A layer-wise analysis for free vibration of thick composite cylindrical shells

System loss factors corresponding to various shell modes have been evaluated by using a complex modulus approach. The damped free vibrations of composite cylindrical shells have been analyzed by using a first order shear deformation theory, in which one assumes a uniform distribution of the transver

The free vibration and the effect of material damping on damping factors are analyzed. An improved shell theory with shear deformation and rotatory inertia has been used, together with a semi-analytical higher order sub-parametric finite element with five nodes per element and 25 degrees of freedom.

A finite element analysis for the free vibration behaviour of point supported laminated composite cylindrical shells is presented. Eight-noded curved quadrilateral isoparametric elements are used. The formulation is based on the assumptions of the first order shear deformation theory for thin, shall

A two-noded finite element is presented for the analysis of thick orthotropic layered shells of revolution based on the discrete layer theory. The effects of transverse shear deformation and rotary inertia are taken into consideration. A piece-wise linear variation of the in-plane displacements acro

The work presented here is concerned with the free vibration analysis of cylindrical storage tanks with axial thickness variation and partially filled with fluid. The tank is modelled using Flügge's thin shell theory and the fluid in the tank is assumed to be inviscid and imcompressible, governed by

An investigation is described of the free vibration characteristics, i.e., natural frequencies and damping ratios in flexural modes of cylindrical tubes made from fibre reinforced materials with potential usage as composite shafts. This paper is concerned with only the first circumferential modes, w