Dynamic Analysis of Three-Dimensional Composite Tube Shafts

TL;DR: In this paper, the in-plane elastic properties at different fiber volume fractions of 3D composite tube shafts are obtained from the literature and modal analysis is carried out, and bending natural frequencies are calculated for different 3D composites with E-glass, carbon and kevlar fibers and epoxy as matrix materials.

Abstract: Three-dimensional (3D) composites have good delamination resistance along with high specific stiffness and high specific strength. Composite tube shafts are modeled with different reinforcement architecture such as multi-axial, stitched, knitted, braided, orthogonal woven, interlock and z-pinned. The in-plane elastic properties at different fiber volume fractions of these composites are obtained from the literature. 3D composite tube shafts are modeled with length: 1 m, internal radius: 25 mm and thickness: 4 mm using modified equivalent modulus beam theory formulation. Modal analysis is carried out, and bending natural frequencies are calculated for different 3D composite tube shafts with E-glass, carbon and kevlar fibers and epoxy as matrix materials. The natural frequency reduces with through thickness reinforcement for orthogonal, knitted, z-pinned and stitched composites. Braided composites tube shafts have higher natural frequencies compared to that of other types.