In fluid dynamics, stagnation pressure is the static pressure at a stagnation point in a fluid flow.[1] At a stagnation point the fluid velocity is zero. In an incompressible flow, stagnation pressure is equal to the sum of the free-stream static pressure and the free-stream dynamic pressure.[2]
Stagnation pressure is sometimes referred to as pitot pressure because the two pressures are numerically equal.
The magnitude of stagnation pressure can be derived from Bernoulli equation[3] [1] for incompressible flow and no height changes. For any two points 1 and 2:
P1+\tfrac{1}{2}\rho
| 2 | |
| v | |
| 1 |
=P2+\tfrac{1}{2}\rho
| 2 | |
| v | |
| 2 |
The two points of interest are 1) in the freestream flow at relative speed
v
v
Then
Pstatic+\tfrac{1}{2}\rhov2=Pstagnation+\tfrac{1}{2}\rho(0)2
or[4]
Pstagnation=Pstatic+\tfrac{1}{2}\rhov2
where:
Pstagnation
\rho
v
Pstatic
So the stagnation pressure is increased over the static pressure, by the amount
\tfrac{1}{2}\rhov2
In compressible flow however, the fluid density is higher at the stagnation point than at the static point. Therefore,
\tfrac{1}{2}\rhov2
Stagnation pressure is the static pressure a gas retains when brought to rest isentropically from Mach number M.[6]
| pt | |
| p |
=\left(1+
| \gamma-1 | |
| 2 |
M2\right)
| ||||
or, assuming an isentropic process, the stagnation pressure can be calculated from the ratio of stagnation temperature to static temperature:
| pt | |
| p |
=\left(
| Tt | |
| T |
| ||||
| \right) |
where:
pt
p
Tt
T
\gamma
The above derivation holds only for the case when the gas is assumed to be calorically perfect (specific heats and the ratio of the specific heats
\gamma