Modeling the dynamic crushing of closed-cell polyethylene and polystyrene foams

Mills, N. J.

doi:10.1177/0021955x10397765

Cited by 4 publications

(2 citation statements)

References 23 publications

(34 reference statements)

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“…The third method is micro‐mechanical finite element model (FEM). Mills established micro‐mechanical FEM for the PE foam, where dynamic finite element analysis (FEA) made accurate quantitative predictions based on the inner structure of the PE foam disregarding of defects and irregular cells that are intrinsic to their structure. However, the analysis of the micro‐mechanical model can be computationally complicated.…”

Section: Introductionmentioning

confidence: 99%

A phenomenological constitutive modelling of polyethylene foam under multiple impact conditions

Hua

Wang

et al. 2019

Packag Technol Sci

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This paper extends the knowledge into the mechanical behaviour characterizations and constitutive modelling of polyethylene (PE) foam under multiple loading and unloading. The mechanical properties of PE foam subjected to single loading cases can be obtained by uniaxial compressive tests at quasi‐static and dynamic states. And the multiple loading and unloading behaviours of the foam can be revealed by consecutive drop tests. The major objective of this research is to propose a phenomenological model consists of shape function and modulus function, which can be predicted compressive response of PE foam for single loading cases. The constitutive models of foamed PE under multiple loading and unloading conditions are established by both using hyperbolic function, where the relations between coefficients and residual strain are introduced. And then, experiments are conducted to validate the proposed model by comparing the constitutive models proposed in this paper and those predicting by finite element software ABAQUS with those by experiments, showing that the proposed models are more accurate for predicting acceleration‐times curves of multiple drop scenarios.

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Section: Introductionmentioning

confidence: 99%

A phenomenological constitutive modelling of polyethylene foam under multiple impact conditions

Hua

Wang

et al. 2019

Packag Technol Sci

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“…Most of the foam researchers focused on impact behavior corresponding to high strain rate [3][4][5] and compression using finite element model. [6][7][8] The compression behavior becomes important when referring to longterm product storage. Therefore, it is crucial to understand the nature of foam microstructure when subjected to compression.…”

Section: Introductionmentioning

confidence: 99%

Monitoring deformation mechanism of foam cells in polyethylene foams via optical microscopy: Effect of density and microstructure

Zakaria

Ariff

Bakar

2018

Journal of Cellular Plastics

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The effect of cellular microstructure and density of low-density polyethylene (LDPE) foam during the compressive deformation were evaluated. Progressive foam cell structure deformation at crosshead speed of 10 mm/min was closely monitored and captured using a portable digital microscope with the assistance of a proposed coating technique to enhance contrast of the foam cells. Results revealed that higher density foam, LDPE1.0, experienced higher compressive stress than the LDPE0.5 foam. It was believed that thicker cell walls in the LDPE1.0 foam contributed to the foam stiffness and higher stress was required to impose cell bending, buckling, and collapse. It was also discovered that the existence of larger cells within a group or cluster of small cells in the LDPE1.0 foam acted as stress concentration points and initiated the formation of shear bands in the foam cells deformation mechanism. The extent of compressive strain on the foam cells were also investigated, and results showed that cells undergo lower compressive strain compared to the actual deformation level given directly by the machine crosshead. Cells located in the middle section of the foam recorded a strain

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Anisotropy of the stiffness and strength of rigid low-density closed-cell polyisocyanurate foams

et al. 2016

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Modeling the dynamic crushing of closed-cell polyethylene and polystyrene foams

Cited by 4 publications

References 23 publications

A phenomenological constitutive modelling of polyethylene foam under multiple impact conditions

A phenomenological constitutive modelling of polyethylene foam under multiple impact conditions

Monitoring deformation mechanism of foam cells in polyethylene foams via optical microscopy: Effect of density and microstructure

Anisotropy of the stiffness and strength of rigid low-density closed-cell polyisocyanurate foams

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