Investigation of acoustical shielding by a wedge-shaped airframe

• Published in: Journal of sound and vibration Vol. 294; no. 1; pp. 49 - 63
• Main Authors: Gerhold, Carl H., Clark, Lorenzo R., Dunn, Mark H., Tweed, John
• Format: Journal Article
• Language: English
• Published: London Elsevier Ltd 27.06.2006; Elsevier
• Subjects: Acoustics; Aeroacoustics, atmospheric sound; Exact sciences and technology; Fundamental areas of phenomenology (including applications); Physics; Structural acoustics and vibration; Wide band noise; wedge shaped airframe; Far field; Boundary integral method; Inlet flow; Sound source; Background noise; Experimental study; Scale model; Modeling; Scaling law; Shielding effect; Air transportation; Aerofoil; Localization; Aeroacoustics; Aircraft; Spatial resolution; Structural acoustics; Point source
• ISSN: 0022-460X; 1095-8568
• DOI: 10.1016/j.jsv.2005.10.010

Experiments on a scale model of an advanced unconventional subsonic transport concept, the blended wing body (BWB), have demonstrated significant shielding of inlet-radiated noise. A computational model of the shielding mechanism has been developed using a combination of boundary integral equation method (BIEM) for source definition and equivalent source method (ESM) for scattering. In this way the sound fields with and without the airfoil can be estimated for comparison to experiment. An experimental test bed using a simplified wedge-shape airfoil and a broadband point noise source in a simulated nacelle has been developed for the purposes of verifying the analytical model and also to study the effect of engine nacelle placement on shielding. The analytic and experimental results are compared at 6300 and 8000 Hz. These frequencies correspond to approximately 125 and 160 Hz on the full-scale aircraft. Comparison between the experimental and analytic results is quite good, not only for the noise scattering by the airframe, but also for the total sound pressure in the far field. Many of the details of the sound field that the analytic model predicts are seen or indicated in the experiment, within the spatial resolution limitations of the experiment. Changing nacelle location produces comparable changes in noise shielding contours evaluated analytically and experimentally.