Compressive properties and energy absorption of 4D printed auxetic mechanical metamaterials

Compressive properties and energy absorption of 4D printed auxetic mechanical metamaterials

Auxetic mechanical metamaterials contract or expand laterally when subjected to compressive or tensile load in the axial direction and offer potential benefits in areas such as flexible electronics, aerospace, and soft actuators. Nevertheless, when metamaterials are fabricated using conventional met...

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Bibliographic Details
Published in:Composite structures Vol. 340; p. 118135
Main Authors: Li, Bingxun, Xin, Xiaozhou, Lin, Cheng, Liu, Liwu, Liu, Yanju, Leng, Jinsong
Format: Journal Article
Language:English
Published: Elsevier Ltd 15-07-2024
Subjects:
4D printing
Auxetic metamaterial
Energy absorption
Programmable and reconfigurable
Quasi-static compression
Shape memory polymer
Programmable and reconfigurable
4D printing
Energy absorption
Quasi-static compression
Shape memory polymer
Auxetic metamaterial
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Summary:Auxetic mechanical metamaterials contract or expand laterally when subjected to compressive or tensile load in the axial direction and offer potential benefits in areas such as flexible electronics, aerospace, and soft actuators. Nevertheless, when metamaterials are fabricated using conventional methods, their configurations and properties are fixed, which prohibits adaptation to the specific geometric requirements of their application environment. This limits their further development. This paper proposes an auxetic mechanical metamaterial with a negative Poisson's ratio and energy absorption capability. Compression specimens are fabricated with LCD photo-curable printing technology. The deformation mechanism and in-plane compression characteristics are examined through experimental and numerical simulation methods. The influence of unit cell geometrical control parameters on Poisson's ratio and energy absorption are also explored. The results indicate the dominant deformation mechanism of metamaterial during in-plane compression is bending deformation. The negative Poisson's ratio behavior is more pronounced when compressing along the X direction than along the Y direction, and the specimens also exhibit energy absorption capacity. In addition, the metamaterials prepared by 4D printing technology can be transformed from one configuration to another under external stimuli stimulation and force, and exhibit different mechanical properties, realizing programmable and reconfigurable, further expanding their application range.
ISSN:0263-8223
1879-1085
DOI:10.1016/j.compstruct.2024.118135