Lattice Boltzmann wall boundary conditions for RANS-based simulations with wall functions
Abstract
In this study, we investigate wall boundary condition schemes for Lattice Boltzmann simulations of turbulent flows modeled using RANS equations with wall functions. Two alternative schemes are formulated and assessed: a hybrid regularized boundary condition and a slip-velocity bounce-back scheme. Their performance is evaluated using two canonical turbulent flow cases, a fully developed channel flow and a zero-pressure-gradient flat plate boundary layer (BL), selected specifically to isolate and analyze the impact of wall boundary condition treatments on turbulence modeling. The comparative analysis reveals that the slip-velocity bounce-back approach, which has received relatively little attention within the context of LBM-RANS with wall functions, consistently outperforms the regularized-based method in terms of both accuracy and sensitivity to mesh resolution. Moreover, the regularized-based approach is shown to be highly sensitive to the reconstruction of the wall-normal velocity gradient, even in simple geometries such as flat walls where no interpolation is required. This dependency necessitates the use of specialized, ad-hoc gradient reconstruction techniques, requirements that are not present in the slip-velocity bounce-back method.