Effect of boundary condition and variable shell thickness on the vibration behavior of grid-stiffened composite conical shells

In this research, it is aimed to investigate the effect of boundary condition and variable shell thickness on the vibration behavior of grid-stiffened composite conical shells. In order to fabricate the stiffeners and shell for the experimental study, continuous and woven glass fibers have been used during a filament winding process, respectively. Due to the non-uniform distribution of the stiffeners in a stiffened conical shell, the equivalent thickness varies along the longitudinal axis. The stiffener and shell structures have been reduced into an equivalent shell using smeared method. The governing equations have been solved in order to evaluate the natural frequencies of the grid-stiffened conical shell by the use of first-shear deformation theory (FSDT) along with the power series method. In order to validate the analytical solutions, an experimental modal analysis have been carried out on a real grid-stiffened composite conical shell with uniform shell thickness. In addition, the finite element solution has been provided for further validations. Furthermore, the effects of various geometric parameters, variable shell thickness and boundary conditions have been discussed. (c) 2021 Elsevier Ltd. All rights reserved.

Automated summary

The research aims to investigate the impact of boundary condition and variable shell thickness on the vibration behavior of grid-stiffened composite conical shells. Experimental and numerical analyses were conducted to explore the effects of various parameters on the shell's vibration.