Abstract
This work demonstrates the potential of manufacturing variable-angle composite cylinders via filament winding (FW), called VAFW. The proposed design strategy allows different filament angles along the axial direction by dividing the cylinder into regions of constant angle called frames. Designs using two, four, or eight frames are herein investigated. A genetic algorithm is applied to optimize each design for maximum axial buckling load. A design with minimum manufacturable filament angle is included in the study. All structures are manufactured and tested under axial compression, with displacements and strains measured by digital image correlation (DIC). The thickness and mid-surface imperfections of the different designs are measured through DIC and used to explain the observed buckling mechanisms. These imperfections are incorporated into a nonlinear numerical model along with a progressive damage analysis. Additionally, a scaling factor is applied on the measured imperfections to enable an imperfection sensitivity study on the proposed designs. The VAFW design shows buckling strength, stiffness, and absorbed energy substantially higher than the constant-angle configuration, attributed to tailored thickness buildup and optimized tow steered angles at particular regions of the cylinder. The experimental and numerical results indicate that VAFW designs can be tailored to postpone buckling so that the material strength can be better exploited. • Innovative manufacturing of Variable-Angle cylinders via Filament Winding: VAFW. • Displacement and strain maps of the VAFW cylinders via DIC. • Optimization using genetic algorithm successfully applied to VAFW cylinders. • Experimental measurement of thickness imperfections for each cylinder design. • Damage modeling with experimental imperfections incorporated in nonlinear FE models.
Highlights
Filament winding (FW) is one of the most suitable manufacturing processes for fiber-reinforced solids of revolution [1], such as composite overwrapped pressure vessels [2,3], tubes [4], pipelines [5,6], drive shafts [7], among others
Hao et al [19,20,21] developed integrated optimization frameworks based on isogeometric analysis for VS panels, providing an efficient numerical framework based on the isoparametric concept, which is similar to the finite element (FE) analysis and meshless method
Variable-angle cylinders were manufactured for the first time through filament winding process
Summary
Filament winding (FW) is one of the most suitable manufacturing processes for fiber-reinforced solids of revolution [1], such as composite overwrapped pressure vessels [2,3], tubes [4], pipelines [5,6], drive shafts [7], among others. Hao et al [19,20,21] developed integrated optimization frameworks based on isogeometric analysis for VS panels, providing an efficient numerical framework based on the isoparametric concept, which is similar to the finite element (FE) analysis and meshless method. They utilized non-uniform rational B-spline (NURBS) basis functions to discretize the geometric model. They developed efficient and reliable optimization frameworks at reasonable computational cost, whilst robust enough to generate complex fiber paths, which is hardly possible to reach in a single optimization step using gradient-based methods
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
