Authors: M. Zarei Mahmoudabadi, M. Sadighi

Abstract:

In the study of honeycomb crushing under quasistatic loading, two parameters are important, the mean crushing stress and the wavelength of the folding mode. The previous theoretical models did not consider the true cylindrical curvature effects and the flow stress in the folding mode of honeycomb material. The present paper introduces a modification on Wierzbicki-s model based on considering two above mentioned parameters in estimating the mean crushing stress and the wavelength through implementation of the energy method. Comparison of the results obtained by the new model and Wierzbicki-s model with existing experimental data shows better prediction by the model presented in this paper.

Keywords: Crush strength, Flow stress, Honeycomb, Quasistatic load.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1074407

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2251

References:

[1] R.K. McFarland, Hexagonal cell structures under post-buckling axial load. AIAA Journal 1, 1963, 1380-1385.
[2] T. Wierzbicki, Crushing analysis of metal honeycombs. International Journal of Impact Engineering 1, 1983, 157-174.
[3] W. Chen, T. Wierzbicki, Relative merits of single-cell, multi-cell and foam-filled thin-walled structures in energy absorption, Thin-Walled Structures 39, 2001 , 287-306.
[4] L. J. Gibson, M. E. Ashby, G. S. Schajer, and C. I. Robertson, The mechanics of two-dimensional cellular materials, Proceedings of the Royal Society of London A, 1982, 382, 25-42.
[5] L.J. Gibson, M.F. Ashby, Cellular Solids: Structure and Properties, second ed. Cambridge University Press, Cambridge, UK, 1997.
[6] E. Wu, W. Jiang. Axial crush of metallic honeycombs. Int J Impact Eng 1997, 439-456.
[7] A. Alavinia, GH. Liaghat, A comment on the axial crush of metallic honeycombs by Wu and Jiang, International Journal of Impact Engineering 28, 2003, 1143-1146.
[8] S. T. Hong, J. Pan, T. Tyan, P. Prasad, Quasi-static crush behavior of aluminum honeycomb specimens under compression dominant combined loads, International Journal of Plasticity 22, 2006, 73-109.
[9] S. T. Hong, J. Pan, T. Tyan, P. Prasad, Quasi-static crush behavior of aluminum honeycomb specimens under non-proportional compression-dominant combined loads, International Journal of Plasticity 22, 2006, 1062-1088.
[10] L. Aktay, AF. Johnson, BH. Kroplin, Numerical modeling of honeycomb core crush behavior, Engineering Fracture Mechanics 75, 2008, 2616-2630.
[11] H. Nakamoto, T. Adachi, W. Araki, In-plane impact behavior of honeycomb structures randomly filled with rigid inclusions, International Journal of Impact Engineering 36, 2009, 73-80.