In fluid dynamics, Stagnation point flow represents a fluid flow in the immediate neighborhood of solid surface at which fluid approaching the surface divides into different streams or a counterflowing fluid streams encountered in experiments. Although the fluid is stagnant everywhere on the solid surface due to no-slip condition, the name stagnation point refers to the stagnation points of inviscid Euler solutions.
Stagnation point flow with translating plateDrazin, Philip G.">Philip Drazin">Drazin, Philip G., and [Norman Riley]. The Navier–Stokes equations: a classification of flows and exact solutions. No. 334. Cambridge University Press, 2006.
Stagnation point flow with moving plate with constant velocity can be considered as model for rotating solids near the stagnation points. The stream function is where satisfies the equation and Rott gave the solution as
Oblique stagnation point flow
The previous analyses assumes the flow impinges in normal direction. The inviscid stream function for oblique stagnation point flow is obtained by adding a constant vorticity. The corresponding analysis for viscous fluid is studied by Stuart, Tamada and Dorrepaal. The self-similar stream function is, where satisfies the equation
Homann flow
The corresponding problem in axisymmetric coordinate is solved by Homann and this serves a model for flow around near the stagnation point of a sphere. Paul A. Libby considered Homann flow with constantly moving plate with velocity and also allowed for suction/injection with velocity at the surface. The self-similar solution is obtained by introducing following transformation for the velocity in cylindrical coordinates and the pressure is given by Therefore, the Navier–Stokes equations reduce to with boundary conditions, When, the classical Homann problem is recovered.
Plane counterflows
Jets emerging from a slot-jets creates stagnation point in between according to potential theory. The flow near the stagnation point can by studied using self-similar solution. This setup is widely used in combustion experiments. The initial study of impinging stagnation flows are due to C.Y. Wang. Let two fluids with constant properties denoted with suffix flowing from opposite direction impinge and let's assume the two fluids are immiscible and the interface is planar. The velocity is given by where are strain rates of the fluids. At the interface, velocities, tangential stress and pressure must be continuous. Introducing the self-similar transformation, results equations, The no-penetration condition at the interface and free stream condition far away from the stagnation plane become But the equations require two more boundary conditions. At, the tangential velocities, the tangential stress and the pressure are continuous. Therefore, where is used. Both are not known apriori, but derived from matching conditions. The third equation is determine variation of outer pressure due to the effect of viscosity. So there are only two parameters, which governs the flow, which are then the boundary conditions become
Constant density and constant viscosity
When densities and viscosities of the two impinging jets are same and constant, then the strain rate is also constant and the potential flow solution become the solution of the Navier-Stokes equations, i.e., everywhere in the flow domain. Kerr and Dold found additional new solution called as Kerr–Dold vortex of Navier-Stokes equations in 1994 in the form of periodic array of steady vortices superposed on the constant density and constant viscosity counterflowing jets.
