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Study of supersonic flows is of high interest for a wide
variety of problems including design of high speed planes and other related
applications [1]. This user tip presents a validation of numerical methods
against experimental data.
Geometry Definition
The blunted cone-cylinder-flare geometry is presented in Figure 1. This configuration, designated HB-2, has been widely used to evaluate
aerodynamic test facilities and consequently, a large quantity of experimental
data are available [2].
Figure 1. Blunted cone-cylinder-flare (HB-2)
Numerical Model
The geometry is discretized using a structured
mesh. A 2D axisymmetrical model is built in order to reduce the CPU time
requirements. The model contains 13 structured zones. On the solid walls, a
boundary layer mesh has been used. The first element size close to the wall is
equal to 2.0e-6 m.
The total number of the cells is around 36,400.
Figure 2. 2D axisymmetric model
Numerical Results
The initial and boundary
conditions used for the HB-2 model are the following :
-
adiabatic walls on the solid boundaries,
- symmetry on the axis of symmetry,
- extrapolated exit condition,
- inflow/outflow condition on other outermost surface
bounding the domain.
| ReD |
2.32E6 |
|
| M |
5
|
|
| V |
1000
|
m/s
|
| T |
99.55
|
K
|
p
|
1142.86
|
Pa
|
| r |
0.04 |
kg/m3
|
| d |
1
|
m
|
R
|
287
|
J/kg-K
|
where ReD is the Reynolds number, M is the Mach number, V is the velocity, T is the temperature, p is the pressure, r is the density, d is the diameter, and R is the specific gas constant.
The simulation is done using the structured solver of CFD-FASTRAN. The
Roe’s upwinding differencing scheme with min mod limiter is used. Steady state
solution is obtained using the Point Jacobi fully implicit scheme. For the
spatial discretization, high order numerical scheme is used. In Figure 3 we
present the Mach number. The detached bow shock in front of the obstacle is
well captured.
Figure 3. Mach number on HB-2 model
The ratio between the static pressure on the wall and the pressure from
the stagnation point function of x/L is represented in Figure 4.
Figure 4. Comparison: Experiment (red) / CFD-FASTRAN (black)
Regarding the drag coefficient for HB-2 model, reference [3] presents
the forbody axial-force coefficient (CA) and the base axial force
coefficient (CAb). The total axial force coefficient (CAt)
is defined as :
CAt = total axial force / qinf
A
| |
Experiment |
CFD-FASTRAN |
| CAt |
0.71 |
0.68
|
The comparison between numerical prediction and experimental measurements
is good.
Regards,
Daniel Vinteler
CFD Support Manager - France
REFERENCES
- CFD-FASTRAN,
Demo/Validation Manual, version 2004
-
Birch, T.J.,
Prince, S.A., Ludlow,
D.K., Qin, N., “The application of
parabolized Navier-Stokes solver to some hypersonic flow problems”, AIAA
2001-1753
- Don Gray,
J., Earl Lindsay, E., “Force Tests of
Standard Hypervelocity Ballistic Models HB-1 and HB-2 at Mach 1.5 to 10 ” , NTIS, AD412651
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