Research on Vibro-Acoustic Characteristics of Underwater Finite Plate-Shell Structure under Multiple Excitations

Yong Yong Zhu

doi:10.4028/www.scientific.net/AMR.834-836.1351

Paper Titles

Double Laplace Transform Computing Dynamic Response of the Large Thickness to Span Ratio Beam
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Finite Element Method for Solving Bucking Load of Semi-Rigid Steel Frame
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Computation of Dynamic Stress Intensity Factor by Direct Integral Boundary Element Method
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Analysis and Simulation on Vehicle Rollover Dynamic Driving on Curving Path
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Research on Vibro-Acoustic Characteristics of Underwater Finite Plate-Shell Structure under Multiple Excitations
p.1351

Grinding Wheel Dynamic Balance Weight Type System Based on the Self-Optimal Fuzzy Control
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The Design of Hydraulic Cylinder for Measuring the Contact Stress of the Bud Type Seal Ring
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Mechanical Analysis on the Scour of Submarine Pipeline
p.1369

The Pressure Performance of a Slide-Style Multianvil Large Volume Press
p.1373

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Research on Vibro-Acoustic Characteristics of Underwater Finite Plate-Shell Structure under Multiple Excitations

Abstract:

An analysis based on the first kind of Lagranges equations was presented for investigating the vibration and acoustic radiation of underwater finite cylindrical shell with interior plate under multiple excitations. The strain energy and kinetic energy of cylinder and plate were gained by the theory of plates and shells, and the potential energy of excitation and fluid loading was found based on acoustic-vibration coupling, and the connection conditions of plate and cylinder were expressed by Lagrange multipliers, then the vibro-acoustic equations of finite cylinder with interior plate under shafting excitation were established. The influences of excitations and plates position to the vibro-acoustic characteristics were studied by the equations. The results show that the frequency components of plate-shell structure are more complex. For the double excitations on plate, the distance between excitations is larger, the average velocity and sound radiation power are lower, while the radiation efficiency is larger. The modeling and analytical methods adopted in this paper are also available for more complex composite structure.