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Abstract

For hierarchical corrugated sandwich structures with second-order core, the prediction error of failure behavior by existing methods becomes unacceptable with the increase of structure thickness. In this study, a novel analytical model called moderately thick plate model is developed based on Mindlin plate theory, which can be used to analyze the failure behavior of hierarchical corrugated structures with second-order core under compression or shear loads. Then, the analytical expressions of nominal stress for six competing failure modes are derived based on the moderately thick plate model. The results of six different unit structures based on the moderately thick plate model agree quite well the ones by finite element methods. Furthermore, the influence of different structure thicknesses is investigated to validate the applicability of the moderately thick plate model. According to the comparative results with the thin plate model, the proposed moderately thick plate model has a better precision with the increase of the ratio of thickness to width for failure components.

Keywords

Hierarchical corrugated sandwich structures failure modes Mindlin plate theory moderately thick plate model nominal stress

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References

Rejab

MRM

Cantwell

. The mechanical behaviour of corrugated-core sandwich panels. Compos Part B-Eng 2013; 47: 267–277.

Khalkhali

Khakshournia

Nariman-Zadeh

. A hybrid method of FEM, modified NSGAII and TOPSIS for structural optimization of sandwich panels with corrugated core. J Sandwich Struct Mater 2014; 16: 398–417.

Kılıçaslan

Odacı

Güden

. Single-and double-layer aluminum corrugated core sandwiches under quasi-static and dynamic loadings. J Sandwich Struct Mater 2016; 18: 667–692.

Kazemahvazi

Zenkert

. Corrugated all-composite sandwich structures. Part 1: Modeling. Compos Sci Technol 2009; 69: 913–919.

Kazemahvazi

Tanner

Zenkert

. Corrugated all-composite sandwich structures. Part 2: Failure mechanisms and experimental programme. Compos Sci Technol 2009; 69: 920–925.

Chang

Ventsel

Krauthammer

et al.

Bending behavior of corrugated-core sandwich plates. Compos Struct 2005; 70: 81–89.

Wadley

HNG

Børvik

Olovsson

et al.

Deformation and fracture of impulsively loaded sandwich panels. J Mech Phys Solids 2013; 61: 674–699.

Lakes

. Materials with structural hierarchy. Nature 1993; 361: 511–515.

Murphey

Hinkle

. Some performance trends in hierarchical truss structures. AIAA J 2003.

10.

Easterling

Harrysson

Gibson

et al.

On the mechanics of balsa and other woods. Proc Roy Soc London A: Math Phys Eng Sci 1982; 383: 31–41.

11.

Rho

Kuhn-Spearing

Zioupos

. Mechanical properties and the hierarchical structure of bone. Med Eng Phys 1998; 20: 92–102.

12.

Hao

Wang

et al.

Hybrid optimization of hierarchical stiffened shells based on smeared stiffener method and finite element method. Thin-Walled Struct 2014; 82: 46–54.

13.

Fan

Jin

Fang

. Mechanical properties of hierarchical cellular materials. Part I: Analysis. Compos Sci Technol 2008; 68: 3380–3387.

14.

Sun

Lai

Fan

et al.

Crushing mechanism of hierarchical lattice structure. Mech Mater 2016; 97: 164–183.

15.

Chen

Pugno

. In-plane elastic buckling of hierarchical honeycomb materials. Eur J Mech A-Solid 2012; 34: 120–129.

16.

Oftadeh

Haghpanah

Vella

et al.

Optimal fractal-like hierarchical honeycombs. Phys Rev Lett 2014; 113: 104301–104301.

17.

Kooistra

Deshpande

Wadley

HNG

. Hierarchical corrugated core sandwich panel concepts. J Appl Mech 2007; 74: 259–268.

18.

Fang

. Failure mode analysis and performance optimization of the hierarchical corrugated truss structure. Adv Mech Eng 2014; 6: 251591–251591.

19.

Fang

Hao

et al.

Three-point bending deflection and failure mechanism map of sandwich beams with second-order hierarchical corrugated truss core. J Sandwich Struct Mater 2017; 19: 83–107.

20.

Marin

. The Lagrange identity method in thermoelasticity of bodies with microstructure. Int J Eng Sci 1994; 32: 1229–1240.

21.

Marin

. On existence and uniqueness in thermoelasticity of micropolar bodies. Comptes Rendus, Acad Sci Paris, Serie II 1995; 321: 475–480.

22.

Marin

Marinescu

. Thermoelasticity of initially stressed bodies, asymptotic equipartition of energies. Int J Eng Sci 1998; 36: 73–86.

23.

Mizusawa

. Vibration of rectangular Mindlin plates by the spline strip method. J Sound Vib 1993; 163: 193–205.

24.

Teo

Liew

. Three-dimensional elasticity solutions to some orthotropic plate problems. Int J Solids Struct 1999; 36: 5301–5326.

25.

Liew

Xiang

Kitipornchai

. Analytical buckling solutions for Mindlin plates involving free edges. Int J Mech Sci 1996; 38: 1127–1138.

26.

Shufrin

Eisenberger

. Stability and vibration of shear deformable plates––first order and higher order analyses. Int J Solids Struct 2005; 42: 1225–1251.

27.

Hashemi

Arsanjani

. Exact characteristic equations for some of classical boundary conditions of vibrating moderately thick rectangular plates. Int J Solids Struct 2005; 42: 819–853.

28.

Hosseini-Hashemi

Khorshidi

Amabili

. Exact solution for linear buckling of rectangular Mindlin plates. J Sound Vib 2008; 315: 318–342.

29.

Zenkert

. An introduction to sandwich construction. Engineering Materials Advisory Services, UK: Sheffield, 1995.

Failure behavior of hierarchical corrugated sandwich structures with second-order core based on Mindlin plate theory

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