Bamboo-inspired hierarchical microlattice structures (BHMSs) for high strength and energy absorption

Mechanical metamaterials as a category of lightweight materials have exhibited superior specific mechanical properties and energy absorption. However, lack of reasonable structural design always results in weakening or failure to achieve the optimal mechanical performance of metamaterials. Here, we...

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Published in:Mechanics of advanced materials and structures 2024-11, Vol.31 (26), p.7991-8003
Main Authors: Song, Jian, Yan, Junfei, Yi, Bengang, Gong, Wenyuan, Du, Zhaojun, Liu, Tengyong, Liang, Darong, Xie, Changchun, Pu, Zihao
Format: Article
Language:English
Subjects:
3D printing
Bamboo
Bearing capacity
Biomimetics
Bionics
Cellular structure
compressive behavior
Compressive properties
Compressive strength
Configuration management
Design
Design optimization
Energy
Energy absorption
Energy distribution
Journal bearings
lattice materials
Lightweight
Lithography
Load bearing elements
Mechanical properties
Metamaterials
Optimization
Strain energy
Structural design
Unit cell
Weight reduction
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Summary:Mechanical metamaterials as a category of lightweight materials have exhibited superior specific mechanical properties and energy absorption. However, lack of reasonable structural design always results in weakening or failure to achieve the optimal mechanical performance of metamaterials. Here, we firstly adopted bio-inspired and structural optimization methods to guideline the design of microlattice structures. Inspired by the strong and ductile 'Moso' bamboo, three bamboo-inspired hierarchical microlattice structures (BHMSs) were initially designed, and the bamboo's features, viz., hollow, gradient distribution, and cellular, were imitated by designed BHMSs. Optimization design with the objective of maximum ratio of strain energy and reaction force was carried out to furthermore improve the mechanical properties of BHMSs. Afterwards, the optimal BHMSs were printed via Stereolithography. The compressive responses of BHMSs were elaborated by experiments and simulation. Results show that these designed biomimetic structures can be easily tailored via tuning the geometric sizes of unit cell, achieving high compressive specific modulus and strength 48.16 kPa m 3 kg −1 and 1389.23 Pa m 3 kg −1 and the energy-absorbing efficient 85.43% in the octet bamboo-inspired hierarchical microlattice structures (OCT BHMSs). The design strategies and findings shed light on the realization of advanced metamaterials with tailored mechanical properties. How to design ordered cellular structures for lightweight structures with high mechanical strength and energy absorption efficiency remains a crucial challenge in automation, aerospace and lightweight construction fields. Inspired by the lightweight and high load-bearing capacity of nature bamboos and metamaterials in the previous researches (Song et al., Materials & Design, 2019, 173: 107773; Song et al., International Journal of Fatigue, 2017, 100: 126), here a comprehensive approach of bionics and optimization was proposed to design hierarchical microlattice structures with lightweight, good mechanical properties and high energy absorption efficiency. The bamboo's characteristics, including hollow, gradient enhancement, and cellular, were completely copied to reasonably produce hierarchical microlattice configurations, while the optimal sizes were obtained though the optimization design. A combination strategy of bamboo-inspired and optimization design to realize light-weight and high mechanical metamaterials was provided.
ISSN:1537-6494
1537-6532
DOI:10.1080/15376494.2023.2253530