and the energy flux predicted by the subgrid models correlates very well with the exact data. The scale similarity model showed very high correlation for reasonable grid resolution. However, with decrease in grid resolution, the scale similarity model became more uncorrelated, when compared to the kinetic energy subgrid model. The subgrid models were then used for large-eddy simulations for a range of Reynolds number. It was determined that the dissipation was modeled poorly and that the correlation with the exact results was quite low for all the models. In general, for coarse grid resolution, the scale similarity model consistently showed very low correlation while the kinetic energy model showed a relatively higher correlation. These results suggest that to use the scale similarity model relatively fine grid resolution may be required, whereas, the kinetic energy model could be used even in coarse grid.
- Publication:
-
In AGARD
- Pub Date:
- December 1994
- Bibcode:
- 1994adle.agarR....M
- Keywords:
-
- Backscattering;
- Correlation;
- Finite Difference Theory;
- Fourier Analysis;
- Isotropic Turbulence;
- Kinetic Energy;
- Simulation;
- Stochastic Processes;
- Vortices;
- Analogies;
- Dissipation;
- Eddy Viscosity;
- Energy Transfer;
- Flux Density;
- Nonlinearity;
- Reynolds Number;
- Scale Models;
- Fluid Mechanics and Heat Transfer