Improved Delayed Detached Eddy Simulation with Reynolds-Stress Background Modeling

TL;DR

This paper introduces a new hybrid turbulence modeling approach combining Reynolds-stress closures with LES techniques, validated through channel flow and boundary layer simulations, aiming for improved accuracy in turbulent flow predictions.

Contribution

A novel hybrid model integrating Reynolds-stress background modeling with LES, enhancing turbulence simulation accuracy across different flow regimes.

Findings

Hybrid model improves turbulence dissipation in LES regions.

Validation shows good agreement with experimental data.

Initial sensitivity analysis reveals potential issues with synthetic turbulence.

Abstract

A novel variant of Improved Delayed Detached-Eddy Simulation based on a differential Reynolds-stress background model is presented. The approach aims to combine the advantages of anisotropy-resolving Reynolds-stress closures in the modelled RANS regions with consistent LES and wall-modelled LES behaviour in the resolved flow regions. In computations of decaying isotropic turbulence with a low-dissipative flow solver it is shown that a straightforward hybridised Reynolds-stress model provides insufficient turbulent dissipation as sub-grid closure in the LES regions and is therefore locally replaced by scalar viscosity modelling. Simulations of periodic channel flows at different Reynolds numbers and grid resolutions are used to calibrate and validate the wall-modelled LES branch of the new model. A final application in embedded wall-modelled LES of a flat-plate boundary layer is widely consistent with results using the SST-RANS background model, but shows some deviations from the Coles-Fernholz skin-friction correlation. In this regard, initial sensitivity studies indicate possible adverse effects due to the synthetic-turbulence approach used in these simulations.