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Journal of Materials Science

Erschienen in:

10.04.2018 | Computation

Mechanical behaviors of hierarchical cellular structures with negative Poisson’s ratio

verfasst von: Jiahong Hou, Dong Li, Liang Dong

Erschienen in: Journal of Materials Science | Ausgabe 14/2018

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Abstract

An investigation of the mechanical behaviors on hierarchical re-entrant honeycomb structures was undertaken using finite element method. The hierarchical structure with a hierarchy order n (n ≥ 1) was constructed by replacing each vertex of a re-entrant hexagonal structure of hierarchy order n − 1 with a smaller re-entrant hexagon with identical geometry aspect ratio. The Poisson’s ratio and energy absorption capacity of re-entrant structures of different hierarchy orders were studied under various compression velocities. The minimum Poisson’s ratios of the first-order (n = 1) and second-order (n = 2) hierarchical re-entrant structures were − 1.581 and − 1.823, respectively; they were 32.9 and 53.2% lower than that of a zeroth-order hierarchical structure (i.e., conventional re-entrant hexagon). The second-order hierarchical structure exhibited the highest rate of increase in energy absorption capacity with an increasing compression velocity. The plateau stresses of the first- and second-order hierarchical structures were lower than that of the zeroth-order hierarchical structure; however, the second-order hierarchical structure exhibited the highest energy absorption capacity at high compression velocity rate (v > 40 m/s). The energy absorption capacities of the first- and second-order hierarchical structures proposed in the present study are 1.5 and 1.8 times, respectively, higher than those of the hierarchical re-entrant structures proposed in our previous work (Li et al. in Smart Mater Struct 26:025014, 2017).

Vorheriger Artikel Minimal surface designs for porous materials: from microstructures to mechanical properties

Nächster Artikel Effect of strain on the intrinsic stacking fault energy of fcc Co: a first-principles study

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Li D, Yin J, Dong L, Lakes RS (2017) Numerical analysis on mechanical behaviors of hierarchical cellular structures with negative Poisson’s ratio. Smart Mater Struct 26:025014CrossRef

Lakes RS, Elms KE (1993) Indentability of conventional and negative Poisson’s ratio foams. J Compos Mater 27:1193–1202CrossRef

Chan N, Evans KE (1998) Indentation resilience of conventional and auxetic foams. J Cell Plast 34:231–260CrossRef

Scarpa F, Ciffo LG, Yates JR (2004) Dynamic properties of high structural integrity auxetic open cell foam. Smart Mater Struct 13:49–56CrossRef

Li D, Dong L, Yin J, Lakes RS (2016) Negative Poisson’s ratio in 2D Voronoi cellular solids by biaxial compression: a numerical study. J Mater Sci 51:7029–7037. https://doi.org/10.1007/s10853-016-9992-6 CrossRef

Grima JN, Caruana-Gauci R, Dudek MR, Wojciechowski KW, Gatt R (2013) Smart metamaterials with tunable auxetic and other properties. Smart Mater Struct 22:084016CrossRef

Lakes RS (1987) Response: negative Poisson’s ratio materials. Science 238:551CrossRef

Gibson LJ, Ashby MF, Schajer GS, Robertson CI (1982) The mechanics of two-dimensional cellular materials. Proc R Soc Lond A 382:25–42CrossRef

Kolpakov AG (1985) On the determination of the averaged moduli of elastic gridworks. Prikl Mat Mekh 59:969–977

10.

Li D, Yin J, Dong L, Lakes RS (2018) Strong re-entrant cellular structures with negative Poisson’s ratio. J Mater Sci 53:3493–3499. https://doi.org/10.1007/s10853-017-1809-8 CrossRef

11.

Wojciechowski KW (1989) Two-dimensional isotropic system with a negative Poisson’s ratio. Phys Lett A 137:60–64CrossRef

12.

Li D, Ma J, Dong L, Lakes RS (2017) Stiff square structure with a negative Poisson’s ratio. Mater Lett 188:149–151CrossRef

13.

Li D, Ma J, Dong L, Lakes RS (2017) Three-dimensional stiff cellular structures with negative Poisson’s ratio. Phys Status Solidi B. https://doi.org/10.1002/pssb.201600785

14.

Pozniak AA, Smardzewski J, Wojciechowski KW (2013) Computer simulations of auxetic foams in two dimensions. Smart Mater Struct 22:1–11CrossRef

15.

Li D, Dong L, Lakes RS (2016) A bi-material structure with Poisson’s ratio tunable from positive to negative via temperature control. Mater Lett 164:456–459CrossRef

16.

Mousanezhad D, Ebrahimi H, Haghpanah B, Ghosh R, Ajdari A, Hamouda AMS, Vaziri A (2015) Spiderweb honeycombs. Int J Solids Struct 66:218–227CrossRef

17.

Mousanezhad D, Babaee S, Ebrahimi H, Ghosh R, Hamouda AS, Bertoldi K, Vaziri A (2015) Hierarchical honeycomb auxetic metamaterials. Sci Rep 5:18306CrossRef

18.

Gatt R, Mizzi L, Azzopardi JI, Azzopardi KM, Attard D, Casha A, Briffa J, Grima JN (2015) Hierarchical auxetic mechanical metamaterials. Sci Rep 5:8395CrossRef

19.

Sun Y, Pugno N (2013) In plane stiffness of multifunctional hierarchical honeycombs with negative Poisson’s ratio sub-structures. Compos Struct 106:681–689CrossRef

20.

Taylor CM, Smith CW, Miller W, Evans KE (2011) The effects of hierarchy on the in-plane elastic properties of honeycombs. Int J Solids Struct 48:1330–1339CrossRef

21.

Taylor CM, Smith CW, Miller W, Evans KE (2012) Functional grading in hierarchical honeycombs: density specific elastic performance. Compos Struct 94:2296–2305CrossRef

22.

Billon K, Zampetakis I, Scarpa F, Ouisse M, Sadoulet-Reboul E, Collet M, Perriman A, Hetherington A (2017) Mechanics and band gaps in hierarchical auxetic rectangular perforated composite metamaterials. Compos Struct 160:1042–1050CrossRef

23.

Lakes RS (1993) Materials with structural hierarchy. Nature 361:511–515CrossRef

24.

Ajdari A, Jahromi BH, Papadopoulos J, Nayeb-Hashemi H, Vaziri A (2012) Hierarchical honeycombs with tailorable properties. Int J Solids Struct 49:1413–1419CrossRef

25.

Oftadeh R, Haghpanah B, Papadopoulos J, Hamouda AMS, Nayeb-Hashemi H, Vaziri A (2014) Mechanics of anisotropic hierarchical honeycombs. Int J Mech Sci 81:126–136CrossRef

26.

Chen Y, Li T, Jia Z, Scarpa F, Yao CW, Wang L (2018) 3D printed hierarchical honeycombs with shape integrity under large compressive deformation. Mater Des 137:226–234CrossRef

27.

Pugno N, Sun Y (2013) Hierarchical fibers with a negative Poisson’s ratio for tougher composites. Materials 6:699–712CrossRef

28.

Chen Q, Huang S (2013) Mechanical properties of a porous bioscaffold with hierarchy. Mater Lett 95:89–92CrossRef

29.

Chen Q, Pugno N (2012) In-plane elastic buckling of hierarchical honeycomb materials. Eur J Mech A/Solids 34:120–129CrossRef

30.

Zhu HX, Yan LB, Zhang R, Qiu XM (2012) Size-dependent and tunable elastic properties of hierarchical honeycombs with regular square and equilateral triangular cells. Acta Mater 60:4927–4939CrossRef

31.

Ashby MF, Evans AG, Fleck NA, Gibson LJ, Hutchinson JW, Wadley HNG (2000) Metal foams: a design guide. Butterworth Heinemann, Oxford

Titel: Mechanical behaviors of hierarchical cellular structures with negative Poisson’s ratio
verfasst von: Jiahong Hou
Dong Li
Liang Dong
Publikationsdatum: 10.04.2018
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 14/2018
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-018-2298-0

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