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251	Solução da equação de condução de calor na presença de uma mudança de fase em uma cavidade cilíndrica / Heat conduction equation solution in the presence of a change of state in a bounded axisymmetric cylindrical domain Danillo Silva de Oliveira 30 November 2011 (has links) O problema da condução de calor, envolvendo mudança de fase, foi resolvido para o caso de uma cavidade limitada por duas superfícies cilíndricas indefinidamente longas. As condições de contorno impostas consistem em manter a temperatura da superfície interna fixa e abaixo da temperatura de fusão do material que preenche a cavidade, enquanto que a temperatura da superfície externa é mantida fixa e acima da temperatura de fusão. Como condição inicial se fixou a temperatura de todo o material que preenche a cavidade no valor da temperatura da superfície externa. A solução obtida consiste em duas soluções da equação de condução de calor, uma escrita para o material solidificado e outra escrita para o material em estado líquido. As duas soluções são formalmente escritas em termos da posição da frente de mudança de fase, que é representada por uma superfície cilíndrica com raio em expansão dentro da cavidade. A posição dessa superfície é, a princípio, desconhecida e é calculada impondo o balanço de energia através da frente da mudança de fase. O balanço de energia é expresso por uma equação diferencial de primeira ordem, cuja solução numérica fornece a posição da frente como função do tempo. A substituição da posição da frente de mudança de fase em um instante particular, nas soluções da equação de condução de calor, fornece a temperatura nas duas fases naquele instante. A solução obtida é ilustrada através de exemplos numéricos. / The heat conduction problem, in the presence of a change of state, was solved for the case of an indefinitely long cylindrical layer cavity. As boundary conditions it is imposed that the internal surface of the cavity is maintained below the fusion temperature of the infilling substance and the external surface is kept above it. The solution, obtained in non-dimensional variables, consists in two closed form heat conduction equation solutions for the solidified and liquid regions, which formally depend of the, at first, unknown position of the phase change front. The energy balance through the phase change front furnishes the equation for time dependence of the front position, which is numerically solved. Substitution of the front position for a particular instant in the heat conduction equation solutions gives the temperature distribution inside the cavity at that moment. The solution is illustrated with numerical examples. camada cilíndrica Condução de calor fronteira móvel mudança de fase Problema de Stefan solução de similaridade cylindrical layer Heat conduction moving boundary phase change similarity solution Stefan problem
252	[en] TRANSPORT COEFFICIENTS OF ICE SLURRY IN PLATE HEAT EXCHANGER / [pt] COEFICIENTES DE TRANSPORTE DA PASTA DE GELO EM UM TROCADOR DE CALOR DE PLACAS HUGO GUILLERMO JIMENEZ PACHECO 14 January 2004 (has links) [pt] O uso da pasta de gelo começou recentemente a ser aplicado em sistemas de refrigeração e condicionamento de ar. Como principais vantagens deste fluido, podem ser citados: a possibilidade de armazenar calor latente do gelo e a possibilidade de ser bombeado como a água fria. Assim, o pasta de gelo pode ser usado para o armazenamento térmico no lugar da água fria ou do gelo, desde que, até determinadas concentrações, possa ser bombeado através dos trocadores de calor. Para que esta tecnologia seja aceita extensamente, informações de engenharia são requeridas nas características de transporte nos equipamentos de troca de calor. Um dispositivo experimental foi desenvolvido para estudar os coeficientes de transporte do pasta de gelo em um trocador de calor de placas, utilizando água como carga térmica a resfriar. Foram investigadas várias situações para diferentes frações iniciais e vazões do pasta de gelo. As condições de entrada da carga térmica, foram mantidas constantes. São monitoradas a temperatura, a queda de pressão, a fração do gelo sólido e a vazão do pasta de gelo no trocador de calor, assim como a vazão e a de temperatura na parte da carga térmica. Os resultados mostram que o coeficiente global de troca de calor aumenta com aumento da fração inicial do gelo. A capacidade do resfriamento do trocador de calor aumenta consideravelmente, em relação da água, quando a pasta de gelo, é utilizada como fluido secundário. Finalmente, a queda de pressão aumenta com o aumento da fração inicial de gelo. / [en] The use of the ice slurry is recently applied in the refrigeration and air conditioning systems. Advantages such as the possibility to store latent heat on ice and the possibility of being pumped as cold water can be considered. Ice slurries can be used both for cold storage in place of chilled water or ice and as a secondary refrigerant since, up to certain concentrations, they can be pumped directly through distribution pipeworks and heat exchangers. For ice slurries to become more widely accepted, however, more engineering information is required on fluid flow and heat transfer characteristics. An experimental device was developed to study the transport properties of the ice slurry in plate heat exchangers. Several situations were investigated for different initial fractions and flows of ice slurry. The conditions of the thermal load (pure water), had been kept constant. The temperature field, the pressure loss, the initial fraction and the flow of ice slurry are monitored in the heat exchanger, beyond the flow and the temperature field is monitored in the part of the thermal load. The overall heat transfer coefficient, increases in function of the initial ice fraction. The capacity cooling of the heat exchanger increases with the use of ice slurry when compared to pure water. Finally can be showed that the loss of pressure increases for higher initial ice fraction. [pt] MUDANCA DE FASE [en] PHASE CHANGE [pt] TROCADOR DE CALOR DE PLACAS [en] PLATE HEAT EXCHANGER [pt] PASTA DE GELO [en] ICE SLURRY [pt] FRACAO DE GELO [en] ICE FRACTION [pt] TERMOACUMULACAO [en] THERMAL STORAGE
253	Contribution to the experimental and numerical characterization of phase-change materials : consideration of convection, supercooling, and soluble impurities / Contribution à la caractérisation expérimentale et numérique des matériaux à changement de phase : Prise en compte de la convection, de la surfusion et d'impuretés solubles Yehya, Alissar 14 December 2015 (has links) Au cours des deux dernières décennies, le contexte économique a changé de manière significative en raison de la hausse des prix de l'énergie. Le bâtiment étant devenu le principal secteur consommateur d'énergie, la réduction de celle-ci est devenue un objectif économique, sociétal et environnemental. Ce sujet mobilise de nombreux travaux de recherche. Les Matériaux à Changement de Phase (MCP) représentent une solution innovante qui pourrait contribuer à améliorer la performance énergétique des bâtiments. Ils sont principalement utilisés pour la régulation de température, et leur forte capacité de stockage est un moyen de réduire la consommation d'énergie. Notre étude vise à caractériser, via une approche expérimentale et numérique, le comportement d'un PCM (l’Octadécane). Pour cela, nous avons développé et mis en œuvre un modèle numérique qui corrobore les résultats expérimentaux, et ainsi améliore la prédiction de la performance du MCP considéré.Dans ce travail, notre principale préoccupation est de mettre en évidence les erreurs ou simplifications présentes dans le modèle numérique traditionnel pouvant entraîner un écart global par rapport au comportement réel du MCP. Ces différences conduisent à une estimation erronée des temps de fusion et de la quantité d'énergie stockée. L'amélioration significative de notre modèle est la prise en compte de la convection naturelle, de la surfusion, et l'utilisation des courbes réelles d'enthalpie du MCP considéré. La relation température-enthalpie réelle tient compte de la présence d'une fraction d'impuretés solubles dans le matériau. L’originalité de ce travail est de traiter ces phénomènes physiques via la méthode de Boltzmann réseau (connue sous l'acronyme LBM) avec des fonctions de distribution doubles couplée à une formulation enthalpique. Une telle approche permet de passer outre la non-linéarité des équations régissant l'écoulement et le transfert de chaleur. Sa simplicité de mise en œuvre et son caractère local permettent d'affiner le modèle. Ainsi, on peut couvrir les problèmes de changement de phase, y compris ceux pouvant avoir lieu dans des matrices poreuses ou fibreuses. Ce dernier point a été couvert dans cette thèse.Enfin, il s'est avéré que l'approche numérique adoptée ici pour traiter les problèmes de changement de phase corrobore à la fois nos résultats expérimentaux et ceux disponibles dans la littérature. / Over the past two decades, the economic context has changed significantly due to the rise in energy prices. The building sector has become the main consumer of energy. Thereby, reducing the latter is now an economic, societal and environmental necessity. Accordingly, this topic mobilizes many researches. Phase Change Materials (PCMs) represent an innovative solution, which could improve buildings' energy performance. They are primarily used for temperature regulation, and their high storage capacity can reduce energy consumption.Our study aims at characterizing, via a complementary approach of experimental and numerical simulation, the behavior of a PCM (n-Octadecane). For this, we have developed and implemented a numerical model that corroborates the experimental results, and hence improves the prediction of the PCM performance.In this work, our main concern is to highlight the common errors or simplifications taken in the traditional numerical model, which can result in an overall discrepancy compared to the actual behavior of PCMs. Those discrepancies lead to wrong estimation of the fusion times and amount of energy stored. The major improvement of our model is the consideration of the natural convection, the supercooling, and the use of real enthalpy curves of the considered PCM. The actual temperature-enthalpy relationship takes into account the presence of a fraction of soluble impurities in the material. The originality of this work is to handle these physical phenomena via a lattice Boltzmann method (known by the acronym LBM), which leans on double distribution functions and coupled with the enthalpy formulation. Such an approach overcomes the non-linearity in the governing equations of fluid flow and heat transfer. Its simplicity and local character allow adding complexity to the model. Thereby, one can cover up the phase change problems, including those, which may occur in heterogeneous matrices. This last point has been also covered in this thesis.Finally, it turned out that the approach implemented here for phase change problems supports both, our experimental results and those available in the literature. Matériaux à changement de phase (MCP) Méthode de Boltzmann sur réseau (LBM) Convection Surfusion Enthalpie Chaleur latente Phase change materials (PCMs) Lattice Boltzmann method (LBM) Convection Supercooling Enthalpy Latent Heat 620
254	Phase change materials encapsulation in crosslinked polymer-based monoliths : syntheses, characterization and evaluation of pullulan and black liquor based-monoliths for the encapsulation of phase change materials / Encapsulation de matériaux à changement de phase dans des monolithes réticulés à base de polymères Moreno Balderrama, Juan Ángel 14 December 2018 (has links) Le stéarate de butyle, un matériau de changement de phase biosourcé (MCP), a été encapsulés dans des matrices polymères (pullulane, lignine, hémicelluloses) par la technique des émulsions concentrées. Les matrices polymères ont été réticulées avec du trimetaphosphate de sodium (STMP) dans des conditions alcalines afin d’obtenir un réseau poreux interconnecté rigide. L’influence du processus de séchage sur les matériaux composites obtenus a été étudiée, indiquant la lyophilisation comme la technique la plus efficace. Des études de calorimétrie à balayage différentiel (DSC) ont permis de déterminer que l’encapsulation de stéarate de butyle dans des matrices polymères ne modifiait pas ses propriétés thermiques de changement de phase. Des essais de compression mécanique et de résistance à la déformation ont permis d'évaluer le potentiel des monolithes en tant que panneaux de stockage de chaleur installés directement dans des bâtiments et des serres.Les produits de réticulation par le STMP ont été identifiés et caractérisés par RMN solide du31P. Il a ainsi été possible de synthétiser des monolithes ayant différents taux de réticulation afin d’optimiser la formulation d'encapsulation de MCP. Les matrices polymères vidée de tous leurs contenus liquides ont été étudiées par microscopie électronique à balayage afin d’étudier leur structure poreuse (distribution de taille des pores). Cette nouvelle approche d’encapsulation en une étape apparaît comme efficace et devrait permettre un développement important des applications énergétiques. / Emulsion-templated polymer based (pullulan, lining and hemicelluloses) monoliths encapsulating butyl stearate as bio-based phase change material (PCM) were synthesized. Polymer-bases were crosslinked with sodium trimetaphosphate (STMP) under alkaline aqueous conditions leading to an interconnected porous network. The influence of the drying process on the obtained composite materials morphology was studied indicating freeze-drying as the most effective technique. Differential Scanning Calorimetry (DSC) studies allow to assess that encapsulation of butyl stearate onto matrices do not alter its phase change thermal properties. Mechanical compression and strain resistance tests allowed to evaluate monoliths potential as heat storage panels installed directly in buildings and greenhouses, STMP crosslinking products were identified by solid-NMR characterization, this allowed to synthetize monoliths at different crosslinking yields to find a formulation that improves PCM encapsulation. Polymer matrices were studied by scanning electron microscopy to identify the pore size distribution obtained in STMP crosslinked materials. This new one-step encapsulating approach appears as efficient and cost-effective and is expected to find a broad development in energy storage applications Encapsulation Matériaux à changement de phase Isolation thermique Pullulane Liqueur noire Encapsulation Phase change materials Pullulan Black liquor STMP crosslinking STMP-NMR reaction products Porous materials
255	Experimental study on Temperature regulating bi-component fibres containing paraffin wax in the core Tajul Islam Mollah, Mohammad January 2010 (has links) Putting on or taking off clothes helps the body to stay within the comfortable temperature range (toavoid shivering or sweating) at different activity levels and ambient conditions. Clothes with built-inthermo-regulating properties would mean maintained comfort without putting on or taking off clothesthat frequently. Integration of phase change materials (PCMs) in clothes is one way of achievingthermo-regulating properties. When the body temperature goes up, the PCM melts and absorbs theheat from the body in the form of latent heat (cooling effect). When the temperature drops, the PCMcrystallizes and the stored heat is released again (warming effect).Research on thermo regulating fibres of the bi-component type containing PCM in the core has beenconducted at Swerea IVF in Mölndal, Sweden, for some time. It has been found that high molecularweight HDPE is a suitable viscosity modifier for hydrocarbon waxes used as PCM. The preparation ofcore materials has so far been done in a batch wise fashion in the way that molten wax has beensoaked into pelletized HDPE at around 180°C during prolonged times followed by melt compoundingin a Brabender batch kneader (0.3 kg per batch). Besides being very impractical for larger productionvolumes the method involves long residence times at high temperatures which may induce thermaldegradation reactions. The objective of the present diploma (master’s thesis) work was to develop acontinuous mixing method to produce PCM/HDPE blends and to test the resulting material in bicomponentfibers with a Nylon (PA6) sheath and to characterize the resulting fiber properties in termsof strength and latent heat.It was proven possible to compound HDPE with large amounts (70%) of octadecane (PCM) on aBrabender twin screw extruder. HDPE was metered to the extruder hoper by means of a screw feederand wax was continuously fed to the hoper in the liquid state by means of a heated membrane pump.To facilitate mixing HDPE in form of powder instead of pellets was used. The extruded threads weresolidified in a water bath followed by granulation. Bi-component fibers were successfully producedfrom such materials. Fibers containing 15 to 42% Octadecane were produced showing heat of fusionsin the range 26 to 86 J/g and tenacities in the range 33 to 16 cN/tex. The heat of fusion of the fiberscompares favorable with existing commercial products showing values in the range 5-15 J/g (acrylicand cellulosic fibres containing microencapsulated hydrocarbon waxes). The peak melting point ofoctadecane measured by DSC was found to be depressed some 4-5°C in the fibers compared to pureoctadecane (28°C). Such a melting point depression is important to consider when choosing type ofhydrocarbon wax. / Program: Magisterutbildning i textilteknologi phase change material polymer compounding thermo regulating property bi component fibre core sheath ratio melt spinning polymer rheology dsc vibrodyn Engineering and Technology Teknik och teknologier
256	Modélisation des écoulements des fluides complexes avec changement de phase solide-liquide : Application à la formation des dépôts de paraffines dans les conduites pétrolières / Modeling of Complex Fluids Flow with Solid-Liquid Phase Change : Application to Wax Deposition in Crude Oil Pipelines Madhaoui, Mustapha 11 December 2014 (has links) Les variations de température à la surface externe d'une conduite peuvent provoquer la solidification du fluide en écoulement interne, induisant la formation de dépôts solides sur les parois en contact avec le fluide. Ces dépôts peuvent s'avérer néfastes au bon fonctionnement du système intégrant cette conduite ce qui motive l'étude de ces phénomènes physiques afin de comprendre les mécanismes qui les gouvernent et de permettre leur prévention. Ce genre de situations peuvent être rencontrées dans le domaine pétrolier, par exemple lors du transport en pipeline d'huiles chargées de paraffines, d'hydrates ou d'asphaltènes ; dans le domaine agroalimentaire pour la circulation de produits liquides dans des tubes refroidis ou bien tout simplement pour des canalisations d'eau subissant un refroidissement. Dans la majorité des cas le fluide en écoulement dans les conduites pétrolières est un matériau à changement de phase (MCP) complexe et sa composition multiple avec des interactions entre la rhéologie, la constitution et la température impactant la thermo-hydrodynamique de l'écoulement et la cinétique de transition de phase. Dans le cadre de cette thèse nous proposons de nous pencher sur ces aspects par voie de modélisation. Dans la première partie de ce travail, nous avons développé un modèle physique basé sur la méthode enthalpique pour étudier l’impact de la convection naturelle sur des écoulements et des transferts thermiques avec transition de phase solide liquide dans différentes géométries (cavité carré, cylindre, sphère, autour d’un faisceau de cylindre, …). L'effet du maillage et de l'ordre de précision des schémas numérique est aussi présenté. Le même modèle a été utilisé pour analyser la cristallisation d’un mélange de deux paraffines dans des cellules calorimétriques (Differential Scanning Calorimetry). Pour cette étude, le modèle a été validé à l’aide des résultats expérimentaux de la technique DSC. Le problème de l’écoulement d’un mélange de deux paraffines dans une conduite cylindrique a été aussi abordé afin de prédire la cristallisation du mélange sur la paroi interne de la conduite. Une étude paramétrique a été effectuée pour analyser l’influence de différents paramètres (nombre de Reynolds, concentration initiale de la solution binaire, température de la paroi, …) sur la cinétique de la cristallisation du mélange. La deuxième partie de la thèse a été consacrée à l’étude de l’écoulement avec changement de phase liquide-solide d’un brut paraffinique dans des conduites pétrolières. En effet, la cristallisation des paraffines dans les bruts engendre un équilibre phase thermodynamique liquide/solide. Un modèle thermodynamique rendant compte de cet équilibre a été développé (et validé à l’aide de résultats expérimentaux disponible dans la littérature). Ce modèle nous a permis de prédire la température de cristallisation commençante (Wax Appearance Temperature), ainsi que la quantité de paraffines cristallisées. Ce modèle thermodynamique a été couplé avec un modèle physique reposant sur les équations de conservation de la masse, de la quantité de mouvement, de l'énergie et des espèces pour décrire l’écoulement d’un brut paraffinique avec changement de phase liquide-solide dans des conduites pétrolières. Le modèle physique a été validé à l’aide de résultats expérimentaux disponibles dans la littérature. / Temperature change at the outer surface of a pipe can cause solidification of the fluid flowing internally, inducing the formation of solid deposits on the walls in contact with the fluid. This kind of phenomena can be encountered in many situations in the industrial context such as petroleum industries, for example when transporting pipeline oils with paraffins, hydrates or asphaltenes; food industry for the flow of liquids in cooled tubes or simply for water pipes undergoing cooling.The rheology of the transported fluid, its composition and temperature are among the key factors that influence the thermo-hydrodynamics of the flow and the kinetics of the formation of the deposits. The analysis of their impact is required to enhance the understanding of these mechanisms in order to avoid their undesirable effects as fouling or complete blockage of pipes.In this thesis we propose to study these mechanisms by numerical modelling. We will focus on the modelling of phase change and especially on the description of liquid-solid interfaces by models able to integrate the thermodynamics of physical phenomena such as diffuse interface methods. We seek the two-dimensional numerical resolution of the equations of flow, heat and mass transfer while taking into account the coupling between rheology, composition and temperature in the liquid phase as well as at the interface. The work will be undertaken in the basis of the in-house computational fluid dynamics (CFD) code developed in the laboratory. Changement de phase liquide-solide Dépôts de paraffine Méthode enthalpique Stockage d'énergie Thermodynamique Ecoulement des fluides complexes Liquid-solid phase change Paraffin deposits Enthalpy method Energy storage Thermodynamics Complex fluids flow
257	Modélisation thermodynamique instationnaire d'une boucle fluide diphasique à pompage capillaire pour la traction ferroviaire : étude du phénomène de changement de phase dans l'évaporateur / Transient thermodynamic modeling of capillary pumped loop for railway traction : study of the phase change phenomenon inside the evaporator Boubaker, Riadh 08 July 2014 (has links) Les boucles diphasiques à pompage capillaire sont des systèmes performants de transfert thermique qui peuvent transporter, de manière passive, de très importantes quantités de chaleur sur de grandes distances : utilisant les phénomènes qui apparaissent lors de la vaporisation d'un liquide dans un corps poreux (la mèche) contenu dans l'évaporateur, ces dispositifs offrent l'avantage de ne pas utiliser d'organe mécanique de puissance pour mettre lefluide frigorigène en mouvement. Vu les performances dont ces systèmes ont fait preuve dans le domaine spatial, leur utilisation dans le domaine gravitaire est aujourd'hui sérieusement étudiée, en particulier dans le domaine ferroviaire. Le travail de cette thèse porte sur la description du comportement thermodynamique instationnaire global d'une boucle diphasique à pompage capillaire, utilisée par Alstom Transport pour refroidir ses composants d'électronique de puissance. La première partie de ce travail consiste en la modélisation du transfert de masse et de chaleur dans la mèche contenu dans l'évaporateur, qui est le composant clé de la boucle. Un modèle mathématique instationnaire 2D a été développé pour décrire l'écoulement diphasique avec changement de phase dans le milieu poreux. Les résultats numériques de ce modèle montrent la formation d'une poche de vapeur au sein de la mèche poreuse. Une étude approfondie est élaborée pour décrire la dynamique de la croissance de cette poche en fonction de plusieurs paramètres (géométrie, sous-refroidissement, température de saturation, porosité). La deuxième partie de ce travail consiste à coupler le modèle de l'évaporateur au reste de la boucle afin d'obtenir un modèle thermodynamique global avec une interface liquide/vapeur mobile dans la mèche poreuse. Ce modèle est validé en régime transitoire par une confrontation de ses résultats aux mesures obtenues lors d'une précédente campagne expérimentale. Le comportement de la boucle au cours de la phase de démarrage est ensuite étudié. Finalement, la réponse transitoire de la boucle globale est analysée, en portant un intérêt particulier au comportement de l'évaporateur soumis à un créneau de puissance appliqué, à la variation de la température de consigne du réservoir de contrôle et à la variation de la température de la source froide en contact avec le condenseur. / Capillary pumped loop is a two phase device that uses the phase change phenomena occurred in the porous wick to transport large heat loads over long distances (several meters) without the need of any mechanical pump. CPLs have been developed and successfully employed for the thermal control of satellites. Thanks to their heat transport capacity, their use is now seriously considered in the gravity field especially for cooling electronic devices of a railroad traction chain. The work of this thesis focuses on the description of the unsteady thermodynamic behavior of a capillary pumped loop used by Alstom Transport to cool its power electronics components. The first part of the thesis consists to study the key component of CPL: the capillary evaporator. A 2D unsteady mathematical model has been developed to describe the heat and mass transfer inside the porous wick of the CPL evaporator. The numerical results of this model show the formation of a vapor pocket inside the porous wick. The influences of evaporator geometry, liquid subcooling, saturation temperature and wick porosity on the dynamic growth of the vapor pocket are discussed in detail. The second part of this work consists of coupling the CPL evaporator model with other CPL components in order to obtain a global capillary pumped poop model with a mobile liquid/vapor interface in the porous wick. The proposed model is validated by comparing numerical simulations with experimental results obtained in a previous works realized at Alstom Transport. The CPL startup is then studied. Finally, the influences of the applied power, reservoir temperature and heat sink temperature on the dynamic response of the overall loop are analyzed, with a particular interest to the evaporator behavior. Boucle diphasique à pompage capillaire Simulation numérique Changement de phase, Évaporateur Milieu poreux Écoulement diphasique. Capillary pumped loop Numerical simulation Phase change Evaporator Porous media Two-phase flow
258	Evaluation of the Performance of Multi-Component Cementitious Composites: Multi-Scale Experimental Characterization and Numerical Simulation January 2018 (has links) abstract: Being a remarkably versatile and inexpensive building material, concrete has found tremendous use in development of modern infrastructure and is the most widely used material in the world. Extensive research in the field of concrete has led to the development of a wide array of concretes with applications ranging from building of skyscrapers to paving of highways. These varied applications require special cementitious composites which can satisfy the demand for enhanced functionalities such as high strength, high durability and improved thermal characteristics among others. The current study focuses on the fundamental understanding of such functional composites, from their microstructural design to macro-scale application. More specifically, this study investigates three different categories of functional cementitious composites. First, it discusses the differences between cementitious systems containing interground and blended limestone with and without alumina. The interground systems are found to outperform the blended systems due to differential grinding of limestone. A novel approach to deduce the particle size distribution of limestone and cement in the interground systems is proposed. Secondly, the study delves into the realm of ultra-high performance concrete, a novel material which possesses extremely high compressive-, tensile- and flexural-strength and service life as compared to regular concrete. The study presents a novel first principles-based paradigm to design economical ultra-high performance concretes using locally available materials. In the final part, the study addresses the thermal benefits of a novel type of concrete containing phase change materials. A software package was designed to perform numerical simulations to analyze temperature profiles and thermal stresses in concrete structures containing PCMs. The design of these materials is accompanied by material characterization of cementitious binders. This has been accomplished using techniques that involve measurement of heat evolution (isothermal calorimetry), determination and quantification of reaction products (thermo-gravimetric analysis, x-ray diffraction, micro-indentation, scanning electron microscopy, energy-dispersive x-ray spectroscopy) and evaluation of pore-size distribution (mercury intrusion porosimetry). In addition, macro-scale testing has been carried out to determine compression, flexure and durability response. Numerical simulations have been carried out to understand hydration of cementitious composites, determine optimum particle packing and determine the thermal performance of these composites. / Dissertation/Thesis / Doctoral Dissertation Civil, Environmental and Sustainable Engineering 2018 Civil engineering Materials Science Sustainability Cementitious Composites Material Characterization Material Modeling Novel Construction Materials Phase Change Materials Ultra-High Performance Concrete
259	Solução da equação de condução de calor na presença de uma mudança de fase em uma cavidade cilíndrica / Heat conduction equation solution in the presence of a change of state in a bounded axisymmetric cylindrical domain Oliveira, Danillo Silva de 30 November 2011 (has links) O problema da condução de calor, envolvendo mudança de fase, foi resolvido para o caso de uma cavidade limitada por duas superfícies cilíndricas indefinidamente longas. As condições de contorno impostas consistem em manter a temperatura da superfície interna fixa e abaixo da temperatura de fusão do material que preenche a cavidade, enquanto que a temperatura da superfície externa é mantida fixa e acima da temperatura de fusão. Como condição inicial se fixou a temperatura de todo o material que preenche a cavidade no valor da temperatura da superfície externa. A solução obtida consiste em duas soluções da equação de condução de calor, uma escrita para o material solidificado e outra escrita para o material em estado líquido. As duas soluções são formalmente escritas em termos da posição da frente de mudança de fase, que é representada por uma superfície cilíndrica com raio em expansão dentro da cavidade. A posição dessa superfície é, a princípio, desconhecida e é calculada impondo o balanço de energia através da frente da mudança de fase. O balanço de energia é expresso por uma equação diferencial de primeira ordem, cuja solução numérica fornece a posição da frente como função do tempo. A substituição da posição da frente de mudança de fase em um instante particular, nas soluções da equação de condução de calor, fornece a temperatura nas duas fases naquele instante. A solução obtida é ilustrada através de exemplos numéricos. / The heat conduction problem, in the presence of a change of state, was solved for the case of an indefinitely long cylindrical layer cavity. As boundary conditions it is imposed that the internal surface of the cavity is maintained below the fusion temperature of the infilling substance and the external surface is kept above it. The solution, obtained in non-dimensional variables, consists in two closed form heat conduction equation solutions for the solidified and liquid regions, which formally depend of the, at first, unknown position of the phase change front. The energy balance through the phase change front furnishes the equation for time dependence of the front position, which is numerically solved. Substitution of the front position for a particular instant in the heat conduction equation solutions gives the temperature distribution inside the cavity at that moment. The solution is illustrated with numerical examples. camada cilíndrica Condução de calor cylindrical layer fronteira móvel Heat conduction moving boundary mudança de fase phase change Problema de Stefan similarity solution solução de similaridade Stefan problem
260	Thermal Characterization of In-Sb-Te thin films for Phase Change Memory Application / Caractérisation thermique des couches minces de l’IST pour des applications de mémoire à changement de phase Nguyen, Huu tan 10 July 2015 (has links) Les matériaux à changement de phase (PCM) sont utilisés pour la réalisation de mémoire non volatile. Ces matériaux possèdent la particularité de passer d’un état cristallin à un état amorphe à l’aide d’une impulsion de chaleur, créant ainsi un processus propre au stockage de l’information. Les PCMs sont généralement basés sur des composés ternaires de type Ge-Sb-Te (GST) avec une température de transition de l’ordre de 125°C, rendent ces matériaux inutilisable dans le domaine de l’automobile et pour des applications militaires. Pour contourner cette limitation, le GST est remplacé par le composé In-Sb-Te (IST) possèdent une température de transition plus élevé et un temps de transition beaucoup plus rapide (nanoseconde). Les propriétés thermiques de l’IST et de ses interfaces au sein de la cellule PCM peuvent influencer la température de transition. C’est pourquoi la mesure de la conductivité thermique nous donnera une estimation de la valeur de cette transition.Différentes techniques ont été misent en oeuvre pour mesurer la conductivité thermique des couches minces d’IST en fonction de la concentration en Te, à savoir ; la radiométrie photo-thermique modulée (MPTR) et la méthode 3ω dans une gamme de température allant de l’ambiant jusqu'à 550°C.Les résultats obtenus par les deux techniques de caractérisation thermiques démontrent que la conductivité thermique de l'IST diminue lorsque l'on augmente la teneur en Te. L'augmentation de la teneur en Te pourrait donc conduire à un alliage thermiquement plus résistif, qui est censé apporter l'avantage d'un flux de chaleur plus confiné et limiter la cross-talk thermique dans le dispositif de mémoire à changement de phase. / Phase change memories (PCM) are typically based on compounds of the Ge-Sb-Te (GST) ternary system. Nevertheless, a major drawback of PCM devices is the failure to fulfill automotive-level or military-grade requirements (125°C continuous operation), due to the low crystallization temperature of GST. To overcome this limitation, alloys belonging to the In-Sb-Te (IST) system have been proposed, which have demonstrated high crystallization temperature, and fast switching. Thermal properties of the chalcogenide alloy and of its interfaces within the PCM cell can influence the programming current, reliability and optimized scaling of PCM devices. The two methods, namely: 3ω and Modulated Photothermal Radiometry (MPTR) technique was implemented to measure the thermal conductivity of IST thin films as well as the thermal boundary resistance at the interface with other surrounding materials (a metal and a dielectric). The experiment was carried outin situ from room temperature up to 550oC in order to investigate the intrinsic thermal properties at different temperatures and the significant structural rearrangement upon the phase transition.The results obtained from the two thermal characterization techniques demonstrate that the thermal conductivity of IST decreases when increasing the Te content. Increasing the Te content could thus lead to a more thermally resistive alloy, which is expected to bring the advantage of a more confined heat flow and limiting the thermal cross-talk in the phase change memory device. Mémoire à changement de phase In-Sb-Te Conductivité thermique Conductivité thermique à l’interface Phase change memory In-Sb-Te ternary Thermal conductivity Thermal boundary resistance.

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