Dynamic Crushing Strength Analysis of Auxetic Honeycombs

The in-plane dynamic crushing behavior of re-entrant honeycomb is analyzed and compared with the conventional hexagon topology. Detailed deformation modes along two orthogonal directions are examined, where a parametric study of the effect of impact velocity and cell wall aspect ratio is performed....

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Published inActa mechanica solida Sinica Vol. 29; no. 5; pp. 490 - 501
Main Authors Hou, Xiuhui, Deng, Zichen, Zhang, Kai
Format Journal Article
LanguageEnglish
Published Singapore Elsevier Ltd 01.10.2016
Springer Singapore
Subjects
auxetic effect
Classical Mechanics
deformation mode
dynamic crushing strength
energy absorption
Engineering
re-entrant honeycomb
Surfaces and Interfaces
Theoretical and Applied Mechanics
Thin Films
energy absorption
auxetic effect
re-entrant honeycomb
dynamic crushing strength
deformation mode
Online AccessGet full text
ISSN0894-9166
1860-2134
DOI10.1016/S0894-9166(16)30267-1

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Abstract The in-plane dynamic crushing behavior of re-entrant honeycomb is analyzed and compared with the conventional hexagon topology. Detailed deformation modes along two orthogonal directions are examined, where a parametric study of the effect of impact velocity and cell wall aspect ratio is performed. An analytical formula of the dynamic crushing strength is then deduced based on the periodic collapse mechanism of cell structures. Comparisons with the finite element results validate the effectiveness of the proposed analytical method. Numerical results also reveal higher plateau stress of re-entrant honeycomb over conventional hexagon topology, implying better energy absorption properties. The underlying physical understanding of the results is emphasized, where the auxetic effect (negative Poisson’s ratio) induced in the re-entrant topology is believed to be responsible for this superior impact resistance.
AbstractList The in-plane dynamic crushing behavior of re-entrant honeycomb is analyzed and compared with the conventional hexagon topology.Detailed deformation modes along two orthogonal directions are examined,where a parametric study of the effect of impact velocity and cell wall aspect ratio is performed.An analytical formula of the dynamic crushing strength is then deduced based on the periodic collapse mechanism of cell structures.Comparisons with the finite element results validate the effectiveness of the proposed analytical method.Numerical results also reveal higher plateau stress of re-entrant honeycomb over conventional hexagon topology,implying better energy absorption properties.The underlying physical understanding of the results is emphasized,where the auxetic effect(negative Poisson's ratio) induced in the re-entrant topology is believed to be responsible for this superior impact resistance.
The in-plane dynamic crushing behavior of re-entrant honeycomb is analyzed and compared with the conventional hexagon topology. Detailed deformation modes along two orthogonal directions are examined, where a parametric study of the effect of impact velocity and cell wall aspect ratio is performed. An analytical formula of the dynamic crushing strength is then deduced based on the periodic collapse mechanism of cell structures. Comparisons with the finite element results validate the effectiveness of the proposed analytical method. Numerical results also reveal higher plateau stress of re-entrant honeycomb over conventional hexagon topology, implying better energy absorption properties. The underlying physical understanding of the results is emphasized, where the auxetic effect (negative Poisson’s ratio) induced in the re-entrant topology is believed to be responsible for this superior impact resistance.
Author Xiuhui Hou Zichen Deng Kai Zhang
AuthorAffiliation School of Mechanics, Civil Engineering and Architecture, Northwestern Polytechnical University, Xi'an 710072, China State Key Laboratory of Structural Analysis for Industrial Equipment, Dalian University of Technology, Dalian 116024, China
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  givenname: Zichen
  surname: Deng
  fullname: Deng, Zichen
  email: dweifan@nwpu.edu.cn
  organization: School of Mechanics, Civil Engineering and Architecture, Northwestern Polytechnical University, Xi’an 710072, China
– sequence: 3
  givenname: Kai
  surname: Zhang
  fullname: Zhang, Kai
  organization: School of Mechanics, Civil Engineering and Architecture, Northwestern Polytechnical University, Xi’an 710072, China
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Issue 5
Keywords energy absorption
auxetic effect
re-entrant honeycomb
dynamic crushing strength
deformation mode
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Notes The in-plane dynamic crushing behavior of re-entrant honeycomb is analyzed and compared with the conventional hexagon topology.Detailed deformation modes along two orthogonal directions are examined,where a parametric study of the effect of impact velocity and cell wall aspect ratio is performed.An analytical formula of the dynamic crushing strength is then deduced based on the periodic collapse mechanism of cell structures.Comparisons with the finite element results validate the effectiveness of the proposed analytical method.Numerical results also reveal higher plateau stress of re-entrant honeycomb over conventional hexagon topology,implying better energy absorption properties.The underlying physical understanding of the results is emphasized,where the auxetic effect(negative Poisson's ratio) induced in the re-entrant topology is believed to be responsible for this superior impact resistance.
42-1121/O3
honeycomb topology collapse plateau emphasized perfectly directions deduced validate Poisson
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PublicationSubtitle The Chinese Society of Theoretical and Applied Mechanics
PublicationTitle Acta mechanica solida Sinica
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PublicationTitleAlternate Acta Mechanica Solida Sinica
PublicationYear 2016
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Springer Singapore
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Snippet The in-plane dynamic crushing behavior of re-entrant honeycomb is analyzed and compared with the conventional hexagon topology.Detailed deformation modes along...
The in-plane dynamic crushing behavior of re-entrant honeycomb is analyzed and compared with the conventional hexagon topology. Detailed deformation modes...
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elsevier
chongqing
SourceType Enrichment Source
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Publisher
StartPage 490
SubjectTerms auxetic effect
Classical Mechanics
deformation mode
dynamic crushing strength
energy absorption
Engineering
re-entrant honeycomb
Surfaces and Interfaces
Theoretical and Applied Mechanics
Thin Films
Title Dynamic Crushing Strength Analysis of Auxetic Honeycombs
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