Abstract
Stretching PET at a high strain rate above the glass transition temperature has a positive effect on the strength of the material. In a recent paper[1], we presented the influence of stretch and blow molding parameters on the properties of the final product, especially on the crystallinity induced by stretching. In this paper, we focus on the effects of loading, temperature, elongation and strain rate on macromolecular orientation and crystallization kinetics. We present experimental results from uniaxial and biaxial elongation tests carried out on injected PET specimens. To minimize the effect of quiescent crystallization, specimens are quickly heated with infrared lamps before the test and temperature is regulated during the test. Both uniaxial and biaxial tests are analyzed using a cross correlation technique[2] that compares a picture used as reference and the picture of the deformed specimen. This technique allows us to determine all strain components at each point of the specimen, even when the strain field is not homogeneous. In a second part, we present measurements of macromolecular orientation and crystallinity ratio performed after each test. The infrared dichroïsm technique is used to determine the orientation of the microscopic morphology of PET before and after the testing. DSC measurements and density measurements are carried out to calculate the crystallinity ratio. Influences of strain rate, temperature and strain path sequence are evaluated in order to build a database for recent models of induced crystallization[3],[4],[5].
Highlights
What we present here is part of a global study of the injection blow-molding process of PET (PolyEthylene Terephthalate) bottles
PET is widely implanted in the plastic bottles market: the consumption of PET bottles increased from 2,8 million tons in 1995 to 5,3 million tons in the year 2000
We present typical tension and relaxation results and the strain hardening index (SHI) and relaxation characteristics (9, crr) with respect to the strain rate and the temperature imposed during the tension test
Summary
What we present here is part of a global study of the injection blow-molding process of PET (PolyEthylene Terephthalate) bottles. Blow molding machines make PET bottles from injected preforms. These preforms are heated up and blown up through bi-orientational -longitudinal radial- stretching. Like most polymers PET has a low heating conductivity. Heating techniques using convection or conduction require a long heating time, and lead to microstructure heterogeneity between the skin and the core of material. An alternative is radiation heating with infrared waves: solution used industrially. It leaves one face of the specimen available for image acquisition with a CCD camera
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