Vibration and Buckling Characteristics of Composite Cylindrical Panels Incorporating the Effects of a Higher Order Shear Theory

Abstract

An analytical study is conducted to determine the fundamental frequencies and critical buckling loads for laminated anisotropic circular cylindrical shell panels, including the effects of transverse shear deformation and rotary inertia, by using the Galerkin Technique. A linearized form of Sander's shell strain-displacement relations are derived, which include a parabolic distribution of transverse shear strains. The theory is valid for laminate thickness to radius ratios, h/R, of 1/5. Higher order constitutive relations are derived for the laminate. A set of five coupled partial differential equations of motion and boundary conditions are derived and then solved using the Galerkin Technique. Simply supported and clamped boundary conditions are investigated. It is found that the Galerkin Technique converges for all panel configurations investigated; additionally, it is found that buckling problems need more terms in the approximation than vibration problems to obtain proper convergence. Theory compares exactly with the Donnel solutions, which are valid up to h/R = 1/50. As expected, as length to thickness ratios are reduced shear deformation effects significantly lower the natural frequencies and buckling loads. Analysis also shows that rotary inertia effects are very small. Finally, as h/R is varied from 0 (flat plate) to 1/5 (maximum limit), the frequencies and buckling loads increase due to membrane and bending coupling. Theses.

Document Details

Document Type

Technical Report

Publication Date

Dec 01, 1988

Accession Number

ADA202939

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