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Investigation of the filler dynamics affected by coupling agent using x-ray photon correlation spectroscopyHuang, Yitong 30 April 2021 (has links)
No description available.
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Polybutadiene Graft Copolymers as Coupling Agents in Rubber CompoundingSwanson, Nicole January 2016 (has links)
No description available.
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Amélioration de l'adhésion de revêtements épais sur acier : étude expérimentale et numérique / Improving adhesion of thick coatings on steel : experimental and numerical studyTchoquessi-Diodjo, Madeleine Rita 22 October 2013 (has links)
La corrosion des canalisations métalliques pour le transport de gaz ou d’hydrocarbures est un problème critique qui peut avoir des répercussions financières et environnementales très importantes. Les revêtements polyoléfines tricouches sont largement utilisés pour préserver l’intégrité des structures. Ils sont constitués d’une sous couche mince époxy, d’une couche mince d’adhésif et d’une couche épaisse le plus souvent en polyéthylène. Ce système de revêtement bénéficie de très bonnes qualités d'adhérence. Néanmoins, des cas de décollements de ces revêtements à l’interface époxy/acier ont été constatés sur des pipelines en service depuis quelques années seulement, alors que la durée minimale de vie escomptée des tubes dans le sol est de quelques dizaines d’années. Ces décollements pourraient être dus à une dégradation progressive des liaisons interfaciales entre le primaire époxy et la surface métallique, associée à la présence de contraintes interfaciales importantes entre les différentes couches de l'assemblage. Cette étude vise alors d'une part à proposer des solutions permettant d’aboutir à la meilleure performance en vieillissement de la liaison adhésive, et d'autre part à quantifier les niveaux de contraintes au sein de la canalisation en acier revêtue depuis sa mise en œuvre, jusqu'à sa mise en service.Les liaisons interfaciales dépendant nécessairement de la préparation de surface de l’acier, des procédés de nettoyage ont été testés afin d’évaluer leur influence sur l’adhérence initiale et la durabilité des assemblages. Les préparations de surface permettent d'obtenir un degré de propreté et une rugosité. Ces deux éléments maximisent les forces de liaison et donc l'adhérence du revêtement. Le revêtement résiste alors mieux dans des environnements agressifs. Tous les procédés de nettoyage testés ont conduits à des niveaux de propreté équivalents du substrat en acier. Les essais effectués sur substrats polis miroir ont mis en évidence qu’une rugosité est nécessaire pour améliorer la durabilité des assemblages. La rugosité permet d'obtenir des adhérences supérieures à celles sur substrats polis miroir, de ralentir les effets du vieillissement humide et donc de prolonger la durée de vie du système. Il a été mis en évidence que les fortes rugosités étaient particulièrement bénéfiques pour les adhérences sèches. Par contre, au-delà d’une certaine rugosité, l’augmentation de la rugosité ne s’accompagne pas d’une amélioration significative de l’adhérence humide. Une étude sur l’apport des traitements de surface a aussi été menée. L’addition d’un traitement de surface a peu d’impact sur les adhérences initiales des assemblages, en comparaison avec une préparation de surface classique. Par contre les traitements de surfaces améliorent considérablement les adhérences humides, et donc la durabilité des assemblages. Notre travail prouve que le traitement aminosilane est un candidat potentiel en vue du remplacement du traitement toxique de chromatation, référence en matière de traitements de surface dans l'industrie des pipelines et dont l'utilisation sera interdite dans un futur proche compte tenu de l'évolution de la réglementation. Dans de bonnes conditions d'application et associé avec des primaires époxy appropriés, les adhérences sèches et humides obtenues avec les silanes sont comparables (voire supérieures) à celles de la chromatation.Par ailleurs, la modélisation par éléments finis du système tricouches a permis de préciser les niveaux de contraintes aux interfaces résultant de la mise en œuvre et de prévoir leur évolution au cours du temps et du vieillissement humide. / External Corrosion can weaken underground steel pipelines and render them unsafe for transporting oil or gas. Premature damage of this network could lead to dramatic financial and environmental consequences. Three layers polyolefin coatings composed by a fusion bonded epoxy, a modified polyolefin adhesive and a thick polyolefin topcoat, are the most widely systems used to preserve the structure integrity. This protective coating system presents excellent adhesion. Nevertheless, in some specific cases, loss of adhesion has been observed at steel/epoxy interface on operating pipelines on shorter period than their expected lifetime of about fifty years. This disbonding can be assigned to the progressive degradation of interfacial bonds between the epoxy primer and the metallic surface combined to substantial interfacial stresses between the different layers of the assembly. This study thus aims both to provide solutions to achieve the best ageing performance of the adhesive bond, and secondly to quantify the stress levels in a coated steel pipe since coating manufacturing to pipeline commissioning.Given that interfacial bonds depend necessarily on steel surface preparation, cleaning methods were compared to appraise their influence on assemblies dry and wet adhesion. Surface preparations allow to achieve a level of cleanness and to create a surface roughness. These two elements maximize binding forces and therefore the adhesion of the coating. The coating is thus more resistant to aggressive environments. All cleaning process have led to equivalent level of cleanness of steel substrate. Experiments carried out on mirror polished steel substrates highlighted that a surface roughness is necessary to improve joints durability. Roughness allows to obtain higher adhesion compared to mirror polished steel substrates, slows the effects of humid ageing and thus contributes to extend the durability of the system. It has been demonstrated that a high roughness is particularly beneficial for dry adhesion. By cons, beyond a certain roughness, increasing the surface roughness does not lead to significant improvement of wet adhesion. The benefits of surface treatments were also investigated. The addition of a surface treatment has little impact on dry adhesion in comparison with a conventional surface preparation. However, surface treatments substantially enhance the adhesion strength in wet stage, and therefore increase the durability of the assemblies. We also demonstrate that aminosilane surface treatments are competitive alternatives to traditional chromate conversion, which is the surface treatment of reference in pipeline industry, and whose use will be prohibited in a near future considering changes in legislation. Under good conditions of application and associated with appropriate fusion bonded epoxy, dry and wet adhesion obtained with silane surface treatments are comparable (or even higher ) than those obtained with chromate surface treatments.Furthermore, finite element modeling has allowed to specify interfacial stresses levels inside the assembly resulting from coating's manufacturing process and to predict their evolution over time and during wet ageing.
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Avaliação de agente de acoplamento polimérico no comportamento térmico de compostos PP/FVBernardes, Giordano Pierozan January 2016 (has links)
Polipropileno (PP) é um termoplástico com ótimo balanço de propriedades, baixo custo e largo espectro de aplicações. Seu uso como material de engenharia é limitado pelos seus valores relativamente baixos de propriedades mecânicas. A adição de reforço ao PP melhora suas propriedades termomecânicas, tornando-o adequado para fabricação de peças de engenharia como composto termoplástico. Fibra de vidro (FV) é o reforço mais empregado em compostos de PP devido a maior resistência mecânica específica gerada no PP e por atuar como agente nucleante. Devido à diferença entre as naturezas das ligações secundárias, há pouca afinidade química entre PP-FV, sendo necessária a modificação interfacial através de agentes de acoplamento poliméricos (AA) para melhorar o desempenho termomecânico deste composto. Averiguou-se neste trabalho a influência de dois AA, um à base de PP e outro à base de EPDM, ambos graftizados com anidrido maleico (PAM e EAM, respectivamente), no comportamento térmico do composto PP∕FV. Os compostos PP30FV-AA foram preparados em extrusora dupla rosca ZSK 26, e posteriormente injetados em uma injetora Airburg para obtenção de corpos de prova utilizando teor fixo de 30% FV e teores de 0,5∕1,0∕2,0% AA. O PP e seus compostos foram caracterizados via microscopia óptica acoplada à placa Hot Stage, cristalização isotérmica e não isotérmica por calorimetria (DSC), resistência à deflexão térmica (HDT), morfologia da fratura (MEV) e comportamento viscoelástico (DMA) para analisar a influência do AA e da FV. Os resultados obtidos foram avaliados estatisticamente via metodologia ANOVA (Analysis of Variance). O efeito sinérgico FV-AA na cristalização isotérmica do PP foi dependente da combinação temperatura-natureza-teor de AA, sendo a temperatura o fator preponderante. A interação interfacial entre a matriz- reforço foi substancialmente favorecida pelo PAM. O uso de EAM retardou a cristalização do PP, enquanto que o PAM favoreceu este processo. Constatou-se que o AA teve pouca influência no tempo de meia-vida de cristalização nas menores isotermas e, para isotermas mais próximas à fusão do PP, o PAM apresentou menores valores deste parâmetro. Os valores de deflexão térmica foram semelhantes para todas as formulações contendo PAM, enquanto que a adição de EAM decresceu esta propriedade. Em temperaturas inferiores à transição vítrea (Tg) do PP, todos os compostos com AA apresentaram menor módulo elástico em relação ao composto puro; em temperaturas superiores à Tg, o PAM favoreceu aumentou esta propriedade na faixa de temperatura em que o composto usualmente é utilizado. / Polypropylene (PP) features by its properties balance, price and large array of applications. However, its use as engineering component is limited by relative low mechanical properties. PP reinforcement improves its thermomechanical properties, turning it into suitable to produce engineering components as a reinforced thermoplastic composite. Glass fiber (GF) is the most usual reinforce utilized in PP due to its great specific mechanical strength elastic modulus and nucleation capability. In reason of different secondary bonds between PP and GF, it is mandatory to modify the interface between these domains through polymeric coupling agents (CA) to improve thermomechanical performance. It was evaluated the influence of two CA based on PP and EPDM grafted with maleic anhydride (PAM and EAM) on thermal behavior of PP∕GF composite. PP30GF-CA composites were prepared in a twin screw extrusor ZSK 26 and injected in an injector Airburg with fixed GF content (30%) and different CA contents (0.5∕1.0∕2.0%). PP and PP composites were analyzed by optical microscopy with Hot Stage, isothermal and non-isothermal crystallization (DSC), as well as viscoelastic behavior. The results were statistically evaluated by ANOVA (Analysis of Variance) methodology. The synergic role between GF∕CA in PP crystallization was dependent on temperature-nature-CA content, mainly influenced by temperature. Interfacial adhesion was mainly favored by PAM. The results pointed a possible PP isotherm crystallization retardant by EAM, whereas PAM significantly favored this same process. CA presence in PP30GF composite did not influence crystallization half-life time values in lower isotherms, while in isotherms near PP melting temperature, PAM considerably decreased this parameter. Deflection thermal values were not affected by PAM, while EAM decreased this property in whole formulations. CA did not improved PP∕GF elastic modulus below PP glass transition (Tg), while in temperatures above Tg, PAM improved PP-GF this same parameter.
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Effects Of Titanate Coupling Agents On Low Density Polyethylene And Polypropylene Blends And CompositesYilmaz, Gokhun 01 December 2008 (has links) (PDF)
The objective of this study is to investigate the effects of titanate coupling agents on low density polyethylene (LDPE) and polypropylene (PP) blends and composites in terms of their mechanical and morphological properties. PP and LDPE composites were produced separately in a Brabender internal mixer, and CaCO3 was used as inorganic filler with compositions of 20, 40 and 60 %. PP/LDPE blends were produced in a twin-screw extruder with ratios of 75/25, 50/50 and 25/75. Their composites were prepared with addition of untreated and titanate-treated CaCO3 at 20% filler content.
Titanate coupling agent which is appropriate for LDPE, PP and CaCO3 was used to improve the mechanical properties of the blends and composites. For this purpose, &ldquo / Lica 12&rdquo / which is a kind of neoalkoxy organotitanate was used. Two forms of Lica 12 were used: powder form (Capow L12) and pellet form (Caps L12).
Samples with and without titanate were prepared and then they were injection molded to make specimens for tensile and impact tests. Tensile fracture surfaces of samples were examined by scanning electron microscopy (SEM). Their mechanical and morphological properties were compared with each other to determine the effects of Lica 12.
This study showed that Capow L12 improved strain at break and impact strength of PP/CaCO3 composites and PP/LDPE blends containing 75% and 50% PP. The strain at break value of of PP75 composite with 20% titanate-treated filler increased significantly up to 509% which is the highest value among all blends and composites in this study. Capow L12 exhibited its functions in PP matrix much more effectively than in LDPE matrix.
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Preparation And Characterization Of Micron Size Serpentine Filled Abs CompositeAlakoc, Can Mustafa 01 November 2008 (has links) (PDF)
Micron size non-treated / silane coupling agent (SCA) treated serpentine filled acrylonitrile-butadiene-styrene (ABS) composite preparation and characterization of composites in terms of mechanical, thermal, flow properties and morphology were studied in this work. First step of the study was the size reduction of the as collected serpentine mineral. Secondly, three types of silane coupling agent treatments were applied to serpentine which were gamma-methacryloxypropyltrimethoxysilane (A-174), beta-(3,4-epoxycyclohexyl)-ethyltrimethoxysilane (A-186) and gamma-mercapto-propyltrimethoxysilane (A-189). Non-treated and three different types of SCA treated serpentine minerals were melt mixed with ABS. Non-treated serpentine filled ABS composites had the serpentine weight fractions of 2%, 5%, 10% and 20%. On the other hand, SCA treated ones had serpentine weight fractions of 2%, 5% and 10%.
Morphological analysis showed that SCA treatment was partly effective in interface interaction enhancement and A-186 gave the best results according to micrographs. There wasn& / #8217 / t any critical mechanical property loss up to 20% serpentine addition. Tensile tests revealed that SCA treatment increased the yield strength values of composites compared to non-treated serpentine filled composites. In accordance with morphological study, best result was obtained from 5% A-186 treated serpentine filled ABS as 12.9% improvement in yield strength value. Percent elongation at break values were increased with filler addition and greatest increase was observed in A-189 treated samples. Serpentine addition had no net effect on Young& / #8217 / s Modulus values. According to the impact testing results, A-189 treated samples had improved toughness compared to non-treated samples in accordance with elongation at break values. However increasing filler content resulted with decrease in impact strength values. DSC analysis showed that glass transion temperatures, especially for SCA treated samples, were decreased compared to neat ABS with filler addition. This result suggests that SCA may had the plasticizing effect on the composite. Flow properties of composites were not different from neat ABS up to 2% addition, when the filler concentration was further increased melt flow index values were dramatically decreased.
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Ter Blend Of Poly (ethylene Terephthalate), Polypropylene And Low Density PolyethyleneDogan, Erkan 01 January 2003 (has links) (PDF)
This study covers the recycling of waste poly(ethylene terephthalate) (PET) bottles through melt blending with low density polyethylene (LDPE) and polypropylene (PP). In general, polymer blends are known to be immiscible and incompatible with poor mechanical properties. This problem is due to the low intermolecular forces between the components of the immiscible blends. In order to enhance the interaction and compatibility between these matrices, some reactive or non-reactive copolymers were used. In this work / PET was treated with silane coupling agent (SCA) (low molecular weight reactive additive) for compatilization of LDPE-PP-PET blends. LDPE-PP-PET blends were prepared in different compositions (by weight) with and without silane coupling agent at high temperatures by a single screw extrusion and injection molding. Mechanical properties of treated and non-treated blends were studied in terms of tensile strength, strain at break and impact strength. Melt flow properties of blends were investigated by melt flow index. The impact fractured surfaces and thermal behaviour of the blends were examined with Scanning Electron Microscope (SEM) and Differential Scanning Calorimeter (DSC), respectively. Through out the studies, good adhesion between PET and LDPE-PP matrix was successfully achieved by the surface treatment of PET particles. The adhesion was also observed in SEM studies. Also the variation in mechanical properties was found to be highly dependent on the number of extrusion.
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Synthesis And Characterization Of Waterborne Silane Coupling Agent Containing Silicone-acrylic ResinAkin, Ozlem 01 September 2003 (has links) (PDF)
In this study, waterborne silicone-acrylic resin was produced by incorporating silane coupling agent onto the acrylic main chain by emulsion polymerization. After applying different emulsion polymerization processes, batch polymerization was selected to obtain the resultant resin. Thus finding the optimum conditions by investigating the parameters of monomer ratios, initiators, concentrations of initiators, temperature and time, the novel resin was synthesized. Water-dispersed silicone-acrylic resin was produced using butyl acrylate, butyl methacrylate, methyl methacrylate, 3-methacryloxypropyltrimethoxysilane and acrylic acid as a hydrophilic monomer. 2,2' / -azobis[2-(2-imidazolin-2yl)propane]dihydrogen chloride as thermal initiator and t-butyl hydroperoxide / sodiummetabisulfite as redox couple initiator were selected as the best effective initiators for the production of silicone-acrylic resin. The reaction temperature of the preparation of silicone-acrylic resin was taken as 50& / #61616 / C maximum to prevent gelation and agglomeration. To understand the effect of silane coupling agent on the properties of the resin, a new resin was synthesized which did not contain any silane coupling agent and the properties of both resins were determined by FTIR spectroscopy, thermal analysis and mechanical tests.
Their physical properties were also determined. The addition of 3-methacryloxypropyltrimethoxysilane to the main chain increased the hardness and the gloss values but slightly decreased the abrasion resistance value of the silicone-acrylic resin. All the samples showed superior flexibility. The produced polymer which contains silane coupling agent showed excellent adhesion properties on glass and metal plates.
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Avaliação de agente de acoplamento polimérico no comportamento térmico de compostos PP/FVBernardes, Giordano Pierozan January 2016 (has links)
Polipropileno (PP) é um termoplástico com ótimo balanço de propriedades, baixo custo e largo espectro de aplicações. Seu uso como material de engenharia é limitado pelos seus valores relativamente baixos de propriedades mecânicas. A adição de reforço ao PP melhora suas propriedades termomecânicas, tornando-o adequado para fabricação de peças de engenharia como composto termoplástico. Fibra de vidro (FV) é o reforço mais empregado em compostos de PP devido a maior resistência mecânica específica gerada no PP e por atuar como agente nucleante. Devido à diferença entre as naturezas das ligações secundárias, há pouca afinidade química entre PP-FV, sendo necessária a modificação interfacial através de agentes de acoplamento poliméricos (AA) para melhorar o desempenho termomecânico deste composto. Averiguou-se neste trabalho a influência de dois AA, um à base de PP e outro à base de EPDM, ambos graftizados com anidrido maleico (PAM e EAM, respectivamente), no comportamento térmico do composto PP∕FV. Os compostos PP30FV-AA foram preparados em extrusora dupla rosca ZSK 26, e posteriormente injetados em uma injetora Airburg para obtenção de corpos de prova utilizando teor fixo de 30% FV e teores de 0,5∕1,0∕2,0% AA. O PP e seus compostos foram caracterizados via microscopia óptica acoplada à placa Hot Stage, cristalização isotérmica e não isotérmica por calorimetria (DSC), resistência à deflexão térmica (HDT), morfologia da fratura (MEV) e comportamento viscoelástico (DMA) para analisar a influência do AA e da FV. Os resultados obtidos foram avaliados estatisticamente via metodologia ANOVA (Analysis of Variance). O efeito sinérgico FV-AA na cristalização isotérmica do PP foi dependente da combinação temperatura-natureza-teor de AA, sendo a temperatura o fator preponderante. A interação interfacial entre a matriz- reforço foi substancialmente favorecida pelo PAM. O uso de EAM retardou a cristalização do PP, enquanto que o PAM favoreceu este processo. Constatou-se que o AA teve pouca influência no tempo de meia-vida de cristalização nas menores isotermas e, para isotermas mais próximas à fusão do PP, o PAM apresentou menores valores deste parâmetro. Os valores de deflexão térmica foram semelhantes para todas as formulações contendo PAM, enquanto que a adição de EAM decresceu esta propriedade. Em temperaturas inferiores à transição vítrea (Tg) do PP, todos os compostos com AA apresentaram menor módulo elástico em relação ao composto puro; em temperaturas superiores à Tg, o PAM favoreceu aumentou esta propriedade na faixa de temperatura em que o composto usualmente é utilizado. / Polypropylene (PP) features by its properties balance, price and large array of applications. However, its use as engineering component is limited by relative low mechanical properties. PP reinforcement improves its thermomechanical properties, turning it into suitable to produce engineering components as a reinforced thermoplastic composite. Glass fiber (GF) is the most usual reinforce utilized in PP due to its great specific mechanical strength elastic modulus and nucleation capability. In reason of different secondary bonds between PP and GF, it is mandatory to modify the interface between these domains through polymeric coupling agents (CA) to improve thermomechanical performance. It was evaluated the influence of two CA based on PP and EPDM grafted with maleic anhydride (PAM and EAM) on thermal behavior of PP∕GF composite. PP30GF-CA composites were prepared in a twin screw extrusor ZSK 26 and injected in an injector Airburg with fixed GF content (30%) and different CA contents (0.5∕1.0∕2.0%). PP and PP composites were analyzed by optical microscopy with Hot Stage, isothermal and non-isothermal crystallization (DSC), as well as viscoelastic behavior. The results were statistically evaluated by ANOVA (Analysis of Variance) methodology. The synergic role between GF∕CA in PP crystallization was dependent on temperature-nature-CA content, mainly influenced by temperature. Interfacial adhesion was mainly favored by PAM. The results pointed a possible PP isotherm crystallization retardant by EAM, whereas PAM significantly favored this same process. CA presence in PP30GF composite did not influence crystallization half-life time values in lower isotherms, while in isotherms near PP melting temperature, PAM considerably decreased this parameter. Deflection thermal values were not affected by PAM, while EAM decreased this property in whole formulations. CA did not improved PP∕GF elastic modulus below PP glass transition (Tg), while in temperatures above Tg, PAM improved PP-GF this same parameter.
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Avaliação de agente de acoplamento polimérico no comportamento térmico de compostos PP/FVBernardes, Giordano Pierozan January 2016 (has links)
Polipropileno (PP) é um termoplástico com ótimo balanço de propriedades, baixo custo e largo espectro de aplicações. Seu uso como material de engenharia é limitado pelos seus valores relativamente baixos de propriedades mecânicas. A adição de reforço ao PP melhora suas propriedades termomecânicas, tornando-o adequado para fabricação de peças de engenharia como composto termoplástico. Fibra de vidro (FV) é o reforço mais empregado em compostos de PP devido a maior resistência mecânica específica gerada no PP e por atuar como agente nucleante. Devido à diferença entre as naturezas das ligações secundárias, há pouca afinidade química entre PP-FV, sendo necessária a modificação interfacial através de agentes de acoplamento poliméricos (AA) para melhorar o desempenho termomecânico deste composto. Averiguou-se neste trabalho a influência de dois AA, um à base de PP e outro à base de EPDM, ambos graftizados com anidrido maleico (PAM e EAM, respectivamente), no comportamento térmico do composto PP∕FV. Os compostos PP30FV-AA foram preparados em extrusora dupla rosca ZSK 26, e posteriormente injetados em uma injetora Airburg para obtenção de corpos de prova utilizando teor fixo de 30% FV e teores de 0,5∕1,0∕2,0% AA. O PP e seus compostos foram caracterizados via microscopia óptica acoplada à placa Hot Stage, cristalização isotérmica e não isotérmica por calorimetria (DSC), resistência à deflexão térmica (HDT), morfologia da fratura (MEV) e comportamento viscoelástico (DMA) para analisar a influência do AA e da FV. Os resultados obtidos foram avaliados estatisticamente via metodologia ANOVA (Analysis of Variance). O efeito sinérgico FV-AA na cristalização isotérmica do PP foi dependente da combinação temperatura-natureza-teor de AA, sendo a temperatura o fator preponderante. A interação interfacial entre a matriz- reforço foi substancialmente favorecida pelo PAM. O uso de EAM retardou a cristalização do PP, enquanto que o PAM favoreceu este processo. Constatou-se que o AA teve pouca influência no tempo de meia-vida de cristalização nas menores isotermas e, para isotermas mais próximas à fusão do PP, o PAM apresentou menores valores deste parâmetro. Os valores de deflexão térmica foram semelhantes para todas as formulações contendo PAM, enquanto que a adição de EAM decresceu esta propriedade. Em temperaturas inferiores à transição vítrea (Tg) do PP, todos os compostos com AA apresentaram menor módulo elástico em relação ao composto puro; em temperaturas superiores à Tg, o PAM favoreceu aumentou esta propriedade na faixa de temperatura em que o composto usualmente é utilizado. / Polypropylene (PP) features by its properties balance, price and large array of applications. However, its use as engineering component is limited by relative low mechanical properties. PP reinforcement improves its thermomechanical properties, turning it into suitable to produce engineering components as a reinforced thermoplastic composite. Glass fiber (GF) is the most usual reinforce utilized in PP due to its great specific mechanical strength elastic modulus and nucleation capability. In reason of different secondary bonds between PP and GF, it is mandatory to modify the interface between these domains through polymeric coupling agents (CA) to improve thermomechanical performance. It was evaluated the influence of two CA based on PP and EPDM grafted with maleic anhydride (PAM and EAM) on thermal behavior of PP∕GF composite. PP30GF-CA composites were prepared in a twin screw extrusor ZSK 26 and injected in an injector Airburg with fixed GF content (30%) and different CA contents (0.5∕1.0∕2.0%). PP and PP composites were analyzed by optical microscopy with Hot Stage, isothermal and non-isothermal crystallization (DSC), as well as viscoelastic behavior. The results were statistically evaluated by ANOVA (Analysis of Variance) methodology. The synergic role between GF∕CA in PP crystallization was dependent on temperature-nature-CA content, mainly influenced by temperature. Interfacial adhesion was mainly favored by PAM. The results pointed a possible PP isotherm crystallization retardant by EAM, whereas PAM significantly favored this same process. CA presence in PP30GF composite did not influence crystallization half-life time values in lower isotherms, while in isotherms near PP melting temperature, PAM considerably decreased this parameter. Deflection thermal values were not affected by PAM, while EAM decreased this property in whole formulations. CA did not improved PP∕GF elastic modulus below PP glass transition (Tg), while in temperatures above Tg, PAM improved PP-GF this same parameter.
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