The evolution of initially uniform shear flow through a nearly two-dimensional 900 curved duct

Abstract

An experimental study has been made in a nearly two-dimensional 90 degrees curved duct to investigate the effects of interaction between streamline curvature and mean strain on the evolution of turbulence. The initial uniform shear at the entrance to the curved duct was varied by an upstream shear generator to produce five different shear conditions; a uniform flow (UF), a positive weak shear (PW), a positive strong shear (PS), a negative weak shear (NW) and a negative strong shear (NS). The variations of surface pressure and the mean velocity profiles along the downstream direction under different initial shears are carefully measured. The responses of turbulent Reynolds stresses and triple velocity products to the curvature and the mean strain are also investigated. The evolution of turbulence under the curvature with the different shear conditions is described in terms of the turbulent kinetic energy and the various length scales vs the angular distance a or a curvature parameters S-c which is defined by S-c = (U/R)/(dU/dy - U/R). The results show that the turbulent kinetic energy and the integral length scale are augmented when S-c < 0.054 whereas they are suppressed when S-c > 0.054. It is also observed that the micro-length scales of Taylor and Kolmogoroff are relatively insensitive to the curvature.