The finite and boundary element modeling of the curved section of a composite honeycomb aircraft fuselage sidewall was validated for both structural response and acoustic radiation. The curved panel was modeled in the pre-processor MSC/PATRAN. Geometry models of the curved panel were constructed based on the physical dimensions of the test article. Material properties were obtained from the panel manufacturer. Finite element models were developed to predict the modal parameters for free and supported panel boundary conditions up to a frequency of 600 Hz. Free boundary conditions were simulated by providing soft foam support under the four corners of the panel or by suspending the panel from elastic bands. Supported boundary conditions were obtained by clamping the panel between plastic tubing seated in grooves along the perimeter of a stiff and heavy frame. The frame was installed in the transmission loss window of the Structural Acoustic Loads and Transmission (SALT) facility at NASA Langley Research Center. The structural response of the curved panel due to point force excitation was predicted using MSC/NASTRAN and the radiated sound was computed with COMET/Acoustics. The predictions were compared with the results from experimental modal surveys and forced response tests on the fuselage panel. The finite element models were refined and updated to provide optimum comparison with the measured modal data. Excellent agreement was obtained between the numerical and experimental modal data for the free as well as for the supported boundary conditions. Frequency response functions (FRF) were computed relating the input force excitation at one panel location to the surface acceleration response at five panel locations. Frequency response functions were measured at the same locations on the test specimen and were compared with the calculated FRF values. Good agreement was obtained for the real and imaginary parts of the transfer functions when modal participation was allowed up to 3000 Hz. The validated finite element model was used to predict the surface velocities due to the point force excitation. Good agreement was obtained between the spatial characteristics of the predicted and measured surface velocities. The measured velocity data were input into the acoustic boundary element code to compute the sound radiated by the panel. The predicted sound pressure levels in the far-field of the panel agreed well with the sound pressure levels measured at the same location.
[1]
S Pappa Richard,et al.
Finite Element Model Development and Validation for Aircraft Fuselage Structures
,
2000
.
[2]
Richard S. Pappa,et al.
Finite Element Model Development For Aircraft Fuselage Structures
,
2000
.
[3]
Gary A. Fleming,et al.
Modal analysis of an aircraft fuselage panel using experimental and finite-element techniques
,
1998,
Other Conferences.
[4]
Ferdinand Grosveld.
Structural normal mode analysis of the Aluminum Testbed Cylinder (ATC)
,
1998
.
[5]
I Pritchard Jocelyn,et al.
Vibro-Acoustics Modal Testing at NASA Langley Research Center
,
1999
.
[6]
A Cunefare Kenneth,et al.
A Tool for Design Minimization of Aircraft Interior Noise
,
1996
.
[7]
Christian M. Fernholz,et al.
AN INVESTIGATION OF THE INFLUENCE OF COMPOSITE LAMINATION ANGLE ON THE INTERIOR NOISE LEVELS OF A BEECH STARSHIP.
,
1996
.
[8]
Ralph D. Buehrle,et al.
Vibroacoustic Model Validation for a Curved Honeycomb Composite Panel
,
2001
.
[9]
Ferdinand W. Grosveld,et al.
Numerical Comparison of Active Acoustic and Structural Noise Control in a Stiffened Double Wall Cylinder
,
1996
.
[10]
Ferdinand W. Grosveld,et al.
Sound transmission loss of integrally damped, curved panels
,
1989
.