Jay H. Robinson scite author profile

Jay H. Robinson

5Publications

84Citation Statements Received

44Citation Statements Given

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Affiliations

Langley Research Center, Old Dominion University

Publications

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Sound transmission through a cylindrical sandwich shell with honeycomb core

Tang

Robinson

Silcox

1996

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Sound transmission through an infinite cylindrical sandwich shell is studied in the context of the transmission of airborne sound into aircraft interiors. The cylindrical shell is immersed in fluid media and excited by an oblique incident plane sound wave. The internal and external fluids are different and there is uniform airflow in the external fluid medium. An explicit expression of transmission loss is derived in terms of modal impedance of the fluids and the shell. The results show the effects of (a) the incident angles of the plane wave; (b) the flight conditions of Mach number and altitude of the aircraft; (c) the ratios between the core thickness and the total thickness of the shell; and (d) the structural loss factors on the transmission loss. Comparisons of the transmission loss are made among different shell constructions and different shell theories.

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Sound transmission through cylindrical shell structures excited by boundary layer pressure fluctuations

Tang

Silcox

Robinson

1996

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This paper examines sound transmission into two concentric cylindrical sandwich shells subject to turbulent flow on the exterior surface of the outer shell. The interior of the shells is filled with fluid medium and there is an airgap between the shells in the annular space. The description of the pressure field is based on the cross-spectral density formulation of Corcos, Maestrello, and Efimtsov models of the turbulent boundary layer. The classical thin shell theory and the first-order shear deformation theory are applied for the inner and outer shells, respectively. Modal expansion and the Galerkin approach are used to obtain closed-form solutions for the shell displacements and the radiation and transmission pressures in the cavities including both the annular space and the interior. The average spectral density of the structural responses and the transmitted interior pressures are expressed explicitly in terms of the summation of the cross-spectral density of generalized force induced by the boundary layer turbulence. The effects of acoustic and hydrodynamic coincidences on the spectral density are observed. Numerical examples are presented to illustrate the method for both subsonic and supersonic flows.

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Vibroacoustic model validation for a curved honeycomb composite panel

Buehrle

Robinson

Grosveld

2001

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Finite element and boundary element models are developed to investigate the vibroacoustic response of a curved honeycomb composite sidewall panel. Results from vibroacoustic tests conducted in the NASA Langley Structural Acoustic Loads and Transmission facility are used to validate the numerical predictions. The sidewall panel is constructed from a flexible honeycomb core sandwiched between carbon fiber reinforced composite laminate face sheets. This type of construction is being used in the development of an all-composite aircraft fuselage. In contrast to conventional rib-stiffened aircraft fuselage structures, the composite panel has nominally uniform thickness resulting in a uniform distribution of mass and stiffness. Due to differences in the mass and stiffness distribution, the noise transmission mechanisms for the composite panel are expected to be substantially different from those of a conventional rib-stiffened structure. The development of accurate vibroacoustic models will aide in the understanding of the dominant noise transmission mechanisms and enable optimization studies to be performed that will determine the most beneficial noise control treatments. Finite element and boundary element models of the sidewall panel are described. Vibroacoustic response predictions are presented for forced vibration input and the results are compared with experimental data.

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Large deflection random response of flat and blade stiffened carbon-carbon panels

Robinson

Rizzi

Clevenson

et al. 1992

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Design and Attenuation Properties of Periodic Checkerboard Liners

Watson

Robinson

Jones

et al. 2003

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Jay H. Robinson

Sound transmission through a cylindrical sandwich shell with honeycomb core

Sound transmission through cylindrical shell structures excited by boundary layer pressure fluctuations

Vibroacoustic model validation for a curved honeycomb composite panel

Large deflection random response of flat and blade stiffened carbon-carbon panels

Design and Attenuation Properties of Periodic Checkerboard Liners

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