Experimental and theoretical study of the peculiarities of the thermo‐mechanical behavior of semicrystalline polymers

Glot, I.; Golotina, L. A.; Шардаков, И. Н.

doi:10.1002/pc.23463

Cited by 2 publications

(2 citation statements)

References 14 publications

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“…To further justify our assumption about the chain network and structural relaxation mechanisms of glassy polymers, we note that it is quite necessary to test a constitutive model rested on the assumption with multistep deformation and stress relaxation experiments. [ 31,60–64 ] However, this cannot be achieved yet in the present work. The main reason is that weak linkages in the chain network can re‐associate/reform after dissociation, and this linkage re‐association is not considered in the extended AAS model yet.…”

Section: Network Linkage Dissociationmentioning

confidence: 72%

Experimental and constitutive analyses of the stress relaxation behavior of glassy polymers

Liu

Wang

Zhang

et al. 2023

Polymer Engineering & Sci

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The physical mechanism underlying the mechanical behavior of glassy polymers has been studied over decades but remains a long‐standing issue. A consensus view achieved is that the yield, flow, and stress relaxation behaviors are due to structural relaxation in the polymer mainly caused by chain conformation transitions. This is the key physical idea behind the many existing elastic–plastic constitutive models for glassy polymers. In this paper, such a constitutive model was employed for predicting and analyzing the stress relaxation of a glassy polymer. It is found that the model works well in predicting the pre‐yield stress relaxation but significantly underestimates the post‐yield stress relaxation. As considering the chain conformation transition alone leads to a dilemma for the model to concurrently represent the yield/flow and stress relaxation behaviors, the model was extended to incorporate an additional structural relaxation mechanism assumed to originate from the dissociation of weak linkages in the chain network. The extended model succeeds in concurrently representing the yield/flow, and stress relaxation behaviors in the whole deformation region, of which the reasons were analyzed. The knowledge revealed in this paper is instructive and may shed new light on understanding the structural relaxation and mechanical behavior of glassy polymers.

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Section: Network Linkage Dissociationmentioning

confidence: 72%

Experimental and constitutive analyses of the stress relaxation behavior of glassy polymers

Liu

Wang

Zhang

et al. 2023

Polymer Engineering & Sci

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“…These regimes determine the sequence through which the stages of evolution of the workpiece material (polymerization, curing, glass transition, etc.) pass, as well as dictating the formation of technological and process-induced strains [13].…”

Section: Prepreg Technologies and Methods For Compression Mouldingmentioning

confidence: 99%

Temperature and strain registration by fibre-optic strain sensor in the polymer composite materials manufacturing

Матвеенко

Kosheleva

Шардаков

et al. 2018

International Journal of Smart and Nano Materials

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The presence of process-induced strains induced by various manufacturing and operational factors is one of the characteristics of polymer composite materials (PCM). Conventional methods of registration and evaluation of process-induced strains can be laborious, time-consuming and demanding in terms of technical applications. The employment of embedded fibre-optic strain sensors (FOSS) offers a real prospect of measuring residual strains. This paper demonstrates the potential for using embedded FOSS for recording technological strains in a PCM plate. The PCM plate is manufactured from prepreg, using the direct compression-moulding method. In this method, the prepared reinforcing package is placed inside a mould, heated, and then exposed to compaction pressure. The examined technology can be used for positioning FOSS between the layers of the composite material. Fibre-optic sensors, interacting with the material of the examined object, make it possible to register the evolution of the strain process during all stages of polymer-composite formation. FOSS data were recorded with interrogator ASTRO X 327. The obtained data were processed using specially developed algorithms.

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Experimental and theoretical study of the peculiarities of the thermo‐mechanical behavior of semicrystalline polymers

Cited by 2 publications

References 14 publications

Experimental and constitutive analyses of the stress relaxation behavior of glassy polymers

Experimental and constitutive analyses of the stress relaxation behavior of glassy polymers

Temperature and strain registration by fibre-optic strain sensor in the polymer composite materials manufacturing

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