Numerical Simulation of the Viscohyperelastic Behaviour of PET near the Glass Transition Temperature

Yun Mei Luo; Luc Chevalier; Eric Monteiro

doi:10.4028/www.scientific.net/KEM.504-506.1139

Paper Titles

The Effect of Temperature, Strain Rate and Strain on the Induced Mechanical Properties of Biaxially Stretched PET
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Mechanical Behavior of Highly-Flexible Elastomeric Composites with Knitted-Fabric Reinforcement
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Measurement and Modelling of Chemical Shrinkage of Thermoset Composites
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The Effect of Thermoforming of PLA-PHBV Films on the Morphology and Gas Barrier Properties
p.1135

Numerical Simulation of the Viscohyperelastic Behaviour of PET near the Glass Transition Temperature
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Shape Evolution of Carbon Epoxy Laminated Composite during Curing
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Structure of Polymer – Multiwall Carbon Nanotube Composites
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Development of a Process Evaluation System for Wire-EDM Applications Using an Intelligent Process Monitoring Tool
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Wire-EDM of ZTA-TiC Composites with Variable Content of Electrically Conductive Phase
p.1165

HomeKey Engineering MaterialsKey Engineering Materials Vols. 504-506Numerical Simulation of the Viscohyperelastic...

Numerical Simulation of the Viscohyperelastic Behaviour of PET near the Glass Transition Temperature

Abstract:

The presentation deals with the non linear strongly elastic and viscous behaviour of poly ethylene terephthalate near the glass transition temperature and biaxially stretched at high strain rates representative of the injection stretch blow moulding process. A non linear visco-hyperelastic model inspired from [1] and identified from the experimental results of the equi-biaxial tension test [2], have been developed and presented in [3] is implemented into a finite element code developed with Matlab. The thermal behaviour modelling, identification and simulation has also been managed. First, a numerical simulation of 2D plane stress case has been performed involving 2 fields (global velocity V and elastic Cauchy Green tensor Be). Rectangular finite elements with quadratic and linear interpolations have been employed for velocity and the elastic left Cauchy Green tensor. Second, an axi symmetric formulation involving 4 fields (global velocity V, lagrange multiplier p associated with the global incompressibility condition, and multiplier q associated with the incompressibility of the elastic part) has been performed using rectangular elements. Degree of interpolation have been tested for all possible combinations to test the LBB like condition. Both simulations are compared with equi biaxial or sequential biaxial testing in order to reproduce the strain hardening effect and the self-heating observed. The final goal of this work is to perform the free blowing simulation to compare with experimental data. Therefore, we should solve an iterative procedure for a thermo-mechanical equation. At each time step, a four-field approach is adopted for the mechanical part, and a classical heat transfer equation is discretised for the thermal part.

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Periodical:

Key Engineering Materials (Volumes 504-506)

Pages:

1139-1144

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.504-506.1139

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Online since:

February 2012

Authors:

Yun Mei Luo, Luc Chevalier, Eric Monteiro

Keywords:

Non-Linear Behavior, Numerical Simulation, Thermo-Mechanical Equation, Viscohyperelastic

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References

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