Recycled Polymers: Eco-Design, Structure/Property Relationships and Compatibility

The efficient ecodesign of secondary raw materials from recycled multiphase polymer systems is performed through the study of various things, such as: The compatibility of mixtures of recycled polymers where work on knowledge of the miscibility of mixtures depends on the different rates and the natu...

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description The efficient ecodesign of secondary raw materials from recycled multiphase polymer systems is performed through the study of various things, such as: The compatibility of mixtures of recycled polymers where work on knowledge of the miscibility of mixtures depends on the different rates and the nature of the constituents;The aging of recycled polymers in terms of the structuring of end-of-life polymers, which may have changed their starting structure due to degradation or aging;The compatibility of mixtures of polymers recycled by additive treatments and/or reactive pre-treatments and integration of coupling agents or reactants in situ at the interface of the mixtures; this compatibility can be linked beforehand to reactive pre-treatments (plasma, corona, heat/chemical treatments) on each of the phases. The selection of these three themes follows a study cycle logic on the development of formulations of blends of recycled polymers, in which compatibilization affects the morphology and therefore the miscibility of blends of polymers in relation to their structure.
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institution Directory of Open Access Books
language eng
publishDate 2024
publishDateRange 2024
publishDateSort 2024
publisher MDPI - Multidisciplinary Digital Publishing Institute
publisherStr MDPI - Multidisciplinary Digital Publishing Institute
record_format ojs
spelling doab-20.500.12854ir-1375122024-05-14T13:21:18Z Recycled Polymers: Eco-Design, Structure/Property Relationships and Compatibility Perrin, Didier mechanical recycling impact resistance WEEE polymer compatibilization design of experiments surface response methodology PTFE nanoparticles microwave recycled Fe2O3 complex permittivity complex permeability recycling plastics waste extrusion polyethylene/polyamide blends compatibility physical properties structure methyl methacrylate PMMA recycling Monte Carlo economic analysis regenerated MMA depolymerization scenario net present value (NPV) payback period risk analysis textile recycling pyrolysis enzymatic hydrolysis ammonolysis glycolysis IoT sorting identification thermoplastic composites basalt fibers ultrasound mechanical properties crystalline poly(ethylene terephthalate) post-industrial recycling polymer processing biofillers coffee chaff rice hull plastic-aggregate ABS mortar flexural strength rupture thermochemical conversion process waste recycling waste-to-energy waste treatment synthetic fiber natural rubber scrap rubber oil absorbency foam waste blow molding polyethylene environmental stress cracking resistance cracked round bar specimens recyclate fatigue slow crack growth plastic recycling compounding thermoforming melt mass-flow rate polypropylene post-consumer thema EDItEUR::P Mathematics and Science::PB Mathematics::PBW Applied mathematics The efficient ecodesign of secondary raw materials from recycled multiphase polymer systems is performed through the study of various things, such as: The compatibility of mixtures of recycled polymers where work on knowledge of the miscibility of mixtures depends on the different rates and the nature of the constituents;The aging of recycled polymers in terms of the structuring of end-of-life polymers, which may have changed their starting structure due to degradation or aging;The compatibility of mixtures of polymers recycled by additive treatments and/or reactive pre-treatments and integration of coupling agents or reactants in situ at the interface of the mixtures; this compatibility can be linked beforehand to reactive pre-treatments (plasma, corona, heat/chemical treatments) on each of the phases. The selection of these three themes follows a study cycle logic on the development of formulations of blends of recycled polymers, in which compatibilization affects the morphology and therefore the miscibility of blends of polymers in relation to their structure. 2024-05-14T13:21:08Z 2024-05-14T13:21:08Z 2024 book ONIX_20240514_9783725800025_114 9783725800025 9783725800018 https://directory.doabooks.org/handle/20.500.12854/137512 eng application/octet-stream Attribution-NonCommercial-NoDerivatives 4.0 International https://mdpi.com/books/pdfview/book/8671 https://mdpi.com/books/pdfview/book/8671 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-7258-0001-8 10.3390/books978-3-7258-0001-8 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783725800025 9783725800018 246 open access
spellingShingle mechanical recycling
impact resistance
WEEE
polymer compatibilization
design of experiments
surface response methodology
PTFE
nanoparticles
microwave
recycled Fe2O3
complex permittivity
complex permeability
recycling
plastics waste
extrusion
polyethylene/polyamide blends
compatibility
physical properties
structure
methyl methacrylate
PMMA recycling
Monte Carlo
economic analysis
regenerated MMA
depolymerization
scenario
net present value (NPV)
payback period
risk analysis
textile recycling
pyrolysis
enzymatic hydrolysis
ammonolysis
glycolysis
IoT
sorting identification
thermoplastic composites
basalt fibers
ultrasound
mechanical properties
crystalline poly(ethylene terephthalate)
post-industrial recycling
polymer processing
biofillers
coffee chaff
rice hull
plastic-aggregate
ABS
mortar
flexural strength
rupture
thermochemical conversion process
waste recycling
waste-to-energy
waste treatment
synthetic fiber
natural rubber
scrap rubber
oil absorbency
foam
waste
blow molding
polyethylene
environmental stress cracking resistance
cracked round bar specimens
recyclate
fatigue
slow crack growth
plastic recycling
compounding
thermoforming
melt mass-flow rate
polypropylene
post-consumer
thema EDItEUR::P Mathematics and Science::PB Mathematics::PBW Applied mathematics
Recycled Polymers: Eco-Design, Structure/Property Relationships and Compatibility
title Recycled Polymers: Eco-Design, Structure/Property Relationships and Compatibility
title_full Recycled Polymers: Eco-Design, Structure/Property Relationships and Compatibility
title_fullStr Recycled Polymers: Eco-Design, Structure/Property Relationships and Compatibility
title_full_unstemmed Recycled Polymers: Eco-Design, Structure/Property Relationships and Compatibility
title_short Recycled Polymers: Eco-Design, Structure/Property Relationships and Compatibility
title_sort recycled polymers eco design structure property relationships and compatibility
topic mechanical recycling
impact resistance
WEEE
polymer compatibilization
design of experiments
surface response methodology
PTFE
nanoparticles
microwave
recycled Fe2O3
complex permittivity
complex permeability
recycling
plastics waste
extrusion
polyethylene/polyamide blends
compatibility
physical properties
structure
methyl methacrylate
PMMA recycling
Monte Carlo
economic analysis
regenerated MMA
depolymerization
scenario
net present value (NPV)
payback period
risk analysis
textile recycling
pyrolysis
enzymatic hydrolysis
ammonolysis
glycolysis
IoT
sorting identification
thermoplastic composites
basalt fibers
ultrasound
mechanical properties
crystalline poly(ethylene terephthalate)
post-industrial recycling
polymer processing
biofillers
coffee chaff
rice hull
plastic-aggregate
ABS
mortar
flexural strength
rupture
thermochemical conversion process
waste recycling
waste-to-energy
waste treatment
synthetic fiber
natural rubber
scrap rubber
oil absorbency
foam
waste
blow molding
polyethylene
environmental stress cracking resistance
cracked round bar specimens
recyclate
fatigue
slow crack growth
plastic recycling
compounding
thermoforming
melt mass-flow rate
polypropylene
post-consumer
thema EDItEUR::P Mathematics and Science::PB Mathematics::PBW Applied mathematics
topic_facet mechanical recycling
impact resistance
WEEE
polymer compatibilization
design of experiments
surface response methodology
PTFE
nanoparticles
microwave
recycled Fe2O3
complex permittivity
complex permeability
recycling
plastics waste
extrusion
polyethylene/polyamide blends
compatibility
physical properties
structure
methyl methacrylate
PMMA recycling
Monte Carlo
economic analysis
regenerated MMA
depolymerization
scenario
net present value (NPV)
payback period
risk analysis
textile recycling
pyrolysis
enzymatic hydrolysis
ammonolysis
glycolysis
IoT
sorting identification
thermoplastic composites
basalt fibers
ultrasound
mechanical properties
crystalline poly(ethylene terephthalate)
post-industrial recycling
polymer processing
biofillers
coffee chaff
rice hull
plastic-aggregate
ABS
mortar
flexural strength
rupture
thermochemical conversion process
waste recycling
waste-to-energy
waste treatment
synthetic fiber
natural rubber
scrap rubber
oil absorbency
foam
waste
blow molding
polyethylene
environmental stress cracking resistance
cracked round bar specimens
recyclate
fatigue
slow crack growth
plastic recycling
compounding
thermoforming
melt mass-flow rate
polypropylene
post-consumer
thema EDItEUR::P Mathematics and Science::PB Mathematics::PBW Applied mathematics
url ONIX_20240514_9783725800025_114