Dynamic Stability Of Stiffened Laminated Composite Plates And Shells Subjected To In-Plane Pulsating Forces

Abstract The dynamic stability of laminated composite stiffened or non-stiffened plates and shells due to periodic in-plane forces at boundaries is investigated in this paper. The 3-D degenerated shell element and 3-D degenerated curved beam element are used to model plates/shells and stiffeners, respectively. The characteristic equations for the natural frequencies, buckling loads and their corresponding mode shapes are obtained from the finite element equations of motion. Then, the method of Hill's infinite determinants or the method of multiple scales is applied to analyze the dynamic instability regions. Numerical results are presented to demonstrate the effects of various parameters, such as skew angle, lamination scheme, stiffening scheme, in-plane force type and the curvature of the cylindrical shells, on the dynamic stability of stiffened and non-stiffened plates and shells subjected to in-plane pulsating forces at boundaries.