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Abstract

A failure criterion for predicting the damage of honeycomb structures under combined compression and transverse shearing is put forward in this paper. An analytical method using the Bloch wave function and von Kármán plate theory is employed to predict the onset of damage based on the fact that failure of honeycomb structures is closely related to the buckling behavior of its core. After obtaining a bunch of data points of different stress conditions where damage occurs, a failure envelop for honeycomb cores under out-of-plane loads is formed and fitted by a nonlinear function. In order to validate the proposed failure criterion, experimental studies are performed on honeycomb sandwich structures consisting of Nomex honeycomb core and CFRP (carbon-fiber reinforced plastics) facesheets including in-plane compression, three-point bending and combined-compression-shearing. The accuracy of the proposed criterion is evaluated by comparing experiments with results predicted by progressive damage model incorporating the failure envelope of honeycomb core.

Keywords

Honeycomb failure criterion buckling

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References

Masters

Evans

KE.

Models for the elastic deformation of honeycombs. Compos Struct 1996; 35: 403–422.

Burton

Noor

AK.

Assessment of continuum models for sandwich panel honeycomb cores. Comput Methods Appl Mech Eng 1997; 145: 341–360.

Gibson

The mechanics of two-dimensional cellular material. Proc R Soc Lond A Math Phys Sci 1982; 382: 25–42.

Papka

Kyriakides

Experiments and full-scale numerical simulations of in-plane crushing of a honeycomb. Acta Mater 1998; 46: 2765–2776.

Karako

Freund

Experimental studies on mechanical properties of cellular structures using nomex honeycomb cores.

Compos Struct 2012; 94: 2017–2024.

Malek

Gibson

Effective elastic properties of periodic hexagonal honeycombs. Mech Mater 2015; 91: 226–240.

Asprone

Auricchio

Menna

, et al. Statistical finite element analysis of the buckling behavior of honeycomb structures. Compos Struct 2013; 105: 240–255.

Giglio

Manes

Gilioli

Investigations on sandwich core properties through an experimental–numerical approach. Compos Part B 2012; 43: 361–374.

López Jiménez

Triantafyllidis

Buckling of rectangular and hexagonal honeycomb under combined axial compression and transverse shear. Int J Solids Struct 2013; 50: 3934–3946.

10.

Montemurro

Anita

A multi-scale approach for the optimum design of sandwich plates with honeycomb core. Part I: homogenisation of core properties. Compos Struct 2014; 118: 664–676.

11.

Montemurro

Anita

A multi-scale approach for the optimum design of sandwich plates with honeycomb core. part ii: the optimisation strategy. Compos Struct 2014; 118: 677–690.

12.

Liu

Wang

Guan

Experimental and numerical study on the mechanical response of nomex honeycomb core under transverse loading. Compos Struct 2015; 121: 304–314.

13.

Tiwari

Thomas

Khandelwal

Influence of reinforcement in the honeycomb structures under axial compressive load. Thin-Wall Struct 2018; 126: 238–245.

14.

Wilbert

Jang

Kyriakides

, et al. Buckling and progressive crushing of laterally loaded honeycomb. Int J Solids Struct 2011; 48: 803–816.

15.

Beynon

Ruan

, et al. Experimental study of the out-of-plane dynamic compression of hexagonal honeycombs. Compos Struct 2012; 94: 2326–2336.

16.

Seemann

Krause

Numerical modeling of nomex honeycomb sandwich cores at meso-scale level. Compos Struct 2017; 159: 702–718.

17.

Dong

Deshpande

Wadley

Mechanical response of Ti–6Al–4V octet-truss lattice structures. Int J Solids Struct 2015; 60–61: 107–124.

18.

Shterenlikht

Pavier

Brittle fracture of three-dimensional lattice structure. Eng Fract Mech 2019; 219: 106598.

19.

Chen

Richmond

, et al. Bioinspired hierarchical composite design using machine learning: simulation, additive manufacturing, and experiment. Mater Horiz 2018; 5: 939–945.

20.

Qiu

Guan

Jiang

, et al. A method of determining effective elastic properties of honeycomb cores based on equal strain energy. Chin J Aeronaut 2017; 30: 766–779.

21.

Besant

Davies

Hitchings

Finite element modelling of low velocity impact of composite sandwich panels. Compos Part A: Appl Sci Manuf 2001; 32: 1189–1196.

22.

Feng

Aymerich

Damage prediction in composite sandwich panels subjected to low-velocity impact. Compos Part A: Appl Sci Manuf 2013; 52: 12–22.

23.

Kintscher

Karger

Wetzel

, et al. Stiffness and failure behaviour of folded sandwich cores under combined transverse shear and compression. Compos Part A: Appl Sci Manuf 2007; 38: 1288–1295.

24.

Liu

Meng

Wang

, et al. The flatwise compressive properties of nomex honeycomb core with debonding imperfections in the double cell wall. Compos Part B: Eng 2015; 76: 122–132.

25.

Qiu

Guan

Guo

, et al. Buckling of honeycomb structures under out-of-plane loads. J Sandw Struct Mater 2020; 22: 797–821.

26.

Schenk

Schuëller

Buckling analysis of cylindrical shells with random geometric imperfections. Int J Non-Linear Mech 2003; 38: 1119–1132.

27.

Lee

López Jiménez

Marthelot

, et al. The geometric role of precisely engineered imperfections on the critical buckling load of spherical elastic shells. J Appl Mech 2016; 83(11): 111005.

A failure criterion for honeycomb structures considering the onset of instability under out-of-plane loads

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