Journal
BIOMIMETICS
Volume 8, Issue 2, Pages -Publisher
MDPI
DOI: 10.3390/biomimetics8020148
Keywords
biomimetics; topology optimization (TO); computer modeling; discontinuous carbon fibers (DiCFs); carbon fiber-reinforced polymer composites (CFRPCs); lattice structure; cuttlefish bone; mechanical properties; lightweight
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The research and development of composite materials with lighter, stronger, tougher, and multifunctional properties, particularly lattice structures, heterogeneities, or hybrid compositions, have gained significant interest in the materials research community. In this study, discontinuous carbon fiber-reinforced polymer matrix composite materials were utilized for structural design, incorporating a three-dimensional periodic lattice block inspired by cuttlefish bone and computer modeling-based topology optimization. The proposed method provides a design tool for affordable and high-performance structural materials, as evidenced by comparison with similar designs and experiments.
The ever-increasing requirements for structural performance drive the research and development of lighter, stronger, tougher, and multifunctional composite materials, especially, the lattice structures, heterogeneities, or hybrid compositions have attracted great interest from the materials research community. If it is pushed to the extreme, these concepts can consist of highly controlled lattice structures subject to biomimetic material design and topology optimization (TO). However, the strong coupling among the composition and the topology of the porous microstructure hinders the conventional trial-and-error approaches. In this work, discontinuous carbon fiber-reinforced polymer matrix composite materials were adopted for structural design. A three-dimensional (3D) periodic lattice block inspired by cuttlefish bone combined with computer modeling-based topology optimization was proposed. Through computer modeling, complex 3D periodic lattice blocks with various porosities were topologically optimized and realized, and the mechanical properties of the topology-optimized lattice structures were characterized by computer modeling. The results of this work were compared with other similar designs and experiments to validate the effectiveness of the proposed method. The proposed approach provides a design tool for more affordable and higher-performance structural materials.
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