期刊
MECHANICS OF ADVANCED MATERIALS AND STRUCTURES
卷 29, 期 3, 页码 408-418出版社
TAYLOR & FRANCIS INC
DOI: 10.1080/15376494.2020.1774690
关键词
Auxetic behavior; bimaterial; 3D printing; finite element simulation; metamaterial; reentrant structure
A multimaterial strategy combined with structure innovation is adopted to enhance structural stiffness while retaining the auxetic behavior for auxetic metamaterials. A bimaterial reentrant structure with additional soft arch-like beams and hinges is proposed and investigated using experimental and simulation approaches. The results demonstrate that reducing the strength of the hinge significantly reduces the buckling issue of the beam/wall and minimizes the reduction of auxetic behavior due to increased stiffness. Thus, the strategy to enhance design flexibility for auxetic metamaterials is verified.
A multimaterial strategy is adopted in combination with the structure innovation to achieve enhanced structural stiffness, and meanwhile, to retain the auxetic behavior for auxetic metamaterials. A bimaterial reentrant structure with additional soft arch-like beams and hinges is proposed, and then investigated using both experimental and simulation approaches. The results indicate that the buckling issue of the beam/wall can be significantly reduced if the strength of the hinge is kept small, and the reduction of auxetic behavior due to increased stiffness can also be minimized. Therefore, the strategy to enhance the design flexibility for auxetic metamaterials is verified.
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