In fluid dynamics, the pressure coefficient is a dimensionless number which describes the relative pressures throughout a flow field. The pressure coefficient is used in aerodynamics and hydrodynamics. Every point in a fluid flow field has its own unique pressure coefficient, .
In many situations in aerodynamics and hydrodynamics, the pressure coefficient at a point near a body is independent of body size. Consequently, an engineering model can be tested in a wind tunnel or water tunnel, pressure coefficients can be determined at critical locations around the model, and these pressure coefficients can be used with confidence to predict the fluid pressure at those critical locations around a full-size aircraft or boat.
The pressure coefficient is a parameter for studying both incompressible/compressible fluids such as water and air. The relationship between the dimensionless coefficient and the dimensional numbers is[1] [2]
Cp={p-pinfty\over
| 1 | |
| 2 |
\rhoinfty
| 2 | |
| V | |
| infty |
}
p
pinfty
\rhoinfty
\rmkg/m3
Vinfty
See main article: Incompressible flow. Using Bernoulli's equation, the pressure coefficient can be further simplified for potential flows (inviscid, and steady):[3]
Cp|M={p-pinfty\overp0-pinfty}={1-(
| u | |
| uinfty |
)2}
where:
u
M
p0
This relationship is valid for the flow of incompressible fluids where variations in speed and pressure are sufficiently small that variations in fluid density can be neglected. This assumption is commonly made in engineering practice when the Mach number is less than about 0.3.
Cp
Cp
Cp
Locations where
Cp=-1
In an incompressible fluid flow field around a body, there will be points having positive pressure coefficients up to one, and negative pressure coefficients including coefficients less than minus one.
See main article: Compressible flow. In the flow of compressible fluids such as air, and particularly the high-speed flow of compressible fluids,
| { | 1 |
| 2 |
\rhov2}
The pressure coefficient
Cp
\Phi
\phi
uinfty
\Phi=uinftyx+\phi(x,y,z)
Using Bernoulli's equation,
| \partial\Phi | |
| \partialt |
+
| \nabla\Phi ⋅ \nabla\Phi | |
| 2 |
+
| \gamma | |
| \gamma-1 |
| p | |
| \rho |
=constant
which can be rewritten as
| \partial\Phi | |
| \partialt |
+
| \nabla\Phi ⋅ \nabla\Phi | |
| 2 |
+
| a2 | |
| \gamma-1 |
=constant
where
a
The pressure coefficient becomes
\begin{align} Cp&=
| p-pinfty | = | |||
|
| 2 | \left[\left( | |
| \gammaM2 |
| a | |
| ainfty |
| ||||
| \right) |
-1\right]\\ &=
| 2 | \left[\left( | |
| \gammaM2 |
| \gamma-1 | ( | |||||
|
| |||||||
| 2 |
-\Phit-
| \nabla\Phi ⋅ \nabla\Phi | |
| 2 |
)+
| ||||
| 1\right) |
-1\right]\\ & ≈
| 2 | |
| \gammaM2 |
\left[\left(1-
| \gamma-1 | ||||||
|
(\phit+uinfty\phix
| ||||
| )\right) |
-1\right]\\ & ≈ -
| 2\phit | ||||||
|
-
| 2\phix | |
| uinfty |
\end{align}
where
ainfty
The classical piston theory is a powerful aerodynamic tool. From the use of the momentum equation and the assumption of isentropic perturbations, one obtains the following basic piston theory formula for the surface pressure:
p=pinfty\left(1+
| \gamma-1 | |
| 2 |
| w | |
| a |
| ||||
| \right) |
where
w
a
Cp=
| p-pinfty | ||||
|
=
| 2 | |
| \gammaM2 |
\left[\left(1+
| \gamma-1 | |
| 2 |
| w | |
| a |
| ||||
| \right) |
-1\right]
The surface is defined as
F(x,y,z,t)=z-f(x,y,t)=0
The slip velocity boundary condition leads to
| \nablaF | |
| |\nablaF| |
(uinfty+\phix,\phiy,\phiz)=Vwall ⋅
| \nablaF | |
| |\nablaF| |
=-
| \partialF | |
| \partialt |
| 1 | |
| |\nablaF| |
The downwash speed
w
w=
| \partialf | |
| \partialt |
+uinfty
| \partialf | |
| \partialx |
See main article: Hypersonic speed. In hypersonic flow, the pressure coefficient can be accurately calculated for a vehicle using Newton's corpuscular theory of fluid motion, which is inaccurate for low-speed flow and relies on three assumptions:[5]
For a freestream velocity
Vinfty
A
\theta
Vinfty\sin\theta
\rhoinftyVinftyA\sin\theta
\rhoinfty
F
F=(\rhoinftyVinftyA\sin\theta)(Vinfty\sin\theta)=\rhoinfty
| 2 | |
| V | |
| infty |
A\sin2\theta
Dividing by the surface area, it is clear that the force per unit area is equal to the pressure difference between the surface pressure
p
pinfty
| F | |
| A |
=p-pinfty=\rhoinfty
| 2 | |
| V | |
| infty |
\sin2\theta\implies
| p-pinfty | |||||||||||
|
=2\sin2\theta
The last equation may be identified as the pressure coefficient, meaning that Newtonian theory predicts that the pressure coefficient in hypersonic flow is:
Cp=2\sin2\theta
For very high speed flows, and vehicles with sharp surfaces, the Newtonian theory works very well.
A modification to the Newtonian theory, specifically for blunt bodies, was proposed by Lester Lees:[6]
Cp=Cp,max\sin2\theta
where
Cp,max
Cp,max=
| po-pinfty | |||||||||||
|
=
| pinfty | ||||||||||
|
\left(
| po | |
| pinfty |
-1\right)=
| 2 | ||||||||
|
\left(
| po | |
| pinfty |
-1\right)
where
po
\gamma
p=\rhoRT
M=V/a
a=\sqrt{\gammaRT}
| po | |
| pinfty |
=\left[
| |||||||||||||
|
\right]\gamma/(\gamma-1)\left[
| ||||||||||
| \gamma+1 |
\right]
Therefore, it follows that the maximum pressure coefficient for the Modified Newtonian law is:
Cp,max=
| 2 | ||||||||
|
\left\{\left[
| |||||||||||||
|
\right]\gamma/(\gamma-1)\left[
| ||||||||||
| \gamma+1 |
\right]-1\right\}
In the limit when
Minfty → infty
Cp,max=\left[
| (\gamma+1)2 | |
| 4\gamma |
\right]\gamma/(\gamma-1)\left(
| 4 | |
| \gamma+1 |
\right)
And as
\gamma → 1
Cp,max=2
An airfoil at a given angle of attack will have what is called a pressure distribution. This pressure distribution is simply the pressure at all points around an airfoil. Typically, graphs of these distributions are drawn so that negative numbers are higher on the graph, as the
Cp
All the three aerodynamic coefficients are integrals of the pressure coefficient curve along the chord.The coefficient of lift for a two-dimensional airfoil section with strictly horizontal surfaces can be calculated from the coefficient of pressure distribution by integration, or calculating the area between the lines on the distribution. This expression is not suitable for direct numeric integration using the panel method of lift approximation, as it does not take into account the direction of pressure-induced lift. This equation is true only for zero angle of attack.
| C | ||||
|
| xTE | |
| \int\limits | |
| xLE |
| \left(C | |
| pl |
| (x)-C | |
| pu |
(x)\right)dx
where:
| C | |
| pl |
| C | |
| pu |
xLE
xTE
When the lower surface
Cp