Abstract
Composite risers with high-performances are in demand for offshore oil and gas exploration in the deep sea. The performances of the composite riser are closely related to the design parameters. This paper focuses on the multi-parameter analysis on the strength ratio of filament-wound risers under combined loading. Based on elasticity theory and Tsai-Wu failure criterion, a strength model of the filament-wound riser is firstly established under combined internal and axial pressure. Then, the filament-wound risers with two winding patterns are discussed to reveal the contribution of five variables on strength ratio, including winding angle, the number of plies, metal liner, fiber volume content, and the load ratio. Finally, the optimal parameters are designed based on the PSO-GWO method. The numerical results show that the number of winding layers, liner and winding angle have a greater influence on strength of composite risers, while the influence of load ratio is smaller. The strength ratio firstly increases, and then decreases with the rise of fiber volume content. It is also found the better range for higher strength of composite riser is 0.4 < Vf < 0.6. Besides, it was found that the strength of composite riser with [–45°/±\(\theta _{1}^{^\circ }\)/±\(\theta _{2}^{^\circ }\)/±\(\theta _{3}^{^\circ }\)/45°] is greater than that of composite riser with [–45°/\(\theta _{1}^{^\circ }\)/–\(\theta _{2}^{^\circ }\)/(\(\theta _{3}^{^\circ }\)/–\(\theta _{4}^{^\circ }\))2/45°].
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Funding
This study was supported by the Natural Science Foundation of Jiangsu Province of China (no. BK20200999), the Postgraduate Research & Practice Innovation Program of Jiangsu Province (SJCX22_1931) and the Scientific Research Foundation for the PhD (Jiangsu University of Science and Technology, no. 1022931904). In addition, we would like to thank all the colleagues and anonymous reviewers who helped to improve the paper.
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Ye, S., Li, C., Liu, Z. et al. Numerical Investigation of the Parametric Effect on the Strength of Filament-Wound Riser under Combined Loads. Mech. Solids 57, 1249–1264 (2022). https://doi.org/10.3103/S0025654422050259
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DOI: https://doi.org/10.3103/S0025654422050259