Mechanical model and mechanical property analysis of fibre-reinforced hybrid composite pipes

• Published in: Marine structures Vol. 89; p. 103396
• Main Authors: Wang, Li, Ma, Weiguo, Deng, Lin, Liu, Shaohu, Yang, Ting
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.05.2023
• Subjects: Fibre-reinforced hybrid composite pipes; Mechanical model; Mechanical properties; Fibre-reinforced hybrid composite pipes; Mechanical properties; Mechanical model
• ISSN: 0951-8339; 1873-4170
• DOI: 10.1016/j.marstruc.2023.103396

Compared to conventional fibre-reinforced composite pipes, fibre-reinforced hybrid composite pipes are more complex and are characterised by the use of hybrid fibres, hybrid matrices, and multiple fibre winding angles. In this study, based on the mechanical model of conventional fibre-reinforced composite pipes, the cross-section division method, the radial pressure on the adjacent layer by spiral wound rope structures, and the calculation method of axial force in each layer were improved. Furthermore, the von Mises stresses in each layer were calculated to discriminate the failure to establish a mechanical model of fibre-reinforced hybrid composite pipes with any number of reinforced layers under axial tension, internal pressure, and external pressure. Experimental data and the finite element method (FEM) were used to verify the reliability of the established model, with the axial tensile mechanical properties analysed based on the established model. The results showed that the large-angle fibres no longer withstood the axial tensile load when the winding angle of the large-angle fibres was greater than 45°. The matrices yielding was much earlier than the fibre breakage. The matrices hybrid methods have a large influence on the axial tensile properties of fibre-reinforced hybrid composite pipes, and improving the material properties of the inner and outer liners can significantly improve the axial tensile properties of fibre-reinforced hybrid composite pipes. •Mechanical model of fibre-reinforced hybrid composite pipes under multiaxial loads was established.•The matrices yielding was much earlier than the fibre breakage.•Large-angle fibres no longer withstand the axial tensile load when the winding angle of them is greater than 45°.•Matrices hybrid methods have a large influence on the axial tensile properties of fibre-reinforced hybrid composite pipes.•Improving the properties of the inner and outer liners can significantly improve the axial tensile properties ofpipes.