Mechanical Recycling of Partially Bio-Based and Recycled Polyethylene Terephthalate Blends by Reactive Extrusion with Poly(styrene- co -glycidyl methacrylate)

In the present study, partially bio-based polyethylene terephthalate (bio-PET) was melt-mixed at 15-45 wt% with recycled polyethylene terephthalate (r-PET) obtained from remnants of the injection blowing process of contaminant-free food-use bottles. The resultant compounded materials were thereafter...

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Veröffentlicht in:	Polymers 2020-01, Vol.12 (1), p.174
Hauptverfasser:	Montava-Jorda, Sergi, Lascano, Diego, Quiles-Carrillo, Luis, Montanes, Nestor, Boronat, Teodomiro, Martinez-Sanz, Antonio Vicente, Ferrandiz-Bou, Santiago, Torres-Giner, Sergio
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Sprache:	eng
Schlagworte:	Biodegradability Biopolymers Chain branching Chains Contaminants Copolymers Dimensional stability Ductility Elongation Emission standards Environmental impact Extrusion rate High density polyethylenes Impact strength Injection molding Macromolecules Mechanical properties Plastics Polyester resins Polyethylene terephthalate Polymer blends Polystyrene resins Recycling Reprocessing Rheology Styrenes Toughness Viscosity
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description	In the present study, partially bio-based polyethylene terephthalate (bio-PET) was melt-mixed at 15-45 wt% with recycled polyethylene terephthalate (r-PET) obtained from remnants of the injection blowing process of contaminant-free food-use bottles. The resultant compounded materials were thereafter shaped into pieces by injection molding for characterization. Poly(styrene- -glycidyl methacrylate) (PS- -GMA) was added at 1-5 parts per hundred resin (phr) of polyester blend during the extrusion process to counteract the ductility and toughness reduction that occurred in the bio-PET pieces after the incorporation of r-PET. This random copolymer effectively acted as a chain extender in the polyester blend, resulting in injection-molded pieces with slightly higher mechanical resistance properties and nearly the same ductility and toughness than those of neat bio-PET. In particular, for the polyester blend containing 45 wt% of r-PET, elongation at break (ε ) increased from 10.8% to 378.8% after the addition of 5 phr of PS- -GMA, while impact strength also improved from 1.84 kJ·m to 2.52 kJ·m . The mechanical enhancement attained was related to the formation of branched and larger macromolecules by a mechanism of chain extension based on the reaction of the multiple glycidyl methacrylate (GMA) groups present in PS- -GMA with the hydroxyl (-OH) and carboxyl (-COOH) terminal groups of both bio-PET and r-PET. Furthermore, all the polyester blend pieces showed thermal and dimensional stabilities similar to those of neat bio-PET, remaining stable up to more than 400 °C. Therefore, the use low contents of the tested multi-functional copolymer can successfully restore the properties of bio-based but non-biodegradable polyesters during melt reprocessing with their recycled petrochemical counterparts and an effective mechanical recycling is achieved.
doi_str_mv	10.3390/polym12010174
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The resultant compounded materials were thereafter shaped into pieces by injection molding for characterization. Poly(styrene- -glycidyl methacrylate) (PS- -GMA) was added at 1-5 parts per hundred resin (phr) of polyester blend during the extrusion process to counteract the ductility and toughness reduction that occurred in the bio-PET pieces after the incorporation of r-PET. This random copolymer effectively acted as a chain extender in the polyester blend, resulting in injection-molded pieces with slightly higher mechanical resistance properties and nearly the same ductility and toughness than those of neat bio-PET. In particular, for the polyester blend containing 45 wt% of r-PET, elongation at break (ε ) increased from 10.8% to 378.8% after the addition of 5 phr of PS- -GMA, while impact strength also improved from 1.84 kJ·m to 2.52 kJ·m . The mechanical enhancement attained was related to the formation of branched and larger macromolecules by a mechanism of chain extension based on the reaction of the multiple glycidyl methacrylate (GMA) groups present in PS- -GMA with the hydroxyl (-OH) and carboxyl (-COOH) terminal groups of both bio-PET and r-PET. Furthermore, all the polyester blend pieces showed thermal and dimensional stabilities similar to those of neat bio-PET, remaining stable up to more than 400 °C. 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The resultant compounded materials were thereafter shaped into pieces by injection molding for characterization. Poly(styrene- -glycidyl methacrylate) (PS- -GMA) was added at 1-5 parts per hundred resin (phr) of polyester blend during the extrusion process to counteract the ductility and toughness reduction that occurred in the bio-PET pieces after the incorporation of r-PET. This random copolymer effectively acted as a chain extender in the polyester blend, resulting in injection-molded pieces with slightly higher mechanical resistance properties and nearly the same ductility and toughness than those of neat bio-PET. In particular, for the polyester blend containing 45 wt% of r-PET, elongation at break (ε ) increased from 10.8% to 378.8% after the addition of 5 phr of PS- -GMA, while impact strength also improved from 1.84 kJ·m to 2.52 kJ·m . 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subjects	Biodegradability Biopolymers Chain branching Chains Contaminants Copolymers Dimensional stability Ductility Elongation Emission standards Environmental impact Extrusion rate High density polyethylenes Impact strength Injection molding Macromolecules Mechanical properties Plastics Polyester resins Polyethylene terephthalate Polymer blends Polystyrene resins Recycling Reprocessing Rheology Styrenes Toughness Viscosity
title	Mechanical Recycling of Partially Bio-Based and Recycled Polyethylene Terephthalate Blends by Reactive Extrusion with Poly(styrene- co -glycidyl methacrylate)
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