Journal
POLYMERS
Volume 14, Issue 17, Pages -Publisher
MDPI
DOI: 10.3390/polym14173466
Keywords
recycling; opaque PET; mechanical properties; fatigue; fracture
Categories
Funding
- EU/FEDER: European Regional Development funds through the project RevalPET'UP (EU Interreg H2020 program through project POCTEFA) [EFA329/19]
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Polyethylene terephthalate (PET) is widely used in large-scale manufacturing as a thermoplastic polymer. Opaque PET is increasingly used in milk bottles for weight savings and a glossy white appearance. However, recycling opaque PET is a challenge. A recent study shows that the mechanical properties of recycled PET can be improved through reactive extrusion. This study evaluates the lifespan of recycled opaque PET during different steps of the recycling process.
Polyethylene terephthalate (PET) is among the most used thermoplastic polymers in large scale manufacturing. Opaque PET is increasingly used in milk bottles to save weight and to bring a glossy white aspect due to TiO2 nanoparticles. The recyclability of opaque PET is an issue: whereas the recycling channels are well established for transparent PET, the presence of opaque PET in household wastes weakens those channels: opaque bottles cannot be mixed with transparent ones because the resulting blend is not transparent anymore. Many research efforts focus on the possibility to turn opaque PET into resources, as one key to a more circular economy. A recent study has demonstrated the improvement of the mechanical properties of recycled PET through reactive extrusion. In the present work, the lifespan of recycled opaque PET has been evaluated throughout tensile-tensile fatigue loading cycles at various steps of the recycling process: The specimens are obtained from flakes after grinding PET wastes (F-r-OPET), from a subsequent homogenization step (r-OPET-hom) and after reactive extrusion (Rex-r-OPET). Virgin PET is also considered as a comparison. First, tensile tests monitored by digital image correlation have been carried out to obtain the elastic modulus and ultimate tensile stress of each type of PET. The fatigue properties of reactive REx-r-OPET increase, probably associated with the rise of cross-linking and branching rates. The fatigue lifespan increases with the macromolecular weight. The fracture surface analysis of specimens brings new insight regarding the factors governing the fatigue behavior and the damaging mode of recycled PET. TiO2 nanoparticles act as stress concentrators, contributing to void formation at multiple sites and thus promoting the fracture process. Finally, the fatigue life of REx-r-OPET is comparable to those of virgin PET. Upcycling opaque PET by reactive extrusion may be a relevant new route to absorb some of the growing amounts of PET worldwide.
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