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31	Caractérisation mécanique et modélisation thermodynamique du comportement anisotrope du polyéthylène à haute densité. Intégration des effets d'endommagement / Characterization and thermodynamic modeling of the mechanical behaviour of anisotropic high density polyEthylene (HDPE). Integration of the damage effects Arieby, Rida 14 November 2007 (has links) L’objectif de ce mémoire de thèse est de contribuer à la connaissance du comportement mécanique en grandes déformations du Polyéthylène à Haute Densité anisotrope obtenu par extrusion de plaques. Nous présentons le protocole et les résultats expérimentaux de traction séquencée, comportant des décharges, recharges et relaxations monotones et cycliques. Ces campagnes d’essais sont également centrées sur la mesure en temps réel de la variation de volume liée aux phénomènes d’endommagement. Les résultats sont présentés pour différentes orientations d’éprouvettes prélevées dans des plaques extrudées. La modélisation thermodynamique de l’ensemble des résultats, a fait l’objet d’un développement original conduisant à la prédiction unifiée de grandeurs en 3D : contrainte vraie axiale, déformations vraies transversales. Le modèle prévoit également le développement de l’endommagement et permet de mettre en évidence une variable tensorielle de dommage. L’identification des paramètres du modèle thermodynamique sur la base de données expérimentales conduit à des grandeurs physiques conformes aux caractéristiques de la microstructure. Ce travail ouvre la perspective d’un enrichissement de l’approche thermodynamique dans la direction de la prévision de l’anisotropie plastique induite des polymères semi-cristallins / The aim of this thesis is to contribute to the knowledge of the mechanical behavior in large strains of anisotropic High Density PolyEthylene (HDPE), obtained by extrusion of plates. We present the experimental procedure and the results for traction, with unloading, reloading and relaxation in monotonous and cyclic conditions. This work is also concerned with the measure in real time of the volume strain due to the phenomena of damage. The results are given for various orientations of specimen within the extruded plates. The thermodynamic modeling of the whole the results, is the subject of an original development leading to the unified prediction of measures in 3D: axial true stress, transverse true strains. The model also predicts the development of the damage and offer the possibility to introduce a tensorial damage variable. The identification of the model parameters on the basis of experimental data leads to physical quantities in conformity with the characteristics of the microstructure. This work opens the prospect for an enrichment of the thermodynamic approach in the direction of the prediction of the induced plastic anisotropy of semi-crystalline polymers Polyéthylène à Haute Densité Polymères semi-cristallins Endommagement Variation de volume Anisotropie High Density PolyEthylene Damage Volume variation Polymers semi-crystalline Anisotropy
32	[en] PHYSICAL -CHEMICAL EVALUATION OF HIGH DENSITY POLYETHYLENE PROCESSED BY THE 3D PRINTING METHOD OF FUSED DEPOSITION MODELING FDM / [pt] AVALIAÇÃO FÍSICO-QUÍMICA DO POLIETILENO DE ALTA DENSIDADE PROCESSADO PELO MÉTODO DE IMPRESSÃO 3D POR MODELAGEM POR FUSÃO E DEPOSIÇÃO FDM DANNY MESIAS CHAVEZ NOVOA 17 April 2015 (has links) [pt] O objetivo deste trabalho foi estudar a influencia das condições da impressão 3D nas propriedades finais do polietileno de alta densidade usando a modelagem por fusão e deposição, FDM. Foram impressos protótipos com formato de corpos de prova para teste de tração tipo V segundo norma ASTM D638, a três temperaturas de processamento: 220, 240 e 260 Graus Celsius. Para a impressão das amostras foram mantidos constantes os parâmetros de controle, entre eles a espessura da camada de impressão. As amostras impressas foram caracterizadas por difração de raios X, espectroscopia infravermelha, calorimetria diferencial de varredura, análise termogravimétrica, ensaio de tração, índice de fluidez e teste de contração. Os resultados das caracterizações das amostras impressas foram comparados com os resultados do material sem processar, cujas propriedades foram obtidas usando os mesmo métodos de caracterização. Estes resultados demostraram que as condições de impressão por FDM empregadas neste trabalho causaram apenas uma leve mudança nas características estruturais das amostras processadas do PEAD em relação ao material original sem processamento. Houve um leve aumento da cristalinidade no PEAD impresso (em torno de 1,3 a 3 porcento). Além disso, foi comprovado que por causa do resfriamento desigual na superfície e no interior da amostra impressa, o grau de cristalinidade foi levemente maior no interior que na superfície do corpo de prova impresso. A leve mudança no grau de cristalinidade não foi suficiente para causar mudança no módulo de elasticidade e no limite de escoamento em relação ao PEAD original. Outros resultados demostraram que não houve mudança significativa envolvendo formação de ligações duplas, quebra de cadeias e degradação térmica por efeito da condição do processamento utilizada durante a impressão. / [en] The aim of this work was to study the influence of process conditions for 3D printing on the final properties of prototypes of high density polyethylene (HDPE) using the method of the fused deposition modeling. Prototypes for type-V tensile testing according to ASTM D 638 were printed; They were made to three processing temperatures: 220, 240 and 260 Celsius degree. Control parameters for printing were kept constant in all the samples. The printed samples were characterized by X – ray diffraction, infrared spectroscopy, thermogravimetric analysis, differential scanning calorimetry, tensile test, melt flow index test, and, shrinkage test. The results of the characterization of the printed samples and of the original material were compared. These results demonstrated that the printing conditions employed in this study caused a slight change in the structural characteristics of the printed samples compared to the unprocessed original material, there being a slight increase in crystallinity (about 1,3 to 3 percent) for HDPE which was printed. In addition, it has been proven that the degree of crystallinity was slightly greater on the inside that on the surface of the printed samples, because of uneven cooling on the surface and inside of these samples. The slight change in the degree of crystallinity was not enough to cause change in the elastic modulus and yield strength compared to the original HDPE. Other results showed that there was not significant change involving bond formation, break chains, and, thermal degradation by the effect of the processing conditions used during printing. [pt] IMPRESSAO 3D [en] 3D PRINTING [pt] MODELAGEM POR FUSAO E DEPOSICAO [pt] POLIETILENO DE ALTA DENSIDADE [en] HIGH DENSITY POLYETHYLENE
33	Wood Fiber Filled Polyolefin Composites Karmarkar, Ajay 08 1900 (has links) The objective of the study is to improve the interfacial adhesion between the wood fibers and thermoplastic matrix. Efforts were also directed towards improving manufacturing processes so as to realize the full potential of wood fibers as reinforcing fillers. Chemical coupling plays an important role in improving interfacial bonding strength in wood-polymer composites. A novel compatibilizer with isocyanate functional group was synthesized by grafting m-Isopropenyl –α –α –dimethylbenzyl-isocyanate (m-TMI) onto isotactic polypropylene using reactive extrusion process. The compatibilizer was characterized with respect to its nature, concentration and location of functional group, and molecular weight. There are two main process issues when blending polymers with incompatible filler: (1) creating and maintaining the target morphology, and (2) doing so with minimum degradation of fillers. A 28mm co-rotating intermeshing twin screw extrusion system was custom built and the design optimized for (1) blending biological fibers with thermoplastics, and (2) for melt phase fictionalization of thermoplastics by reactive extrusion. To assess the effect of inclusion of wood fibers in polypropylene composites, a series of polypropylene wood fiber/wood flour filled composite materials having 10 to 50 wt % of wood content were prepared using the co-rotating twin screw extrusion system. m-TMI-g-PP and MAPP were used as coupling agents. Addition of wood fibers, at all levels, resulted in more rigid and tenacious composites. The continuous improvement in properties of the composites with the increasing wood filler is attributed to the effective reinforcement of low modulus polypropylene matrix with the high modulus wood filler. Studies on were also undertaken to understand effect of particle morphology, type and concentration of coupling agent, and effect of process additives on mechanical properties. Composites prepared with m-TMI-grafted-PP were much superior to the composites prepared with conventionally used maleated polypropylene in all the cases. Non-destructive evaluation of dynamic modulus of elasticity (MoE) and shear modulus of wood filled polypropylene composite at various filler contents was carried out from the vibration frequencies of disc shaped specimens. The vibration damping behaviour of the composite material was evaluated. MoE and shear modulus were found to increase whereas damping coefficient decreased with the increasing filler content. Knowledge of moisture uptake and transport properties is useful in estimating moisture related effects such as fungal attack and loss of mechanical strength. Hence, a study was undertaken to asses the moisture absorption by wood filled polypropylene composites. Composites prepared with coupling agents absorbed at least 30% less moisture than composites without compatibilizer. Thermo-gravimetric measurements were also carried out to evaluate the thermal stability and to evaluate kinetic parameters associated with thermal degradation of wood fiber and wood flour filled polypropylene composites. The moisture absorption and thermal behaviour are described based on analytical models. High efficiency filler-anchored catalyst system was prepared by substituting of hydroxyl groups present on the cellulosic filler. The process involves immobilizing the cocatalyst onto the cellulosic filler surface followed by addition of metallocene catalyst and then polymerization of ethylene using this filler supported catalyst. The polymerization and composite formation takes place simultaneously. All the polymerization reactions were carried out in a high-pressure stirred autoclave. Effect of temperature, ethylene pressure, and cocatalyst to catalyst ratios (Al/TM ratios) were also studied. Studies on kinetics of polymerization showed that, higher Al/Zr ratio and higher temperature lead to higher polymerization rates but lower the molecular weight. A model incorporating effect of reaction parameter on polymerization rates has been developed. Olefins Wood Fiber Polyolefin Composites Wood Polymer Composites Polypropylene Composites Polymerization High Density Polyethylene Composites Chemical Coupling Coupling Agent HDPE Composites Chemical Engineering
34	Sécurité des réseaux d’adduction d’eau potable en présence de défaut superficiel sous l’effet du phénomène de coup de bélier / Safety of drinking water systems in the presence of surface defects under the effect of water hammer phenomenon Bouaziz, Mohamed Ali 02 June 2016 (has links) La crise de l’eau dans le monde et la pénurie des ressources en eau exigent une bonne gestion de cette précieuse ressource. La bonne gestion passe en premier lieu par un réseau d’adduction d’eau potable fiable avec un faible taux de fuite. Les fuites causées par la rupture des canalisations, phénomène assez fréquent en milieu urbain, s’amorcent sur un défaut dû à la corrosion ou autres. L’amorçage et la propagation de la fissure se fait par fatigue sous l’effet de contraintes engendrées par le passage des véhicules, ou brutalement à cause du phénomène de coup de bélier. La gravité de ces phénomènes dépend de plusieurs paramètres y compris la nature du matériau des conduites. Les matériaux polymères, comme le PEHD, occupent une bonne partie du marché de transport d’eau, grâce à leurs multiples qualités (coût réduit, facilité de pose, flexibilité), notamment dans les réseaux de distribution (réseau secondaire). L’utilisation de ce matériau dans les réseaux d’adduction (aqueducs) est en pleine expansion mais beaucoup moins étudier dans les travaux de recherche. L’objectif de la thèse consiste à étudier le risque de rupture des conduites en polyéthylène haute densité destinée à l’adduction d’eau potable ainsi que leurs résistances au phénomène de coup de bélier. Pour répondre à cette problématique, en premier lieu nous avons caractérisé expérimentalement le comportement mécanique à la rupture des conduites en PEHD. Ensuite, nous avons développé un outil numérique de calcul par élément fini permettant de modéliser la rupture des conduites. À l'issue de cette étude nous avons proposé un modèle semi-empirique reliant la pression d’amorçage d’une fissure à la taille du défaut préexistant ainsi qu’aux dimensions de la conduite. Finalement, nous avons appliqué les outils développés sur un réseau d’adduction d’eau potable existant. Le comportement d’une conduite en PEHD soumise à un phénomène de coup de bélier a été analysé / The water crisis in the world and the shortage of water resources require good management of this precious resource. Good management requires, first and foremost, a reliable drinking water supply system with low leakage rate. Leakage caused by the rupture of pipes, fairly frequent phenomenon in urban areas, initiate from a pre-existing defect in the pipe wall. The initiation and propagation of the crack occur under environmental stress caused by passing vehicles, or it can happen brutally due to water hammer phenomenon. The severity of these phenomena depends on several parameters including the nature of the piping material. Polymeric materials such as HDPE, take a great part of the water transport market, thanks to their many qualities (reduced cost, ease of installation, flexibility), especially in secondary network distribution system. Currently, the use of this material in the supply networks (aqueducts) is booming but less studied in research works. The aim of the present work is to study the failure of high density polyethylene pipes for the supply of drinking water and their resistance to water hammer phenomenon. In order to address this issue, first we have characterized experimentally the mechanical fracture behavior of HDPE pipe. Then, we have developed a finite element calculation tool allowing the modeling of pipes subjected to internal pressure loads. As a result of this numerical study, we proposed a semi-empirical model linking the failure pressure to the size of pre-existing defects as well as the pipe dimensions. Finally, we applied the developed tools on an existing drinking water system. The behavior of HDPE pipe subjected to a water hammer phenomenon was analyzed Coup de bélier Réseaux d’adduction d’eau Polyéthylène haute densité Défaut superficiel Water hammer Water supply networks High density polyethylene Surface defect 620.112 6
35	[en] STUDY OF THE EXFOLIATION OF LEPIDOCROCITE-LIKE FERRITIATANATE NANOSHEETS WITH A DIMETHYLDIOCTADECYLAMMONIUM SALT AND THEIR APPLICATION IN THE POLYMER-BASED NANOCOMPOSITES / [pt] ESTUDO DA ESFOLIAÇÃO DE NANOFOLHAS DE FERRITITANATOS DE ESTRUTURA LEPIDOCROCÍTICA COM DIMETILDIOCTADECILAMÔNIO E SUA APLICAÇÃO EM NANOCOMPÓSITOS DE MATRIZ POLIMÉRICA JULIANA BENTO VIOL 09 May 2016 (has links) [pt] Nanofolhas de ferrititanato com estrutura tipo lepidocrocita foram sintetizadas a partir de um precursor de baixo custo (areia ilmenítica), via rota hidrotérmica alcalina. Dois tipos de nanofolhas com alto e baixo teor de sódio foram obtidos: a) nanofolhas sódicas (NaLTs) e b) nanofolhas protonizadas (pLTs), obtidas mediante uma reação rápida de troca-ácida à temperatura ambiente. As capacidades de troca catiônica de ambos os tipos de nanofolhas foram determinadas seguindo-se a norma C 837 da ASTM. Após a síntese desses dois nanomateriais com diferentes teores de sódio foi estudado o processo de esfoliação em camadas de espessura sub-nanométrica, sob agitação intensa à temperatura de 60 C, utilizando-se como o agente de esfoliação pela primeira vez numa estrutura lepidocrocítica o sal cloreto de dimetildioctadecilamônio (2C18), visando a posterior aplicação das nanofolhas esfoliadas como reforço em nanocompósitos de matriz polimérica. O intuito de aplicar estes reforços em uma matriz polimérica foi buscar uma dispersão mais homogênea das folhas esfoliadas, além do aumento da compatibilidade das nanocargas com a matriz polimérica pela presença dos grupos orgânicos do sal quimicamente ligados às nanofolhas e, consequentemente, o incremento das propriedades térmicas e mecânicas do material polimérico. Dependendo do teor de sódio, foram obtidas nanofolhas esfoliadas e/ou intercaladas que foram posteriormente caracterizadas por fotometria de chama, espetroscopia de infravermelho, área superficial específica por adsorção de N2, termogravimetria, difração de raios-X de alto ângulo, espalhamento de raios-X a baixo ângulo, microscopia de força atômica e microscopia eletrônica de transmissão. Para a fabricação dos nanocompósitos foram utilizadas duas matrizes: a) uma de PEAD puro e b) a outra de PEAD com adição de uma porcentagem baixa, e constante, de polietileno funcionalizado com anidrido maleico (PE-g-MA), sendo reforçadas com as nanocargas protonizadas virgens (pLTs) e esfoliadas (pLTs-o-2C18) nas concentrações de 1,0; 2,0 e 4,0 por cento p. Finalmente, foram avaliadas as propriedades mecânicas e térmicas dos nanocompósitos por meio de ensaios de tração, termogravimetria, calorimetria diferencial de varredura e dilatometria. Os nanocompósitos preparados com pLTs virgem e os fabricados com a adição de agente de acoplamento de PE-g-MA apresentaram um aumento no módulo de Young de aproximadamente 12,8 por cento e 5,1 por cento para cargas de 4 por cento e 2 por cento em peso de pLTs virgem, respectivamente. Os nanocompósitos, que apresentam o maior aumento no limite de escoamento foram os reforçados com 4 por cento p de nanofolhas esfoliada (pLTs-o-2C18). No entanto, estes materiais apresentam uma diminuição no módulo de Young de aproximadamente 12 por cento. Os nanocompósitos com o maior aumento no módulo de Young foram os preparados com 4 por cento p pLTs ( aproximadamente 12,8 por cento), enquanto sua tensão no escoamento também foi melhorada (um aumento de aproximadamente 4 por cento). A incorporação de nanofolhas não afetou significativamente as propriedades de estabilidade térmica da matriz e uma diminuição no coeficiente de expansão térmica de 4 a 5,5 por cento foi apenas observada para nanocompósitos preparados com pLTs virgens. O grau de cristalinidade diminuiu para todos os nanocompósitos fabricados, no qual variou de 2,17 até 26 por cento. / [en] Ferrititanate nanosheets with lepidocrocite-like structure were synthesized from a low cost precursor (ilmenite sand) through alkaline hydrothermal route. Two types of nanosheets with high and low-sodium content were obtained: a) sodium rich nanosheets (NaLTs) and b) protonated nanosheets (pLTs), obtained by a rapid acid-exchange reaction at room temperature. The cation exchange capacities of both types of nanosheets were determinated according ASTM C 837. After the synthesis of these two nanomaterials with different sodium levels, it was studied the exfoliation process to obtain monolayers of nanometric lateral dimensions under intensive stirring at 60 C, using dimethyldioctadecylammonium cloride (2C18) as the exfoliating agent of the lepidocrocite-like ferrititanate nanosheets for the first time, aiming the further application of the exfoliated nanosheets as reinforcement in polymer matrix nanocomposites. The purpose of the addition of these nanofillers within a polymer matrix is to obtain a more homogeneous dispersion of exfoliated nanosheets, as well as the improvement of the compatibility between nanofillers and the polymer matrix, due to the presence of the organic groups from 2C18, chemically attached to nanosheets and hence, to promote the an increase on mechanical and thermal properties of the polymeric matrix. Depending on the sodium content, it was obtained exfoliated and/or intercalated nanosheets that were further characterized by flame photometry, infrared spectroscopy, specific surface area by N2 adsorption, thermogravimetry, X-ray powder diffraction (XRPD) and of small angle X-ray scattering (SAXS), atomic force microscopy (AFM) and transmission electron microscopy (TEM). For the manufacturing of nanocomposites two types of matrices were used: a) neat high density polyethylene (HDPE) and b) HDPE with the addition of a low percentage of polyethylene-graft-maleic anhydride (PE-g-MA). Pristine nanosheets (pLTs) and exfoliated nanosheets (pLTs-O-2C18) were used as nanofillers at loadings of 1.0; 2.0 and 4.0 wt percent. Finally, we assessed the mechanical and thermal properties of the as-prepared nanocomposites through tensile tests, thermogravimetry analysis (TGA), differential scanning calorimetry (DSC) and dilatometry. Nanocomposites prepared with pristine pLTs and those manufactured with the addition of PE-g-MA coupling agent showed an increase on the Young modulus of about 12,8 percent and 5,1 percent for loadings of 4wt percent and 2 wt percent of pristine pLTs, respectively. The nanocomposites that present the highest increase on yield stress were reinforced with 4 wt percent of exfoliated nanosheets (pLTs-o-2C18). However, these materials presents a decrease in the Young modulus of about 12 percent. The nanocomposites with the highest increase on Young Modulus were those prepared with 4 wt percent of pristine ( about 12,8 percent), and the yield stress was also improved (increase of about 4 percent). The incorporation of nanosheets did not affect significantly the thermal stability properties of the matrix and a decrease on the coefficient of thermal expansion was solely observed for nanocomposites prepared with pristine pLTs. The degree of crystallinity decreased for all the manufactured nanocomposites, in the range of about 2,17 t-26 percent for nanocomposites prepared with pristine pLTs and those fabricated with the addition of PE-g-MA, respectively. up to about pLTs with the addition of PE-g-MA. [pt] NANOCOMPOSITOS [pt] POLIETILENO DE ALTA DENSIDADE [en] HIGH DENSITY POLYETHYLENE [pt] NANOFOLHAS DE TITANATO [en] TITANATE NANOSHEETS [pt] FERRITITANATO [en] FERRITITANATE [pt] ESFOLIACAO [en] EXFOLIATION [pt] DIMETILDIOCTADECILAMONIO [en] DIMETHYLDIOCTADECYLAMMONIUM
36	[en] HIGH-DENSITY POLYETHYLENE COMPOSITES REINFORCED WITH IN2W3O12 NANOPARTICLES / [pt] COMPÓSITOS DE POLIETILENO DE ALTA DENSIDADE REFORÇADOS POR NANOPARTÍCULAS DE IN2W3O12 GUSTAVO SCHINAZI 20 April 2017 (has links) [pt] O Polietileno de Alta Densidade (PEAD) é um dos materiais mais conhecidos e é utilizado em diversos campos de aplicação. Apesar de suas inúmeras qualidades, como baixa densidade, alta ductilidade e alta resistência específica, esse material possui algumas desvantagens que limitam a sua aplicabilidade, tais como baixa rigidez, baixa estabilidade térmica e alta expansividade térmica. Por outro lado, existe uma classe seleta de materiais que possuem coeficiente de expansão térmica (CET) negativo ou próximo de zero. Pertencem a esse grupo, por exemplo, as cerâmicas da família A2M3O12, como o In2W3O12 (tungstato de índio). Tendo isso em vista, a proposta deste trabalho foi estudar diferentes métodos de mistura física entre esses dois materiais para fabricar e caracterizar compósitos de PEAD reforçados por nanopartículas de In2W3O12 com CET reduzido e propriedades mecânicas aumentadas em relação ao polímero. Primeiramente, sintetizaram-se nanopartículas de In2W3O12 pelo método de coprecipitação. Suas temperaturas de cristalização (aproximadamente 530 graus Celsius) e de transformação de fase monoclínica/ortorrômbica (259 graus Celsius) foram determinadas por análise térmica simultânea, e seus parâmetros de rede à temperatura ambiente foram determinados por DRX. Além disso, calcularam-se os CET s intrínsecos do In2W3O12 para ambas as suas fases por DRX in situ com temperatura variável. Foi encontrado, pela primeira vez, um CET intrínseco negativo para sua fase ortorrômbica, de alpha1 igual a menos 1,5 multiplicado por 10 elevado a menos 6 e K elevado a menos 1. Em seguida, fabricaram-se compósitos a partir de pellets de PEAD e das nanopartículas de In2W3O12 por microextrusão e microinjeção precedidas por uma etapa de pré-mistura. Dois parâmetros do processo de fabricação foram variados: a fração de carga no compósito (0,5; 2; 4 e 10 por cento) e o método de pré-mistura (sem pré-mistura; por vibração dentro de um moinho sem as bolas de moagem; e em uma autoclave giratória a 190 graus Celsius e pressão ambiente). Finalmente, os compósitos foram caracterizados por ensaios de tração, dilatometria e análise termogravimétrica. Todos os compósitos apresentaram incremento no módulo de elasticidade e no limite de escoamento, obtendo-se aumentos de até 45 por cento e 17 por cento, respectivamente, em relação ao PEAD puro. Os materiais preparados no moinho com 10 por cento p de reforço apresentaram os melhores resultados. De forma geral, os compósitos submetidos a algum tipo de pré-mistura tiveram melhores propriedades mecânicas do que os que não foram pré-misturados. Por outro lado, os compósitos não apresentaram uma grande redução no CET em relação ao PEAD. O melhor resultado encontrado foi uma redução de 6 por cento para os materiais sem pré-mistura com 4 por cento p de reforço. A temperatura de degradação dos compósitos sem pré-mistura também não apresentou melhora significativa. O maior incremento foi de 1,5 por cento em relação ao PEAD puro, encontrado para os materiais com 0,5 por cento p de carga. Finalmente, amostras de PEAD puro submetidas aos diferentes métodos de pré-mistura foram analisados por DSC. Constatou-se que a temperatura de fusão não é alterada, mas a entalpia de fusão e o grau de cristalinidade aumentam com a pré-mistura por vibração (8 por cento) e ainda mais com a pré-mistura na autoclave (15 por cento) em relação ao PEAD puro como recebido. / [en] High-density polyethylene (HDPE) is one of the most widely used materials. Despite its numerous qualities, such as low density, high ductility, and high specific strength, HDPE presents certain disadvantages that limit its applicability, like low stiffness, low thermal stability, and high thermal expansion. In contrast, there is a select group of materials that display negative or near-zero coefficient of thermal expansion (CTE). Ceramics belonging to the A2M3O12 family, which includes In2W3O12 (indium tungstate), are examples of such materials. Therefore, this dissertation proposes to examine different methods of physical mixture in order to produce and characterize HDPE composites reinforced with In2W3O12 nanoparticles with reduced CTE and better mechanical properties than the neat polymer. Firstly, In2W3O12 nanoparticles were synthesized by coprecipitation. Simultaneous thermal analysis proved their crystallization temperature and monoclinic/orthorhombic phase transition temperature to be approximately 530 Celsius degrees and 259 Celsius degrees, respectively. The lattice parameters at room temperature were determined by XRD, and the intrinsic CTE s for both phases were calculated by variable-temperature in situ XRD. For the first time, a negative intrinsic CTE was found for the orthorhombic phase (Alpha 1 equal than minus 1.5 multiplied 10 power minus 6 and K power minus 1). Secondly, composites were produced from HDPE pellets and the In2W3O12 nanoparticles by microextrusion and microinjection preceded by a pre-mixing step. Two fabrication parameters were analyzed: the filler content (0.5, 2, 4, and 10wt percent were used) and the pre-mixing method (no pre-mixture, by vibration within a mill without balls, and in a rotating autoclave at 190 Celsius degrees and ambient pressure). Finally, the composites were characterized by tensile tests, dilatometry, and thermogravimetric analysis. All of the composites presented higher Young s modulus and yield stress than neat HDPE, with increases of up to 45 percent and 17 percent, respectively. The best results were displayed by the materials that were pre-mixed in the mill with 10wt percent filler fraction. In general, both pre-mixing methods improved the composites mechanical properties. On the other hand, the polymer s CTE was not significantly reduced, being decreased by 6 percent in the best case. The degradation temperature showed almost no improvement, with a 1.5 percent increase for the composites with 0.5 percent filler content. Lastly, neat HDPE samples exposed to the different pre-mixing methods were analyzed by differential scanning calorimetry and compared with the as-received pellets. Results showed that the melting temperature was not affected by the mixing techniques, but both the enthalpy of fusion and the degree of crystallinity were increased by 8 percent and 15 percent for the samples pre-mixed by vibration in the mill and by rotation in the autoclave, respectively. [pt] NANOCOMPOSITOS [pt] POLIETILENO DE ALTA DENSIDADE [en] HIGH DENSITY POLYETHYLENE [pt] TUNGSTATO DE INDIO [pt] PROPRIEDADES A TRACAO
37	Etude expérimentale et numérique de l'influence des interactions contenant/contenu sur le comportement élasto-viscoplastique d'emballages en polyéthylène haute densité / Experimental and numerical study of the influence of interactions container/content on the elasto-viscoplastic behaviour of high density polyethylene based-packaging Tran, Ngoc Giang 09 July 2015 (has links) Dans le cadre de cette thèse, nous avons étudié l'interaction contenant-contenu entre un emballage à base de polyéthylène haute densité (PEHD) et l'acétate d'amyle considéré comme diffusant. Nous nous sommes plus précisément intéressés à l'impact du phénomène de sorption et de diffusion sur les propriétés mécaniques en sollicitations statique et de fluage de flacons en PEHD à différents stades du vieillissement physique. Une campagne expérimentale a été menée et une base de données issue d'essais menés sur des éprouvettes prélevées sur des flacons ainsi que d'essais de structure réalisés sur des flacons a été constituée. L'analyse des différents résultats expérimentaux a notamment mis en évidence la nature fickienne du phénomène de diffusion et la chute de la résistance à la compression verticale des flacons. Nous avons ensuite proposé la modélisation du comportement mécanique du PEHD avec prise en compte du transfert de masse induit par le phénomène de diffusion. Des modèles élastoviscoplastique et de fluage ont été proposés et implémentés dans le code de calcul en éléments finis ABAQUS. Les paramètres de ces modèles ont été identifiés à partir de sollicitations simples par la résolution d'un problème d'optimisation, et les modèles ainsi identifiés ont été validés par la simulation numérique d'essais réalisés sur des flacons. Les résultats numériques obtenus sont en très bonne adéquation avec les mesures expérimentales. / As part of this thesis, we studied the container-content interaction between a high-density polyethylene-based packaging (HDPE) and amyl acetate considered as diffusing agent. We were specifically interested in the impact of sorption and diffusion phenomenon on mechanical properties of HDPE bottles under static and creep conditions at different stages of physical aging. Several uniaxialtests have been performed on samples cut from bottles and structural tests have been performed on bottles. The analysis of such various experimental results has highlighted in particular the Fickean nature of the diffusion phenomenon and the fall of the vertical compression strength. We have then focused onthe modeling of the mechanical behavior of HDPE taking into account the mass transfer induced by the diffusion phenomenon. Elasto-viscoplastic and creep models have been proposed and implemented in the finite elements code ABAQUS. The parameters of these models have been identified from simple tests by solving an optimization problem, and thus identified models have been validated by numerical simulation of vertical compression of HDPE bottles. Numerical results are in very good agreement with experimental measurements. Polyéthylène haute densité Emballage Interactions contenant/contenu Comportement élasto-Viscoplastique Modélisation High density polyethylene Packaging Interactions container/content Elastoviscoplastic behaviour Modelling
38	Analyse de la sécurité et de la protection anti-bélier des conduites coudées d'adduction d'eau potable en polyéthylène haute densité / Analysis of the safety and Water Hammer Arrestors protection of water supply elbow pipes in high density polyethylene Dallali, Manel 06 July 2017 (has links) Le stress hydrique menacera plus que 40% de la population mondiale en 2050. Plus de 240 millions de personnes seront dépourvues d’accès à une source d’eau améliorée. En effet, pour assurer une gestion durable de cette ressource, la minimisation des ruptures dans les réseaux d'adduction d'eau potable est primordiale. La rupture des canalisations, phénomène assez fréquent en milieu urbain, s’amorce sur un défaut et sous l’effet des contraintes engendrées par un chargement inhabituel : coup de bélier, un phénomène de surpression. Depuis les années 80, le polyéthylène prend une part de plus en plus importante dans la fabrication des canalisations d'eau potable. Les jonctions sont les zones les plus dangereuses dans les réseaux. D'où l'importance d'étudier la résistance à la rupture des conduites coudées en PEHD. Pour résoudre ce problème, une étude est abordée par une approche expérimentale et une approche numérique par éléments finis pour caractériserle comportement à la fissuration des conduites coudées en PE100. Deux méthodologies sont proposées pour déterminer la ténacité du PEHD : la méthode de l'intégrale J et la méthode du déplacement d'ouverture en pointe de fissure ''CTOD''.La combinaison de ces outils permet de choisir la valeur critique de l'intégrale J comme valeur de la ténacité du PEHD.Ensuite, nous proposons une formule simplifiée basée sur la détermination de l'intégrale J en fonction de la pression dans les réseaux d'adduction d'eau potable en présence d'un défaut superficiel. Enfin, nous étudions le phénomène de coup de bélier pour déterminer la surpression avec un modèle mathématique développé dans cette thèse. Nous démontrons l'importance de l'interaction fluide-structure pour définir la pression au niveau des coudes / Water scarcity will be threatening more than 40% of the world population by 2050, more than 240 million people will not have a source of improved water. In fact, to ensure a sustainable management of this resource, the minimization of the leakages in drinking-water supply network is vital. Pipe rupture, a frequent phenomenon in urban zones, starts with a defect, under the effect of constraints caused by an unusual over pressure: Water Hammer. Since the 80s, polyethylene is being widely considered in manufacturing the pipelines water supply networks. Nevertheless, junctions are the most dangerous zones in the networks. As a result, it is vital to study the tear resistance of the angled conducts in PEHD. To solve this problem, a study is approached with an experimental investigation and a digital approach by fine elements in order to characterize the behavior in the fissuring of pipe bends PE100. Two methodologies are proposed to determine the tenacity of the PEHD: the method of the J-integral and the method of the sharp's movement opening of crack "CTOD ". The combination of these tools permits to choose the critical value of the integral J as a value of the tenacity of the HDPE. In addition, a simplified formula was proposed based on the calculation of the J-integral as a function of the pressure in water supply networks in the presence of a superficial defect. Finally, the water hammer phenomenon was investigated in order to determine the overpressure with a mathematical model which was developed in this thesis. The fluid-structure interaction was found to be important in defining the pressure at elbow pipe Eau potable Conduites coudées Polyéthylène haute densité Rupture Intégrale J CTOD Drinking water Elbow pipe High-density polyethylene Rupture J-integral CTOD 620.112 6 628.144
39	Otimização da co-pirólise de gasóleo pesado com embalagens de PEAD pós-uso utilizando planejamento fatorial / Optimization co-pyrolysys from HDPE and heavy gas oil using factorial design methodology Ney Joppert Junior 07 January 2015 (has links) A co-pirólise é uma rota promissora, uma vez que minimiza o impacto ambiental causado pela disposição do plástico de maneira inadequada, evita seu acúmulo em lixões e permite um melhor aproveitamento de um recurso natural não-renovável, o petróleo, matéria prima importante para a geração de energia e obtenção de produtos químicos. O presente trabalho teve como objetivo a definição das condições experimentais mais propícias à obtenção de líquidos pirolíticos com alta fração de óleo diesel, resultantes da co-pirólise de polietileno de alta densidade (PEAD) pós-consumo com gasóleo pesado tilizando-se catalisador de FCC (Fluid Catalytic Cracking). Como instrumento de otimização das condições experimentais, optou-se pela Metodologia Planejamento Fatorial. Foi também estudado o efeito das condições experimentais, como: a temperatura de reação, a relação gasóleo/polietileno e a quantidade de catalisador no meio reacional. As amostras de polietileno, gasóleo e catalisador foram submetidas à co-pirólise em sistema de leito fixo, sob fluxo constante de nitrogênio, variando-se a temperatura entre 450 C a 550 C, a quantidade de PEAD no meio reacional foi de 0,2 a 0,6 g, e a quantidade de catalisador foi de zero a 0,06 g, mantendo-se fixa a quantidade de gasóleo em 2 g. Foram efetuadas as caracterizações física e química do gasóleo, polietileno pós-uso e do catalisador. Como resultado, obteve-se a produção de 87% de fração de óleo diesel em duas condições diferentes: (a) 550 0C de temperatura sem catalisador; (b) 500 0C de temperatura e 25% de catalisador FCC. Em ambos os casos, a quantidade de gasóleo pesado e PEAD foram constantes (2 g Gasóleo; 0,2 g PEAD), assim com o tempo de reação de 15 minutos. A fração de óleo diesel obtida neste estudo alcançou o poder calorífico de 44,0 MJ/Kg que é similar ao óleo diesel comercial. É importante ressaltar que em ambos os casos nenhum resíduo foi produzido, sendo uma rota ambientalmente importante para reciclagem de embalagens plásticas contaminadas com óleo lubrificante originárias de postos de serviço, visando à recuperação de ambos conteúdo energético e orgânico dos resíduos de embalagens plásticas pós-uso / In this work it was studied the co-pyrolysis process applied to HDPE plastic package with motor oil residues with Heavy Gas Oil and FCC Catalyst. The main objective of this work was to find the experimental conditions that enhanced the diesel fuel fraction in the pyrolitic oil. Factorial Design Methodology (FDM) was developed to enhance diesel fuel fraction (C9-C23) from waste high-density polyethylene (HDPE) and heavy gas oil (HGO) through copyrolysis. FDM was used for optimization of the following reaction parameters: temperature, catalyst and HDPE amounts. The HGO amount was constant (2.0 g) in all experiments. The model optimum conditions were determined to be temperature of 550 C, HDPE = 0.20 g and no FCC catalyst. Under such conditions, 94% of pyrolytic oil was recovered, of which diesel fuel fraction was 93% (87% diesel fuel fraction yield), no residue was produced and 6% of noncondensable gaseous/volatile fraction was obtained. Seeking to reduce the cost due to high process temperatures, the impact of using higher catalyst content (25 %) with a lower temperature (500 C) was investigated. Under these conditions, 88% of pyrolytic oil was recovered (diesel fuel fraction yield was also 87%) as well as 12% of the noncondensable gaseous/volatile fraction. No waste was produced in these conditions, being an environmentally friendly approach for recycling the waste plastic. The diesel fuel fraction obtained in this study achieved heating value (44.0 MJ/Kg) similar to commercial diesel oil. This paper demonstrated the usefulness of using FDM to predict and to optimize diesel fuel fraction yield with a great reduction in the number of experiments. Based on experimental results, co-pyrolysis can represent a significant role in future in the recovery of both energetic and organic content of HDPE plastic package with motor oil residues Resíduos polietileno gasóleo co-pirólise High density polyethylene waste heavy gas oil factorial design methodology pyrolysis ANALISE DE TRACOS E QUIMICA AMBIENTAL
40	Otimização da co-pirólise de gasóleo pesado com embalagens de PEAD pós-uso utilizando planejamento fatorial / Optimization co-pyrolysys from HDPE and heavy gas oil using factorial design methodology Ney Joppert Junior 07 January 2015 (has links) A co-pirólise é uma rota promissora, uma vez que minimiza o impacto ambiental causado pela disposição do plástico de maneira inadequada, evita seu acúmulo em lixões e permite um melhor aproveitamento de um recurso natural não-renovável, o petróleo, matéria prima importante para a geração de energia e obtenção de produtos químicos. O presente trabalho teve como objetivo a definição das condições experimentais mais propícias à obtenção de líquidos pirolíticos com alta fração de óleo diesel, resultantes da co-pirólise de polietileno de alta densidade (PEAD) pós-consumo com gasóleo pesado tilizando-se catalisador de FCC (Fluid Catalytic Cracking). Como instrumento de otimização das condições experimentais, optou-se pela Metodologia Planejamento Fatorial. Foi também estudado o efeito das condições experimentais, como: a temperatura de reação, a relação gasóleo/polietileno e a quantidade de catalisador no meio reacional. As amostras de polietileno, gasóleo e catalisador foram submetidas à co-pirólise em sistema de leito fixo, sob fluxo constante de nitrogênio, variando-se a temperatura entre 450 C a 550 C, a quantidade de PEAD no meio reacional foi de 0,2 a 0,6 g, e a quantidade de catalisador foi de zero a 0,06 g, mantendo-se fixa a quantidade de gasóleo em 2 g. Foram efetuadas as caracterizações física e química do gasóleo, polietileno pós-uso e do catalisador. Como resultado, obteve-se a produção de 87% de fração de óleo diesel em duas condições diferentes: (a) 550 0C de temperatura sem catalisador; (b) 500 0C de temperatura e 25% de catalisador FCC. Em ambos os casos, a quantidade de gasóleo pesado e PEAD foram constantes (2 g Gasóleo; 0,2 g PEAD), assim com o tempo de reação de 15 minutos. A fração de óleo diesel obtida neste estudo alcançou o poder calorífico de 44,0 MJ/Kg que é similar ao óleo diesel comercial. É importante ressaltar que em ambos os casos nenhum resíduo foi produzido, sendo uma rota ambientalmente importante para reciclagem de embalagens plásticas contaminadas com óleo lubrificante originárias de postos de serviço, visando à recuperação de ambos conteúdo energético e orgânico dos resíduos de embalagens plásticas pós-uso / In this work it was studied the co-pyrolysis process applied to HDPE plastic package with motor oil residues with Heavy Gas Oil and FCC Catalyst. The main objective of this work was to find the experimental conditions that enhanced the diesel fuel fraction in the pyrolitic oil. Factorial Design Methodology (FDM) was developed to enhance diesel fuel fraction (C9-C23) from waste high-density polyethylene (HDPE) and heavy gas oil (HGO) through copyrolysis. FDM was used for optimization of the following reaction parameters: temperature, catalyst and HDPE amounts. The HGO amount was constant (2.0 g) in all experiments. The model optimum conditions were determined to be temperature of 550 C, HDPE = 0.20 g and no FCC catalyst. Under such conditions, 94% of pyrolytic oil was recovered, of which diesel fuel fraction was 93% (87% diesel fuel fraction yield), no residue was produced and 6% of noncondensable gaseous/volatile fraction was obtained. Seeking to reduce the cost due to high process temperatures, the impact of using higher catalyst content (25 %) with a lower temperature (500 C) was investigated. Under these conditions, 88% of pyrolytic oil was recovered (diesel fuel fraction yield was also 87%) as well as 12% of the noncondensable gaseous/volatile fraction. No waste was produced in these conditions, being an environmentally friendly approach for recycling the waste plastic. The diesel fuel fraction obtained in this study achieved heating value (44.0 MJ/Kg) similar to commercial diesel oil. This paper demonstrated the usefulness of using FDM to predict and to optimize diesel fuel fraction yield with a great reduction in the number of experiments. Based on experimental results, co-pyrolysis can represent a significant role in future in the recovery of both energetic and organic content of HDPE plastic package with motor oil residues Resíduos polietileno gasóleo co-pirólise High density polyethylene waste heavy gas oil factorial design methodology pyrolysis ANALISE DE TRACOS E QUIMICA AMBIENTAL

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