Recycling of Glass Fiber Composites

Krishnamoorthi, Ramesh, Shinzhao, Zhang

January 2012

Composites are the materials which can be used for a wide variety of applications andproducts such as sports equipment, aerospace and marine because of light and stiffnessproperties. Composites are often made from thermoset resin with glass fibers.In this study, two ways of recycling composites were evaluated, which are microwavepyrolysed composites (MGC) and mechanical composites (GC). These glass fibers weregoing to be compounded with Polypropylene (PP) or Maleic Anhydride ModifiedPolypropylene (MAPP) and then injection moulded the sample by Micro-compounder.In order to get better adhesion to the polymer, a coating was added. The Neoxil 5682-polypropylene water emulsion was evaluated.The samples were characterized by Tensile Testing, Thermogravimetric Analysis (TGA),Different Scanning Calorimetry (DSC), and Dynamic Mechanical Analysis (DMA) to find aoptimum combination of recycled glass fiber reinforced polymer.Microwave pyrolysis is a new research area. The glass fiber, polymer oil and gas can beobtained by heating the composite with microwaves to in an inert atmosphere. The polymeroil can be distillated and then evaluated with GC-MS; in order to obtain the chemicalcompositions.Keywords: Composites, grinded and microwave pyrolyse composites (MGC), grindedcomposites (GC), Polypropylene (PP), Maleic Anhydride Modified Polypropylene (MAPP),Micro-compounder, Tensile Testing, Thermogravimetric Analysis (TGA), Different ScanningCalorimetry (DSC), and Dynamic Mechanical Analysis (DMA), Microwave pyrolysis,polymer oil, distillation, GCMS Analysis. / Program: MSc in Resource Recovery - Sustainable Engineering

polypropylene (pp)

grinded composites (gc)

neoxil

virgin glass fiber

caco3

hammer mill fiber

micro-compounder

injection

termogravimetric analysis (tga)

tensile testing

gcmsanalysis

dynamic mechanical analysis

microwavepyrolysis

different scanning calorimetry(dsc)

distillation

polymer oil

Engineering and Technology

Teknik och teknologier

Single-Step Covalent Functionalization of Polylactide Surfaces / Nano Patterened Covalent Surface Modification of Poly(ε-caprolactone)

Källrot, Martina

January 2005

<p>Degradable polymers have gained an increased attention in the field of biomedical applications over the past decades, for example in tissue engineering. One way of improving the biocompatibility of these polymers is by chemical surface modification, however the risk of degradation during the modification procedure is a limiting factor. In some biomedical applications, for example in nerve guides, a patterned surface is desired to improve the cell attachment and proliferation.</p><p>In this thesis a new non-destructive, single-step, and solvent free method for surface modification of degradable polymers is described. Poly(L-lactide) (PLLA) substrates have been functionalized with one of the following vinyl monomers; N-vinylpyrrolidone (VP), acrylamide (AAm), or maleic anhydride (MAH) grafts. The substrates were subjected to a vapor phase atmosphere constituted of a mixture of a vinyl monomer and a photoinitiator (benzophenone) in a closed chamber at very low pressure and under UV irradiation. Poly(ε-caprolactone) (PCL), poly(lactide-co-glycolide) (PLGA), and poly(trimethylene carbonate) (PTMC) have been surface modified with VP using the same procedure to show the versatility of the method. The wettability of all of the four substrates increased after grafting. The surface compositions were confirmed by ATR-FTIR and XPS. The VP grafted PLLA, PTMC and PLGA substrates have been shown to be good substrates for the normal human cells i.e. keratinocytes and fibroblasts, to adhere and proliferate on. The topography of substrates with well defined nano patterns was preserved during grafting, since the grafted layer is very thin. We have also shown that the method is useful for a simultaneous chemical and topographical modification of substrates by masked vapor phase grafting. The surface topography was determined with SEM and AFM.</p> / <p>Intresset för användningen av nedbrytbara polymerer till biomedicinska applikationer som till exempel vävnads rekonstruktion har ökat avsevärt de senaste decennierna. Ett sätt att öka biokompatibiliteten hos dessa polymerer är genom kemisk ytmodifiering, men risken för nedbrytning under själva modifieringen är en begränsande faktor. I vissa biomedicinska applikationer, till exempel nervguider, är det önskvärt att ha en väldefinierad ytstruktur för att öka vidhäftningen och tillväxten av celler.</p><p>I den här avhandlingen presenteras en ny ickeförstörande, lösningsmedelsfri enstegsprocess för ytmodifiering av nedbrytbara polymerer. Substrat av poly(L-laktid) (PLLA) har ytfunktionaliserats med var och en av följande vinylmonomerer, N-vinylpyrrolidon (VP), akrylamid (AAm) eller maleinsyraanhydrid (MAH). Substraten har exponerats för en gasfasatmosfär av en blandning av en vinylmonomer och en fotoinitiator (bensofenon) i en tillsluten reaktor vid mycket lågt tryck och under UV-strålning. Metodens mångsidighet har även påvisats genom att ytmodifiera substrat av poly(ε-kaprolakton) (PCL), poly(laktid-co-glykolid) (PLGA) och poly(trimetylen karbonat) (PTMC) med VP. Vätbarheten ökade för alla fyra materialen efter ympning med en vinylmonomer. Ytsammansättningen fastställdes med ATR-FTIR och XPS. De VP ympade filmerna av PLLA, PLGA och PTMC visade sig vara bra substrat för mänskliga celler, i detta fall keratinocyter och fibroblaster, att vidhäfta och växa på. Yttopografin hos filmer med väldefinierade nanomönstrade ytor kunde bevaras efter ympning, tack vare att det ympade lagret är så tunt. Gasfas metoden har också visat sig användbar för att simultant ytmodifiera både kemiskt och topografiskt genom maskad gasfasympning. Yttopografin bestämdes med SEM och AFM.</p>

Vapor phase grafting

covalent surface modification

solvent free

nano patterned topography

degradable polymers

poly(ε-caprolactone)

poly(L-lactide)

poly(lactide-co-glycolide)

poly(trimethylene carbonate)

N-vinylpyrrolidone

maleic anhydride

acrylamide

Gasfasympning

kovalent ytmodifiering

lösningsmedelsfri

nedbrytbara polymerer

nanomönstrad topografi

poly(L-laktid)

poly(ε-kaprolakton)

poly(laktid-co-glykolid)

poly(trimetylen karbonat)

N-vinylpyrrolidon

maleinsyraanhydrid

akrylamid

Polymer chemistry

Polymerkemi

Comportements thermomécaniques de polymères chargés selon différents chemins de déformation et traitements thermiques / Thermomechanical behaviours of filled polymers along various deformation paths and thermal treatments

Ponçot, Marc

28 October 2009

Le centre de recherche ArcelorMittal de Montataire développent de nouvelles solutions acier innovantes associant métal et polymère. Pour les ailes de voiture, le composite retenu est un matériau multicouche composé d’une lame d’acier sur laquelle est déposé un film mince de polypropylène choc chargé avec des particules minérales par l’intermédiaire d’une fine couche de polypropylène fonctionnalisé par le greffage d’anhydride maléique. Afin de prévoir et de connaitre le comportement de la partie organique du matériau lors de sa mise en forme par emboutissage et à posteriori de prédire l’état de ses propriétés mécaniques lors de son utilisation, la détermination des lois de comportement mécanique vrai et intrinsèque sur le modèle de la loi G’sell et Jonas est nécessaire. Ces lois sont définies selon trois chemins de déformation : la traction uniaxiale, le cisaillement simple et la traction plane. Les micromécanismes de déformation de la microstructure semi-cristalline des différentes formulations des matériaux selon leur mode de sollicitation mécanique ont été étudiés. Les résultats obtenus Post Mortem et In Situ ont permis la description qualitative et quantitative des évolutions des principales modifications microstructurales. Ces dernières diffèrent avec l’ajout de charges minérales. Deux nouvelles méthodes, la Tomographie X et la spectroscopie Raman permettent la détermination de la déformation volumique dans le cas de matériau de géométrie fine (300 µm). Le retrait lors d’un cycle thermique est étudié. Les influences du chauffage, de la formulation et de la microstructure (orientation des chaînes macromoléculaires et endommagement volumique) sont décrites / The ArcelorMittal research centre of Montataire elaborates innovative steel / polymer products. In the case of automotive fenders, the composite is a multilayered material. A thin impact polypropylene film is laminated on steel using a thin layer of a functionalized polypropylene. Mineral particles are added to improve stiffness. In order to predict and understand the behaviour of the organic layer all along its production process and finally to be able to characterize the state of its mechanical properties in use, the determination of the true and intrinsic mechanical behaviour laws according to the G’sell and Jonas model is necessary. These laws are obtained for three different mechanical paths: uniaxial tensile, simple shear and plane tensile. The deformation micromechanisms of the impact polypropylene semi-crystalline microstructure which depend on the materials formulations and on the mechanical path used are studied. Post Mortem and In Situ results give qualitative and quantitative description of the main microstructural modifications. Two new methods, X Tomography and Raman spectroscopy allow the quantification of the volume deformation which is developed during tensile tests. They are mainly available for very thin samples. X radiography and VideoTraction™ are not suitable anymore for this kind of geometry. Finally, the thermo-mechanical phenomenon of shrinkage which occurs during thermal treatment above the material melting point is analysed. Influences of the heating conditions, of the material formulations and of the material microstructure are described. Special overviews are done on the macromolecular chains orientation and on the volume damage influences

Composite métal / polymère

Elastomère éthylène-propylène

Polymère semi-cristallin

Polypropylène choc

Déformation volumique

Déformation plastique

Cisaillement simple

Traction plane

Traction uniaxiale

µ-talc

Anhydride maléique

CaCO3

Steel / polymer composite

Semi-crystalline polymer

Impact polypropylene

Ethylene-propylene rubber

µ-talc

CaCO3

Maleic anhydride

Uniaxiale tensile

Covalent Surface Modification of Degradable Polymers for Increased Biocompatibility / Nano Patterened Covalent Surface Modification of Poly(ε-caprolactone)

Källrot, Martina

January 2005

Degradable polymers have gained an increased attention in the field of biomedical applications over the past decades, for example in tissue engineering. One way of improving the biocompatibility of these polymers is by chemical surface modification, however the risk of degradation during the modification procedure is a limiting factor. In some biomedical applications, for example in nerve guides, a patterned surface is desired to improve the cell attachment and proliferation. In this thesis a new non-destructive, single-step, and solvent free method for surface modification of degradable polymers is described. Poly(L-lactide) (PLLA) substrates have been functionalized with one of the following vinyl monomers; N-vinylpyrrolidone (VP), acrylamide (AAm), or maleic anhydride (MAH) grafts. The substrates were subjected to a vapor phase atmosphere constituted of a mixture of a vinyl monomer and a photoinitiator (benzophenone) in a closed chamber at very low pressure and under UV irradiation. Poly(ε-caprolactone) (PCL), poly(lactide-co-glycolide) (PLGA), and poly(trimethylene carbonate) (PTMC) have been surface modified with VP using the same procedure to show the versatility of the method. The wettability of all of the four substrates increased after grafting. The surface compositions were confirmed by ATR-FTIR and XPS. The VP grafted PLLA, PTMC and PLGA substrates have been shown to be good substrates for the normal human cells i.e. keratinocytes and fibroblasts, to adhere and proliferate on. The topography of substrates with well defined nano patterns was preserved during grafting, since the grafted layer is very thin. We have also shown that the method is useful for a simultaneous chemical and topographical modification of substrates by masked vapor phase grafting. The surface topography was determined with SEM and AFM. / Intresset för användningen av nedbrytbara polymerer till biomedicinska applikationer som till exempel vävnads rekonstruktion har ökat avsevärt de senaste decennierna. Ett sätt att öka biokompatibiliteten hos dessa polymerer är genom kemisk ytmodifiering, men risken för nedbrytning under själva modifieringen är en begränsande faktor. I vissa biomedicinska applikationer, till exempel nervguider, är det önskvärt att ha en väldefinierad ytstruktur för att öka vidhäftningen och tillväxten av celler. I den här avhandlingen presenteras en ny ickeförstörande, lösningsmedelsfri enstegsprocess för ytmodifiering av nedbrytbara polymerer. Substrat av poly(L-laktid) (PLLA) har ytfunktionaliserats med var och en av följande vinylmonomerer, N-vinylpyrrolidon (VP), akrylamid (AAm) eller maleinsyraanhydrid (MAH). Substraten har exponerats för en gasfasatmosfär av en blandning av en vinylmonomer och en fotoinitiator (bensofenon) i en tillsluten reaktor vid mycket lågt tryck och under UV-strålning. Metodens mångsidighet har även påvisats genom att ytmodifiera substrat av poly(ε-kaprolakton) (PCL), poly(laktid-co-glykolid) (PLGA) och poly(trimetylen karbonat) (PTMC) med VP. Vätbarheten ökade för alla fyra materialen efter ympning med en vinylmonomer. Ytsammansättningen fastställdes med ATR-FTIR och XPS. De VP ympade filmerna av PLLA, PLGA och PTMC visade sig vara bra substrat för mänskliga celler, i detta fall keratinocyter och fibroblaster, att vidhäfta och växa på. Yttopografin hos filmer med väldefinierade nanomönstrade ytor kunde bevaras efter ympning, tack vare att det ympade lagret är så tunt. Gasfas metoden har också visat sig användbar för att simultant ytmodifiera både kemiskt och topografiskt genom maskad gasfasympning. Yttopografin bestämdes med SEM och AFM. / QC 20101014

Vapor phase grafting

covalent surface modification

solvent free

nano patterned topography

degradable polymers

poly(ε-caprolactone)

poly(L-lactide)

poly(lactide-co-glycolide)

poly(trimethylene carbonate)

N-vinylpyrrolidone

maleic anhydride

acrylamide

Gasfasympning

kovalent ytmodifiering

lösningsmedelsfri

nedbrytbara polymerer

nanomönstrad topografi

poly(L-laktid)

poly(ε-kaprolakton)

poly(laktid-co-glykolid)

poly(trimetylen karbonat)

N-vinylpyrrolidon

maleinsyraanhydrid

akrylamid

Polymer Chemistry

Polymerkemi