Engineering Transactions

Engineering Transactions, 56, 3, pp. 201–225, 2008
10.24423/ENGTRANS.196.2008

Two-dimensional contact problem formulated for anisotropic, elastic bodies is considered. As an example of anisotropic medium, the cellular material is taken. The idea of two-scale modeling is adopted for formulation of an equivalent continuum, on the basis of which elastic properties can be obtained [2, 3]. Typical cellular microstructures with various types of symme- tries are considered. Special attention is paid to cell structures giving negative Poisson’s ratio in some directions (re-entrant cells). Application of the energy-based criterion for equivalent continuum gives macroscopic yield condition [2, 5]. Condition for the energy coefficient defined as a sum of weighted energies stored in elastic eigenstates ensures that the material works in elastic state. Unilateral frictional contact problem is analyzed using FEM. Calculations are performed for rough contact of square block subjected to normal load. Numerical solutions show differences in deformation type and contact stress distributions for different types of microstructures of the analyzed medium. The study enables the optimal choice of material structure topology, which ensures the reduction of peak contact pressure and friction stress, and applicability of anisotropic material to the given problem.

Copyright © Polish Academy of Sciences & Institute of Fundamental Technological Research (IPPT PAN).

ANSYS 10.0 manual.

M. Janus–Michalska, Micromechanical model of auxetic cellular materials, submitted for publication in Archives of Metallurgy and Materials.

M. Janus–Michalska, Effective models describing elastic behaviour of cellular materials, Archives of Metallurgy and Materials, 50, 3, 595–608, 2005.

N. Kikuchi, J. T. Oden, Contact problems in elasticity: a study of variational ineqalitiees and finite element methods, SIAM, Philadelphia 1988.

P. Kordzikowski, M. Janus–Michalska, R. B. Pęcherski, Specification of energy – based criterion of elastic limit states for cellular materials, Archives of Metallurgy and Materials, 50, 3, 621–634, 2005.

R. S. Lakes, Foam structures with a negative Poisson’s ratio, Science, 235, 1038–1040, 1987.

R. S. Lakes, Design considerations for materials with negative Poisson’s ratios, Trans. ASME J. Mech., 115, 696–700, 1993.

D. W. Overaker, A. M. Cuitino, N. A. Langrana, Elastoplastic micromechanical modeling of two-dimensional irregular convex and nonconvex (re-entrant) hexagonal foams, Transactions of ASME, 65, 1998.

A. Scalia, Contact Problem for porous elastic half-plane, J. Elasticity, 60, 91–102, 2000.

G. E. Stavroulakis, Auxetic behavior: appearance and engineering applications, Physica Status Solidi, 3, 710–720, 2005.

G. Szefer, D. Kędzior, Contact of elastic bodies with negative poisson’s ratio, Springer V., 2002.

Y. Wang, R. Lakes, Analytical parametric analysis of the contact problem of human buttocks and negative Poisson’s ratio foam cushions, Int. J. Sol. Struc., 39, 4825–38, 2002.

J. Rychlewski, Unconventional approach to linear elasticity, Arch. Mech., 47, 149–171, 1995.