# Stratford's separation criterion

(Difference between revisions)
 Revision as of 18:41, 14 February 2008 (view source)Jola (Talk | contribs)m← Older edit Revision as of 09:50, 11 December 2013 (view source)Jola (Talk | contribs) (Added formula for C'p > 4/7)Newer edit → Line 28: Line 28: *$Re = \frac{U_{max} \cdot x'}{\nu}$ *$Re = \frac{U_{max} \cdot x'}{\nu}$ The Reynolds number above is based on the effective length of the bounday layer $x'$ and the  maximum velocity $U_{max}$ at the start of the recovery. The Reynolds number above is based on the effective length of the bounday layer $x'$ and the  maximum velocity $U_{max}$ at the start of the recovery. + + For $C'_p > \frac{4}{7}$ (velocity ratios $\frac{U_{max}}{U} > 1.53$) Stratford successfully used the following formula to compute $C'_p$: + + $C'_p = 1 - \frac{a}{\sqrt{x' + b}}$, for $C'_p > \frac{4}{7}$ where the constants a and b are chosen so that the slope and value of $C'_p$ match at $C'_p = \frac{4}{7}$ Stratford's separation criteria is known to be conservative. It will most likely predict a bit too early separation. Stratford's separation criteria is known to be conservative. It will most likely predict a bit too early separation. Line 36: Line 40: *{{reference-paper|author=Cebeci, T., Mosinskis, G. J., and Smith A. M. O|year=1972|title=Calculation of Separation Points in Incompressible Turbulent Flows|rest=Journal of Aircraft, Vol. 9., Sept. 1972, p. 618-624}} *{{reference-paper|author=Cebeci, T., Mosinskis, G. J., and Smith A. M. O|year=1972|title=Calculation of Separation Points in Incompressible Turbulent Flows|rest=Journal of Aircraft, Vol. 9., Sept. 1972, p. 618-624}} + + == External Links == + + * http://adg.stanford.edu/aa200b/blayers/turbseparation.html

## Revision as of 09:50, 11 December 2013

Stratford's separation criterion is an old classical analytical way to assess if a turbulent boundary layer is likely to separate or not. Stratford's criteria says that from the start of the pressure recovery where the max velocity and the minimum static pressure is obtained the boundary layer is on the verge of separation when:

$C'_p \cdot \sqrt{x' \frac{dC'_p}{dx}} = k \cdot \left( \frac{Re}{10^6} \right) ^ {0.1}$

This formula is only valid as long as $C'_p < \frac{4}{7}$.

• $C'_p$ is the canonical pressure distribution defined by:
$C'_p = 1 - \left( \frac{U}{U_{max}} \right) ^ 2$
$U$ is the local velocity and $U_{max}$ is the maximum velocity at the start of the pressure recovery.
• $k$ is a constant which Stratford used the following values for:
$k = \begin{cases} 0.35 & \mbox{if } \frac{d^2p}{dx^2} \le 0 \mbox{ (concave recovery)} \\ 0.39 & \mbox{if } \frac{d^2p}{dx^2} > 0 \mbox{ (convex recovery)} \end{cases}$

Other researcers have used other values. Cebeci-Smith for example used $k = 0.5$, which is a bit less conservative than Statford's original values.

• $x'$ is the effective length of the boundary layer. Note that computing $x'$ can be a bit tricky. If the boundary layer is first accelerated up to the start of the recovery and is assumed to be turbulent all the time a turbulent boundary layer can be assumed to have the followig effective length:
$x' = \int_0^{x^{turb}_{rec}} \left( \frac{U}{U_{max}} \right) ^ 3 dx + (x - x^{turb}_{rec})$

Note that this is only valid if the approaching boundary layer can be assumed to be fully turbulent. If the boundary layer is laminar, or undergoes transition, a different approximations needs to be done.

• $Re = \frac{U_{max} \cdot x'}{\nu}$

The Reynolds number above is based on the effective length of the bounday layer $x'$ and the maximum velocity $U_{max}$ at the start of the recovery.

For $C'_p > \frac{4}{7}$ (velocity ratios $\frac{U_{max}}{U} > 1.53$) Stratford successfully used the following formula to compute $C'_p$:

$C'_p = 1 - \frac{a}{\sqrt{x' + b}}$, for $C'_p > \frac{4}{7}$ where the constants a and b are chosen so that the slope and value of $C'_p$ match at $C'_p = \frac{4}{7}$

Stratford's separation criteria is known to be conservative. It will most likely predict a bit too early separation.

## References

• Stratford, B. S. (1959), "The Prediction of Separation of the Turbulent Boundary Layer", Journal of Fluid Mechanics, Vol. 5, pp. 1-16.
• Cebeci, T., Mosinskis, G. J., and Smith A. M. O (1972), "Calculation of Separation Points in Incompressible Turbulent Flows", Journal of Aircraft, Vol. 9., Sept. 1972, p. 618-624.