Relation between thermal effects and structural changes under deformation of thermoplastics

The article reports thermal effects accompanying deformation of widely used thermoplastics: PE of different density, highly isotactic and stereodefective PP, PA6, PC. A number of structural methods (X-ray diffraction at large and small angles, DSC, IR spectroscopy, microscopy, volume measurements) w...

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Bibliographic Details
Published in:Polymer (Guilford) 2018-05, Vol.144, p.18-32
Main Authors: Guseva, M.A., Gerasin, V.A., Shklyaruk, B.F., Dubinskiy, V.A.
Format: Article
Language:English
Subjects:
Crystallization
Crystallography
Crystals
Data processing
Deformation
Deformation effects
Deformation mechanism
Deformation mechanisms
Degree of crystallinity
Entropy
Heat
Heat generation
Heat sources
Infrared spectroscopy
Internal friction
Isotacticity
Lamellae
Microscopy
Necking
Phase transitions
Plastic deformation
Plastics
Polyethylenes
Polymers
Polyolefins
Pore formation
Surface tension
Temperature effects
Thermal effects
Thermal energy
Thermoplastic polymers
Thermoplastic resins
Thermoplastics
X-ray diffraction
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Summary:The article reports thermal effects accompanying deformation of widely used thermoplastics: PE of different density, highly isotactic and stereodefective PP, PA6, PC. A number of structural methods (X-ray diffraction at large and small angles, DSC, IR spectroscopy, microscopy, volume measurements) were used to establish the factors underlying generation of heat under tension. In all the polymers studied, the greatest temperature and structural changes are observed in the second stage of deformation, when the neck is being formed. For polyolefins the temperature jump at the transition to the neck was found to correlate with the degree of crystallinity. Analysis of structural data showed that for these polymers the most important heat sources are the following structural processes: decrease in entropy of polymer chains due to orientation, appearance and growth of cavities, strain-induced crystallization of a part of amorphous phase. In the PEs, studied in this work, the crystallographic modification does not change under plastic deformation. In highly isotactic PP a part of initial α-crystals lose three-dimensional ordering and transform into the mesomorphic form during fragmentation of lamellae. In PA6 necking triggers transition from a less ordered γ-phase to a more stable α-modification, which proceeds in parallel with the crystallization of a part of the amorphous phase in the α-form. When the glassy amorphous PC is deformed, phase transformations, crystallization and pore formation do not occur. In this polymer, processes of internal friction are supposed to be the main cause of heat generation during deformation. Structural factors responsible for heat generation during deformation. [Display omitted] •Relationship between temperature and structural changes was analyzed.•In polyolefins temperature rise at necking is roughly proportional to crystallinity.•Main sources of heat at necking are orientation and cavitation.•Others are strain-induced crystallization, phase transformation, internal friction.
ISSN:0032-3861
1873-2291
DOI:10.1016/j.polymer.2018.04.023