This article describes uniaxial compression tests on a melt-extruded closed-cell low-density polyethylene foam. The stress–strain response shows that the mechanical behaviour of the foam is predominantly transversely isotropic viscoelastic and compressible. Image analysis is used to estimate the Poisson’s ratio under large strains. When the deformation is less than 5%, the compression kinematics and mechanical response of the polymer foam can be well described by a linear compressible transversely isotropic elastic model. For large strain, a simple method is proposed to estimate the uniaxial compression response of the foam at any arbitrary orientation by manipulating experimental data obtained from compression tests in the principal and transverse directions (stress vs. strain and Poisson’s ratio) and a simple shear test. An isotropic compressible hyperfoam model is then used to implement this behaviour in a finite element code.
GibsonLJAshbyMF. Cellular solids structure and properties, 2nd ed. Cambridge, UK: Cambridge University Press, 1997.
2.
MillsNJ. Polymer foams handbook: engineering and biomechanics applications and design guide. Oxford: Butterworth-Heinemann, 2007.
3.
OzturkUEAnlasG. Hydrostatic compression of anisotropic low density polymeric foams under multiple loadings and unloadings. Polym Test2011; 30(7): 737–742.
4.
IsaacMDIshaiO. Engineering mechanics of composite materials. Oxford, UK: Oxford University Press, 2005.
5.
WeiXXChauKT. Finite and transversely isotropic elastic cylinders under compression with end constraint induced by friction. Int J Solids Struct2009; 46(9): 1953–1965.
6.
OgdenRW. Large deformation isotropic elasticity – on the correlation of theory and experiment for in compressible rubber like solids. Proc R Soc London Ser A1972; 326(1567): 565–584.
7.
OgdenRW. Non-linear elastic deformations. New York: Dover, 1997.
8.
WiddleRDBajajAKDaviesP. Measurement of the Poisson’s ratio of flexible polyurethane foam and its influence on a uniaxial compression model. Int J Eng Sci2008; 46(1): 31–49.
9.
GuoZYPengXQMoranB. A composites-based hyperelastic constitutive model for soft tissue with application to the human annulus fibrosus. J Mech Phys Solids2006; 54(9): 1952–1971.
10.
PengXQGuoZYMoranB. An anisotropic hyperelastic constitutive model with fiber-matrix shear interaction for the human annulus fibrosus. Trans ASME J Appl Mech2006; 73(5): 815–824.
JemioloSTelegaJJ. Transversely isotropic materials undergoing large deformations and application to modelling of soft tissues. Mech Res Commun2001; 28(4): 397–404.
13.
TagarielliVLDeshpandeVSFleckNA. A constitutive model for transversely isotropic foams, and its application to the indentation of balsa wood. Int J Mech Sci2005; 47(4–5): 666–686.
14.
Zhurov AI, Evans SL, Holt CA, et al. A nonlinear compressible transversely isotropic viscohyperelastic constitutive model of the periodontal ligament. In: Proceedings of the ASME international mechanical engineering congress and exposition 2008, Boston, MA, vol. 2, paper no. IMECE2008-67949, pp.707–719, 31 October–6. November. New York: ASME.
15.
ZhurovAILimbertGAeschlimannDP. A constitutive model for the periodontal ligament as a compressible transversely isotropic visco-hyperelastic tissue. Comput Meth Biomech Biomed Eng2007; 10(3): 223–235.
16.
GuoZYCanerFPengXQ. On constitutive modelling of porous neo-Hookean composites. J Mech Phys Solids2008; 56(6): 2338–2357.
17.
GuoZYCanerFC. Mechanical behaviour of transversely isotropic porous neo-Hookean solids. Int J Appl Mech2010; 2(1): 11–39.
18.
ASTM D1621:2004. Standard test method for compressive properties of rigid cellular plastics.
19.
HaojiangDWeiqiuCLiangchiZ. Elasticity of transversely isotropic materials. New York: Springer, 2006.
20.
MillsNJStampfliRMaroneF. Finite element micromechanics model of impact compression of closed-cell polymer foams. Int J Solids Struct2009; 46(3–4): 677–697.
21.
TwizellEHOgdenRW. Non-Linear optimization of the material constants in Ogden’s stress-deformation function for incompressible isotropic elastic materials. J Aust Math Soc Ser B1983; 24: 424–434.
22.
SurhoneLMTennoeMTHenssonowSF. ImageJ. Saarbrücken, Germany: VDM Verlag Dr. Mueller AG & Co. Kg, 2010.
23.
British Standard. BS ISO 1922:2001. Rigid cellular plastics — determination of shear strength.
24.
FreiHOxlandTRRathonyiGC. The effect of nucleotomy on lumbar spine mechanics in compression and shear loading. Spine2001; 26(19): 2080–2089.
25.
Linear elastic behaviour. In: ABAQUS user manual. Ver. 6.8. Section 18.2.1. Providence, RI: Simulia Corporation, 2008.
26.
Fitting of elastomeric foam test data. In: ABAQUS user manual. Ver. 6.8. Section 3.1.5. Providence, RI: Simulia Corporation, 2008.
27.
MillsNJMasso-MoreuY. Finite element analysis (FEA) applied to polyethylene foam cushions in package drop tests. Packag Technol Sci2005; 18(1): 29–38.
