Vibrations of Rotating Circular Cylindrical Shells With Varying Thickness

Free vibrations of thick rotating cross-ply laminated composite cylindrical shells are studied based on the "rst order shear deformation shell theory (FSDT). The governing equations of "ve degrees of freedom with consideration of Coriolis accelerations and rotary inertias are established. Analytical

The general equations of the vibrations of high speed rotating shells of revolution, with consideration of Coriolis accelerations and large deformations, are established by the method of linear approximation. In the general case, there are great difficulties in obtaining analytical solutions of the

By using a C0 continuous, QUAD-4 shear flexible shell element, based on the field consistency principle, the non-linear free flexural vibrations of thin circular cylindrical shells have been studied. The formulation is general in the sense that it includes anisotropy, transverse shear deformation, i

A two-dimensional higher-order shell theory is applied to the free vibration problems of a simply supported cylindrical shell subjected to axial stresses. The effects of higher-order deformations such as shear deformations with thickness changes and rotatory inertia on natural frequencies of a thick

The problems of the vibration of rotating cylindrical shells are solved by using nine-node super-parametric "nite element with shear and axial deformation and rotatory inertial. The non-linear plate-shell theory for large de#ection is used to handle the cylindrical shell before it reaches equilibriu