Quasi-static crushing behavior of novel re-entrant circular auxetic honeycombs

Qi, Chang; Jiang, Feng; Remennikov, Alexander; Pei, Lian-Zheng; Li, Jun; Wang, Junshan; Liao, Xiangwei; Yang, Shu

doi:10.1016/j.compositesb.2020.108117

Cited by 188 publications

(31 citation statements)

References 39 publications

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“…In 2020, Wu et al found that an increase in the cell wall angle and cell wall thickness of re-entrant honeycomb mechanical metamaterials improved their energy absorption capacity. This agreed with the reports of Zhang et al and Wang et al Qi et al fabricated a doubly circular arc slope cell wall re-entrant honeycomb structure, which resulted in improved energy adsorption and a significant NPR effect compared to those of a regular honeycomb structure.…”

Section: Auxetic Polymer-based Mechanical Metamaterialssupporting

confidence: 91%

Review: Auxetic Polymer-Based Mechanical Metamaterials for Biomedical Applications

Veerabagu

Palza

Quero

2022

ACS Biomater. Sci. Eng.

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Over the last three decades but more particularly during the last 5 years, auxetic mechanical metamaterials constructed from precisely architected polymer-based materials have attracted considerable attention due to their fascinating mechanical properties. These materials present a negative Poisson's ratio and therefore unusual mechanical behavior, which has resulted in enhanced static modulus, energy adsorption, and shear resistance, as compared with the bulk properties of polymers. Novel advanced polymer processing and fabrication techniques, and in particular additive manufacturing, allow one to design complex and customizable polymer architectures that are particularly relevant to fabricate auxetic mechanical metamaterials. Although these metamaterials exhibit exotic mechanical properties with potential applications in several engineering fields, biomedical applications seem to be one of the most relevant with a growing number of articles published over recent years. As a result, special focus is needed to understand the potential of these structures and foster theoretical and experimental investigations on the potential benefits of the unusual mechanical properties of these materials on the way to high performance biomedical applications. The present Review provides up to date information on the recent progress of polymer-based auxetic mechanical metamaterials mainly fabricated using additive manufacturing methods with a special focus toward biomedical applications including tissue engineering as well as medical devices including stents and sensors.

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Section: Auxetic Polymer-based Mechanical Metamaterialssupporting

confidence: 91%

Review: Auxetic Polymer-Based Mechanical Metamaterials for Biomedical Applications

Veerabagu

Palza

Quero

2022

ACS Biomater. Sci. Eng.

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“…Realizing architected honeycombs via material jetting additive manufacturing, their study demonstrated that such geometrically tailored designs exhibit energy absorption efficiency as high as 90%. It can be concluded from the above studies that mechanical/energy absorption properties of auxetic honeycombs are primarily governed by their unit-cell architectures [36,37].…”

Section: Introductionmentioning

confidence: 92%

In-plane energy absorption characteristics of a modified re-entrant auxetic structure fabricated via 3D printing

Choudhry

Panda

Kumar

2022

Composites Part B: Engineering

129

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“…In this paper, the compression speed is set as 0.5 m/s according to other references. [31][32][33] The experiment outcomes are compared with the finite element simulation results. The maximum compression displacement is 60 mm.…”

Section: Experimental Validationmentioning

confidence: 99%

Topology design and equivalent mechanical properties of a three-dimensional star-shaped auxetic structure

Wang

Dai

Zhao

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part L:

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Topology design is the most important method of obtaining optimal material distribution that is directly related to the mechanical properties of structural materials. Aimed at improving the accuracy and efficiency of topology design, this paper explores an innovative topological technique that integrates a sigmoid-rational approximation of material properties approach, with a modified optimality criteria algorithm. Furthermore, a three-dimensional (3D) star-shaped auxetic structure, based on the sigmoid-rational approximation of material properties approach and a modified optimality criteria technique is proposed. The unit cell structural parameters are extracted, and the mechanical properties of the 3D star-shaped structure, including the relative density, equivalent elastic modulus, and equivalent Poisson's ratio, are investigated using mechanical derivation, numerical, and experimental methods. The subsequent results demonstrate that the sigmoid-rational approximation of material properties approach and a modified optimality criteria technique provides a feasible novel idea for multicellular structure development and that the advantageous 3D star-shaped auxetic structure has great potential within the field of structural safety.

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Quasi-static crushing behavior of novel re-entrant circular auxetic honeycombs

Cited by 188 publications

References 39 publications

Review: Auxetic Polymer-Based Mechanical Metamaterials for Biomedical Applications

Review: Auxetic Polymer-Based Mechanical Metamaterials for Biomedical Applications

In-plane energy absorption characteristics of a modified re-entrant auxetic structure fabricated via 3D printing

Topology design and equivalent mechanical properties of a three-dimensional star-shaped auxetic structure

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