Numerical experiments in two dimensions are carried out in order to investigate the response of a typical aircraft structure to a mean flow and an acoustic excitation. Two physical problems are considered; one in which the acoustic excitation is applied on one side of the flexible structure and the mean flow is on the other side while in the second problem both the mean flow and acoustic excitation are on the same side. Subsonic and supersonic mean flows are considered together with a random and harmonic acoustic excitation. In the first physical problem and using a random acoustic excitation, the results show that at low excitation levels the response is unaffected by the mean flow Mach number. However, at high excitation levels the structural response is significantly reduced by increasing the Mach number. In particular, both the shift in the frequency response spectrum and the broadening of the peaks are reduced. In the second physical problem, the results show that the response spectrum is dominated by the lower modes (1 and 3) for the subsonic mean flow case and by the higher modes (5 and 7) in the supersonic case. When a harmonic excitation is used, it is found that in the subsonic case the power spectral density of the structural response shows a subharmonic (f/4) while in the supersonic case no subharmonic is obtained.

Issue Section:
Research Papers
Topics:
Acoustics, Excitation, Flow (Dynamics), Radiation (Physics), Mach number, Aircraft, Dimensions, Flexible structures, Frequency response, Spectral energy distribution
1.
Frendi
A.
,
Maestrello
L.
, and
Bayliss
A.
, “
On the Coupling Between a Supersonic Boundary Layer and a Flexible Surface
,”
AIAA Journal
, Vol.
31
, No.
4
, 1993, pp.
708
713
.
2.
Dowling
A. P.
, “
Flow-Acoustic Interaction Near a Flexible Wall
,”
Journal of Fluid Mechanics
, Vol.
128
, 1983, pp.
181
198
.
3.
Dowling, A. P., “Mean Flow Effects on the Low-Wavenumber Pressure Spectrum on a Flexible Surface,” ASME Winter Annual Meeting, December 9–14, 1984.
4.
Haj-Hariri
H.
, and
Akylas
T. R.
, “
Mean Flow Effects on Low-Wavenumber Wall-Pressure Spectrum of a Turbulent Boundary Layer Over a Compliant Surface
,”
Journal of Acoustical Society of America
, Vol.
77
, No.
5
, 1985, pp.
1840
1844
.
5.
Lekoudis
S. G.
, and
Sengupta
T. K.
, “
Two Dimensional Turbulent Boundary Layers Over Rigid and Moving Swept Wavy Surfaces
,”
Physics of Fluids
, Vol.
29
, No.
4
, 1986, pp.
964
970
.
6.
Maestrello
L.
, “
Radiation From and Panel Response to a Supersonic Turbulent Boundary Layer
,”
Journal of Sound and Vibration
, Vol.
10
, No.
2
, 1969, pp.
261
295
.
7.
Mei
C.
, and
Prasad
C. B.
, “
Effects of Nonlinear Damping on Random Response of Beams to Acoustic Loading
,”
Journal of Sound and Vibration
, Vol.
117
, No.
1
, 1987, pp.
173
186
.
8.
Dowell
E. H.
, and
Pezeshki
C.
, “
On the Understanding of Chaos in Duffings Equation Including a Comparison with Experiment
,”
ASME Journal of Applied Mechanics
, Vol.
53
, No.
1
, 1986, pp.
5
9
.
9.
Reinhall
P. G.
, and
Miles
R. N.
, “
Effect of Damping and Stiffness on the Random Vibration of Nonlinear Periodic Plates
,”
Journal of Sound and Vibration
, Vol.
131
, No.
1
, 1989, pp.
33
42
.
10.
Robinson, J., Rizzi, S., Clevenson, S., and Daniels, E., “Large Deflection Random Response of Flat and Blade Stiffened Carbon-Carbon Panels,” AIAA paper 92–2390, May 1992.
11.
Frendi
A.
, and
Robinson
J.
, “
Effect of Acoustic Coupling on Random and Harmonic Plate Vibrations
,”
AIAA Journal
, Vol.
31
, No.
11
, 1993, pp.
1992
1997
.
12.
Frendi
A.
,
Maestrello
L.
, and
Bayliss
A.
, “
Coupling Between Plate Vibration and Acoustic Radiation
,”
Journal of Sound and Vibration
,
177
, No.
2
,
1994
, pp.
207
226
.
13.
Lyle, K. H., and Dowell, E. H., “Acoustic Radiation Damping of Flat Rectangular Plates Subjected to Subsonic Flows,” submitted to the Journal of Fluid and Structure.
14.
Atalla, N., Sgard, F., and Nicolas, J., “Effects of Mean Flow on the Vibroacoustic Behavior of a Plate-Backed Cavity,” AIAA paper 93–4381, October 1993.
15.
Gottlieb
D.
, and
Turkel
E.
, “
Dissipative Two-Four Methods for Time Dependent Problems
,”
Mathematics of Computation
, Vol.
30
, No.
136
, 1976, pp.
703
723
.
16.
Bayhss, A., Parikh, P., Maestrello, L., and Turkel, E., “A Fourth Order Scheme for the Unsteady Compressible Navier-Stokes Equations,” AIAA paper 85–1694, July 1985.
17.
Abarbanel, S. S., Don, W. S., Gottlieb, D., Rudy, D. H., and Townsend, J. C., “Secondary Frequencies in the Wake of a Cylinder with Vortex Shedding,” Inst. for Comp. Appl. in Sci. and Eng. Report 90–16.
18.
International Mathematical and Statistical Library, version 2.0, Vol. 3, Houston, TX, 1991, p. 1317.
19.
Givoli
D.
, “
Non-Reflecting Boundary Conditions
,”
Journal of Computational Physics
, Vol.
94
, No.
1
, 1991, pp.
1
29
.
20.
Hoff
C.
, and
Pahl
P. J.
, “
Development of an Implicit Method with Numerical Dissipation From a Generalized Single-Step Algorithm for Structural Dynamics
,”
Comp. Meth. in Appl. Mech. Eng.
, Vol.
67
, No.
2
, 1988, pp.
367
385
.
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