An investigation of subgrid mixing timescale modelling in LES of supersonic turbulent flames

The predictive numerical simulation of supersonic turbulent combustion, in which the turbulent intensity is high and the fuel/air mixture is near the flammability limit, remains challenging. An investigation of subgrid mixing timescale modelling in large eddy simulation (LES) of supersonic turbulent flames was carried out in this study. In the Partially Stirred Reactor (PaSR) combustion model, the dissipation-rate-based models estimate the mixing timescale by modeling dissipation rate, which may lead to incorrect estimation of mixing times at different grid resolutions. To solve the existing problem, a gradient-based mixing timescale estimation method was proposed. Subsequently, different approaches of subgrid mixing timescale in PaSR are compared and validated on a supersonic mixing layer, including a dissipation-rate-based model and the proposed gradient-based model. Sensitivity analysis of the model constants and grid resolution was also studied and compared with detailed DNS data. The results highlight the importance of mixing models to correctly handle turbulence/chemistry interactions in supersonic combustion and clearly indicate the proposed model can correctly estimate the subgrid mixing timescale at coarse grids and decline rapidly as it tends to DNS limit.