Propagating structures in wall-bounded turbulent flows

An adjoint optimization method is utilized to design an inviscid outer wall shape required for a turbulent ¯ow ®eld solution of the So±Mellor convex curved wall experiment using the Navier±Stokes equations. The associated cost function is the desired pressure distribution on the inner wall. Using th

The performance of Reynolds stress transport (RST) models in non-equilibrium ¯ows is limited by the lack of information about two dynamically important eects: the role of energy-containing turbulence structure (dimensionality) and the breaking of re¯ectional symmetry due to strong mean or frame rota

A low-Reynolds-number second-moment closure without wall-re¯ection redistribution terms is tested in wall-bounded turbulent ¯ows with streamline curvature. The turbulence model was previously shown to give good predictions for a fully developed channel ¯ow, boundary layers in zero, adverse and favor

A nonlinear stress±strain model, derived from the modeled Reynolds stress transport equation, is modi®ed to account for the near wall eects in wall-bounded turbulent ¯ows. Since it is known that wall re¯ection of the turbulent pressure ®eld modi®es the pressure±strain correlation, the approach taken

ding in the other two. This technique permits a fine grid to be embedded near the wall without placing a large A B-spline based numerical method on a zonal embedded grid has been developed. The method is aimed at reducing the computa-number of grid points in the outer layers. As a result, the tional