In fluid dynamics, the Falkner–Skan boundary layer (named after V. M. Falkner and Sylvia W. Skan[1]) describes the steady two-dimensional laminar boundary layer that forms on a wedge, i.e. flows in which the plate is not parallel to the flow. It is also representative of flow on a flat plate with an imposed pressure gradient along the plate length, a situation often encountered in wind tunnel flow. It is a generalization of the flat plate Blasius boundary layer in which the pressure gradient along the plate is zero.
The basis of the Falkner-Skan approach are the Prandtl boundary layer equations. Ludwig Prandtl[2] simplified the equations for fluid flowing along a wall (wedge) by dividing the flow into two areas: one close to the wall dominated by viscosity, and one outside this near-wall boundary layer region where viscosity can be neglected without significant effects on the solution. This means that about half of the terms in the Navier-Stokes equations are negligible in near-wall boundary layer flows (except in a small region near the leading edge of the plate). This reduced set of equations are known as the Prandtl boundary layer equations. For steady incompressible flow with constant viscosity and density, these read:
Mass Continuity:
\dfrac{\partialu}{\partialx}+\dfrac{\partialv}{\partialy}=0
x
u\dfrac{\partialu}{\partialx}+v\dfrac{\partialu}{\partialy}=-\dfrac{1}{\rho}\dfrac{\partialp}{\partialx}+{\nu}\dfrac{\partial2u}{\partialy2}
y
0=-\dfrac{\partialp}{\partialy}
Here the coordinate system is chosen with
x
y
u
v
x
y
p
\rho
\nu
Source:[3]
Falkner and Skan generalized the Blasius boundary layer by considering a wedge with an angle of
\pi\beta/2
U0
-\dfrac{1}{\rho}\dfrac{\partialp}{\partialx}=ue\dfrac{due}{dx} .
ue(x)
Having made the Bernoulli equation substitution, Falkner and Skan pointed out that similarity solutions are obtained when the boundary layer thickness and velocity scaling factors are assumed to be simple power functions of x.[5] That is, they assumed the velocity similarity scaling factor is given by:
ue(x)=U0\left(
| x | |
| L |
\right)m ,
where
L
\delta(x) = \sqrt{
| 2\nuL | |
| U0(m+1) |
Mass conservation is automatically ensured when the Prandtl momentum boundary layer equations are solved using a stream function approach. The stream function, in terms of the scaling factors, is given by:[7]
\psi(x,y) = ue(x)\delta(x)f(η) ,
where
η={y}/{\delta(x)}
u(x,y) =
| {\partial\psi(x,y) | |
This means
\psi(x,y) = \sqrt{
| 2\nuU0L | |
| m+1 |
The non-dimensionalized Prandtl x-momentum equation using the similarity length and velocity scaling factors together with the stream function based velocities results in an equation known as the Falkner–Skan equation and is given by:
f'''+ff''+\beta\left[1-(f')2\right]=0 ,
where each dash represents differentiation with respect to
η
\beta
\alpha
u(x,y)
v(x,y)
\beta
f(0)=f'(0)=0, f'(infty)=1.
The wedge angle, after some manipulation, is given by:
\beta=
| 2m | |
| m+1 |
.
The
m=\beta=0
\beta=1
-0.090429\leqm\leq2 (-0.198838\leq\beta\leq4/3)
With the solution for f and its derivatives in hand, the Falkner and Skan velocities become:[9]
u(x,y)=ue(x)f' ,
v(x,y)=-\sqrt{
| (m+1)\nuU0 | |
| 2L |
\left(
| x | |
| L |
\right)m-1
The Prandtl
y
y
{\partialp}
{\partialy}
\alpha
\beta
| {x2 | |
where the displacement thickness,
\delta1
\delta1(x)=\left(
| 2 | |
| m+1 |
\right)1/2\left(
| \nux | |
| U |
\right)1/2
| infty | |
| \int | |
| 0 |
(1-f')dη
and the shear stress acting at the wedge is given by
\tauw(x)=\mu\left(
| m+1 | |
| 2 |
\right)1/2\left(
| U3 | |
| \nux |
\right)1/2f''(0)
Source:[11]
h
\rho
\mu
\kappa
| \begin{align} | \partial(\rhou) |
| \partialx |
+
| \partial(\rhov) | |
| \partialy |
&=0,\\ \left(u
| \partialu | |
| \partialx |
+v
| \partialu | |
| \partialy |
\right)&=-
| 1 | |
| \rho |
| dp | |
| dx |
+
| 1 | |
| \rho |
| \partial | \left(\mu | |
| \partialy |
| \partialu | |
| \partialy |
\right),\\ \rho\left(u
| \partialh | |
| \partialx |
+v
| \partialh | |
| \partialy |
\right)&=
| \partial | \left( | |
| \partialy |
| \mu | |
| Pr |
| \partialh | |
| \partialy |
\right)\end{align}
where
| Pr=c | |
| pinfty |
\muinfty/\kappainfty
infty
u=v=h-hw(x)=0 for y=0
u-U=h-hinfty=0 for y=infty or x=0
Unlike the incompressible boundary layer, similarity solution can exists for only if the transformation
x → c2x, y → cy, u → u, v →
| v | |
| c |
, h → h, \rho → \rho, \mu → \mu
holds and this is possible only if
hw=constant
Introducing the self-similar variables using Howarth–Dorodnitsyn transformation
η=\sqrt{
| Uo(m+1) | |
| 2\nuinftyLm |
the equations reduce to
\begin{align} (\tilde\rho\tilde\muf'')'+ff''+\beta[\tildeh-(f')2]=0,\\ (\tilde\rho\tilde\mu\tildeh')'+Prf\tildeh'=0\end{align}
The equation can be solved once
\tilde\rho=\tilde\rho(\tildeh), \tilde\mu=\tilde\mu(\tildeh)
f(0)=f'(0)=\theta(0)-\tildehw=f'(infty)-1=\tildeh(infty)-1=0.
The commonly used expressions for air are
\gamma=1.4, Pr=0.7, \tilde\rho=\tildeh-1, \tilde\mu=\tildeh2/3
cp
\tildeh=\tilde\theta=T/Tinfty