High Schmidt mass transfer in a turbulent impinging slot–jet flow

The flow field due to an impinging jet over a moving surface at a moderately high Reynolds number, emanating from a rectangular slot nozzle has been computed using the large eddy simulation technique. A dynamic subgrid-scale stress model has been used for the small scales of turbulence. The velocity

## Abstract Exact solutions of the boundary layer equations were used to calculate the local mass transfer coefficients for an impinging jet with a parabolic velocity distribution. Boundary conditions were obtained from an inviscid flow solution and also from experimental pressure distributions. Ex

I t has been shown previously that the first four of these derivatives are not numerically equal (Navari et al., 1971; Bryant and Navari, 1974), which leads to the conclusion that Equations (7) and ( ) are, in turn, not equivalent. A recent paper compares diffusion data by stating that af5/8A) a,p,

The ¯ow ®eld due to an impinging jet at a moderately high Reynolds number, emanating from a rectangular slot nozzle has been computed using a large eddy simulation (LES) technique. A dynamic subgrid-scale stress model has been used for the small scales of turbulence. Quite a few successful applicati