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Process-driven strength enhancement and progressive damage analysis of three-dimensional woven composites traction rods

Hao Huang, Zhongde Shan, Yanming Xing, Zitong Guo, Chunguang Yang, Jianhua Liu, Zheng Sun, Xiaohui Ao, Dong Wang, Chen‐Chen Tan, Weihao Wang, Juncheng Luo

2025Materials & Design7 citationsDOIOpen Access PDF

Abstract

• The embedding feature selection surrogate model is proposed for integration of material, structural and process parameters. • A progressive damage model is developed to elucidate the failure sequence in composites matrix and yarns under axial loads. • Optimized parameters are validated, achieving 40.69% strength improvement, 18.56% stiffness increase and 6.1% mass reduction. • The accuracy of the progressive damage model is shown, with relative errors of 13.5% for stiffness and 10.7% for strength. With the growing emphasis on lightweight and high-strength materials, optimizing the performance of composites has become increasingly critical for engineering applications. This study presents a comprehensive methodology for optimizing the process parameters of three-dimensional (3D) woven composites traction rods using a progressive damage failure model and an embedding feature selection-based back propagation neural network (EFSBPNN) surrogate model. The forming processes were systematically analyzed to identify key design variables, followed by developing an advanced surrogate model integrating material, structural, and process parameters. A progressive damage failure analysis model was established to predict the structural response, forming the basis for the optimization strategy. Experimental validation demonstrated significant performance improvements, including an 18.56% increase in stiffness, a 40.69% enhancement in strength, and a 6.1% reduction in mass. The surrogate model achieved high accuracy across multiple metrics, and the predictive capabilities of the damage model showed a relative error of 13.5% for stiffness and 10.7% for strength. These findings highlight the potential of the proposed approach for the efficient design and optimization of composite structures.

Topics & Concepts

Materials scienceComposite materialTraction (geology)RodProcess (computing)Structural engineeringMechanical engineeringEngineeringComputer scienceAlternative medicinePathologyOperating systemMedicineMechanical Behavior of CompositesAdditive Manufacturing and 3D Printing TechnologiesFiber-reinforced polymer composites