Mechanical and interfacial analysis of 3D-printed two-matrix continuous carbon fibre composites for enhanced structural performance

•Fractographic behaviour of 3D printed two-matrix continuous carbon fibre composites has been comprehensively analysed across multiple scales.•The corresponding molecule dynamic models are established to reveal the interfacial characteristics of two-matrix continuous carbon fibre composites.•Combine...

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Bibliographic Details
Published in:Composites. Part A, Applied science and manufacturing Applied science and manufacturing, 2024-05, Vol.180, p.108105, Article 108105
Main Authors: Liu, Fei, Wang, Shenru, Zhang, Wuxiang, Ding, Xilun, Ferraris, Eleonora, Ivens, Jan
Format: Article
Language:English
Subjects:
A. Carbon fibres
B. Fracture
D. Microstructural analysis
E. 3-D printing
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Summary:•Fractographic behaviour of 3D printed two-matrix continuous carbon fibre composites has been comprehensively analysed across multiple scales.•The corresponding molecule dynamic models are established to reveal the interfacial characteristics of two-matrix continuous carbon fibre composites.•Combined with the similarity and divergence between the experimental results and simulation, four fracture modes of the composite are concluded.•An optimisation strategy for enhancing the composite's performance is given based on the multi-scale analysis. Two-matrix continuous carbon fibre composites are recognized for enhancing structural and mechanical properties. However, a comprehensive investigation into their interfacial behaviour and potential has yet to be undertaken. Based on the 3D printing process, this study uses experimental and simulation techniques to analyse the mechanical and interfacial performance across multiple scales. The flexure properties under different processing parameters are studied at the macro level. Meso and micro-structural characterization are evaluated by scanning electron microscopy, optical microscopy and molecular dynamics simulation. The disparities in simulations and experimental results are attributed to macroscopic defects and reinforcement volume fraction. This yields insights into strategies for optimising performance, culminating in a comprehensive understanding of the fracture mechanism of two-matrix continuous carbon fibre composites. Our study provides an approach to creating and analysing other systems with multiple matrix composites and enabling new engineering applications for composites.
ISSN:1359-835X
1878-5840
DOI:10.1016/j.compositesa.2024.108105