Implicit LES of turbulent, separated flow: wall-mounted hump configuration

Abstract: Direct simulations (ILES) of turbulent, separated flow over the wall-mounted hump configuration is conducted to investigate the physics of separated flows. A chord-based Reynolds number of Rec = 47,500 is set up, with a turbulent inflow of Re θ = 1,400 (θ/c = 3%). FDL3DI, a code that solves the compressible Navier-Stokes equations using highorder compact-difference scheme and filter, with the standard recycling/rescaling method of turbulence generation, is used. Two different configurations of the upper-wall a… Show more

“…In the flow deceleration region and x/c < 0.1 regions, the simulations agree well with the experiments but overpredict the skin friction coefficient in the favorable pressure gradient region (0.1 < x/c < 0.5). Skin friction prediction in the favorable gradient region was problematic for most of the computational methods (Large Eddy Simulation, 12 Implicit Large Eddy Simulation and Reynolds Averaged Navier-Stokes Simulations, 13 Lattice Boltzmann Method, 14 and see Ref [15] for other CFD methods) that computed the reference case, predicting considerably higher skin friction coefficient. There are Cf anomalies near x/c = -0.1, 0.45, 0.9, and, 1.1.…”

A Numerical and Experimental Investigation of Flow Separation Control over a Wall-Mounted Hump Model

“…In the flow deceleration region and x/c < 0.1 regions, the simulations agree well with the experiments but overpredict the skin friction coefficient in the favorable pressure gradient region (0.1 < x/c < 0.5). Skin friction prediction in the favorable gradient region was problematic for most of the computational methods (Large Eddy Simulation, 12 Implicit Large Eddy Simulation and Reynolds Averaged Navier-Stokes Simulations, 13 Lattice Boltzmann Method, 14 and see Ref [15] for other CFD methods) that computed the reference case, predicting considerably higher skin friction coefficient. There are Cf anomalies near x/c = -0.1, 0.45, 0.9, and, 1.1.…”

A Numerical and Experimental Investigation of Flow Separation Control over a Wall-Mounted Hump Model

“…The LES simulations of You, Wang & Moin 5 yielded good predictions of the reattachment location and Reynolds stresses. Some of the computational studies for this configuration were performed by Saric et al, 6 Morgan et al, 7 Rumsey, 8 Balakumar 9 and Krishnan et al 10 More recent computations include those by Avdis et al, 11 Franck & Colonius, 12 Yeh et al, 13 Sekhar et al, 14 Woodruff, 15 Duda & Fares 16 and Kalsi & Tucker. 17 Park 18 performed WMLES using an equilibrium and non-equilibrium wall model for the same NASA hump configuration and obtained reasonable agreement with experiment.…”

Wall--modeled Large Eddy Simulation of Flow Over a Wall--mounted Hump

Pressure–Rate-of-Strain, Pressure Diffusion, and Velocity–Pressure-Gradient Tensor Measurements in a Cavity Flow