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181	Exemplos de universalidade na física estatística de modelos aperiódicos e desordenados / Examples of universality in statistical physics of disordered and aperiodic models Haddad, Thomás Augusto Santoro 21 July 2004 (has links) Apresentamos neste trabalho uma série de estudos sobre os efeitos de perturbações geométricas em alguns modelos da física estatística com transições de fase contínuas, Essas perturbações são causadas por distribuições aleatórias ou aperiódicas (e determinísticas) de campos ou de acoplamentos microscópicos ao longo das redes em que os modelos são definidos. No caso de sistemas aperiódicos sem desordem, mostramos uma grande quantidade de exemplos das possíveis alterações induzidas no comportamento crítico de modelos de Ising, Potts e um modelo para polímeros em interação. Empregamos técnicas não-perturbativas de grupo de renormalização no espaço real (matrizes de transferência para estudar a termodinâmica desses sistemas na região crítica ou tricrítica. Concluímos que, ainda que distribuições aperiódicas de constantes de acoplamento muitas vezes alterem sensivelmente os expoentes críticos associados às transições de fases, classificações universais ainda são possíveis. As classes de universalidade ligadas aos diferentes modelos e às várias maneiras de perturbá-los aperiodicamente estão associadas n inesperadas estruturas atratoras que surgem no espaço hamiltoniano de parâmetros, descritas em detalhe. No caso de modelos em presença de perturbações aleatórias à simetria translacional, argumentamos que alguns tipos de classificações universais também devem ser possíveis, primeiramente por causa de urna certa analogia com os sistemas aperiódicos anteriores, e também porque eles parecem sempre estar associados a formas de dinâmica complexa (corno a que se observa em sistemas vítreos não-desordenados). Comentamos brevemente sobre esta última conexão, e apresentamos urna análise ele um modelo desordenado muito simples, que tem a termodinâmica inteiramente calculável, e pode esconder alguma assinatura dessa dinâmica complexa. Finalmente. discutimos os rudimentos da chamada técnica de Martin-Siggia-Rose (MSR), que pode ser empregada para estudos avançados de sistemas com evoluções do tipo Langevin, e que permitiu o início da compreensão, já há algumas décadas, da possível universalidade da dinâmica complexa de sistemas desordenados. / We present in this work a series of studies on the effects of geometrical perturbations on statistical-physics models with continuous phase transitions. These perturbations are generated by random or aperiodic (deterministic) distributions of fields or microscopic couplings, along the lattices on which the models are defined. In case of non-disordered aperiodic systems, we s: show a wealth of examples of the changes that may be brought about on the critical behavior of Ising, Potts and interacting-polymer models. We employ non-perturbative real-space renormalization group techniques, as well as transfer-matrix methods to study the thermodynamics of such systems in the neighborhood of critical and tricritical points. Our conclusion is that although critical exponents may change appreciably in the presence of aperiodic distributions of couplings, universal classifications are nevertheless still workable. The universality classes associated to different models and the distinct ways of implementing aperiodicity are connected to unexpected attractors in Hamiltonian parameter space, which are thoroughly described. In case of random perturbations that break translational symmetry we argue that some universal classifications should still be possible. First, because these systems are in a sense analogous to the former aperiodic ones, and also because they always seem to be associated with some form of complex dynamics (as the dynamics of vitreous, non-random materials). We make some brief comments on this connection, and present a study of a very simpIe disordered model, whose thermodynamics is completely solvable, and which may hide some signatures of complex dynamics. Finally, we discuss the first steps of the so-called Martin-Siggia-Rose (MSR) method, which may be employed in advanced studies of systems undergoing Langevin-type evolutions, and which was responsible, some decades ago, for a first glimpse into the possible universality of complex dynamical behavior of disordered systems. Classical statistical mechanics Disordered systems Mecânica estatística clássica Mudança de fase Phase change Sistemas desordenados Teorias da termodinâmica Theories of thermodynamics
182	Efeito da rugosidade superficial na ebulição nucleada de refrigerantes halogenados em tubos horizontais / Effect of surface roughness on nucleate boiling heat transfer of halocarbon refrigerants on horizontal tubes Stelute, Elvio Bugança 12 August 2004 (has links) O estudo presente constitui uma análise da influência do acabamento superficial no coeficiente de transferência de calor na ebulição nucleada de refrigerantes halogenados. Dados para três superfícies distintas (cobre, latão e aço inoxidável), dois fluidos refrigerantes (R123 e R134a) e pressões reduzidas entre 0,023 e 0,26 são analisados com o intuito de verificar a influência da rugosidade nestes três parâmetros. O efeito da rugosidade foi avaliado com três acabamentos distintos (massa polidora, lixa e jato de areia) cobrindo uma faixa de rugosidades médias variando desde 0,03 até 10,5 micrômetro. Uma análise de diversas publicações da literatura foi levada a cabo, tendo sido particularmente investigadas algumas correlações que consideram o efeito do acabamento superficial em sua estimativa do coeficiente de transferência de calor. As tendências destas correlações são comparadas entre si e com os dados experimentais. A análise dos resultados permitiu levantar tendências inéditas na literatura consultada. A superfície em ebulição recebeu especial atenção com a obtenção de microfotografias e o cálculo de diversos parâmetros de rugosidade. Foram, ainda, investigados efeitos de envelhecimento da superfície, caracterizado pela diminuição do coeficiente de transferência de calor ao longo do tempo de ebulição. / The present research has been focused in an analysis of the effect of surface finishing on nucleate boiling heat transfer coefficient of halocarbon refrigerants. Experimental data for three different surface material (cooper, brass and stainless steel), two refrigerants (R123 and R134a) and reduced pressures between 0.023 and 0.26 have been analyzed aiming to verify the roughness effects on these three parameters. Three different finishing processes (polishing, emery papering and shot pining) have been used to result in an average roughness range from 0.03 to 10.5 micrometer. An analysis of varied publications and some correlations, particularly those which estimate the effect of surface roughness in heat transfer coefficient, has been done. The tendencies from these correlations have been compared with themselves and with experimental data. These results have shown some effects still unpublished. The boiling surface has received an especial attention, micro-photography has been taken and various parameters have been evaluated. Ageing effects, characterized by the reduction of heat transfer coefficient, have been verified and analyzed. Ebulição nucleada Halocarbon refrigerants Heat transfer Mudança de fase Nucleate boiling Phase change Refrigerantes halogenados Roughness Rugosidade Transferência de calor
183	Utilisation de méthodes inverses pour la caractérisation de matériaux à changement de phase (MCP) / Use of inverse methods for the characterization of phase change materials (PCM) Maréchal, William 24 April 2014 (has links) Avec le développement des énergies intermittentes et la raréfaction des énergies fossiles, le sujet du stockage de l’énergie prend de plus en plus d’ampleur. Une des voies étudiée est le stockage thermique par utilisation de matériaux à changement de phase (MCP). Cette voie est en outre développée pour améliorer l’inertie thermique dans le secteur du bâtiment. Pour utiliser au mieux ces matériaux il est nécessaire de pouvoir prévoir leur comportement énergétique. Cela nécessite une connaissance précise des propriétés thermophysiques, et en premier lieu de la fonction enthalpie massique . Actuellement, il est souvent proposé d'approximer cette enthalpie par l'intégration directe des thermogrammes de la calorimétrie utilisant notamment la notion de capacité calorifique "équivalente". Cette approche est cependant fausse car le thermogramme n’est qu'une représentation en fonction du temps de phénomènes complexes faisant intervenir non seulement les propriétés énergétique du matériaux mais également les transferts thermiques au sein de la cellule du calorimètre. Il en résulte, par exemple, que la forme des thermogrammes, et donc l’enthalpie apparente, dépend de la vitesse de réchauffement et de la masse de l'échantillon ce qui n'est pas le cas de l'enthalpie des MCP qui ne dépend, à pression fixe, que de la température ou de la concentration (pour les solutions). On propose de comparer la sortie d’un modèle numérique direct avec des thermogrammes expérimentaux. L’objectif principal de cette thèse est alors d’utiliser ce modèle dans le cadre d’une méthode inverse permettant l’identification des paramètres de l’équation d’état permettant alors de calculer l’enthapie massique . Dans un premier temps, il est donc présenté le détail d'un modèle 2D dit enthalpique qui néglige la convection, validé par l'expérience, permettant de reconstituer les thermogrammes de corps purs ou de solutions binaires dont les enthalpies sont connues. Il en est déduit une étude de l'influence des différents paramètres ( , , , ...) sur la forme des thermogrammes pour en déduire leurs sensibilités. Une réduction de ce modèle est ensuite effectuée pour réduire le temps de calcul du modèle direct en vue de l’utilisation dans une méthode inverse. Cette dernière est décrite ainsi que les algorithmes d’optimisation correspondants (de Levenberg-Marquardt, génétique ou du simplexe qui s'est avéré le plus rapide) dans un second temps. Nous appliquerons ensuite cet algorithme pour identifier, à partir d'expériences, la fonction enthalpie de corps purs ou de solutions binaires. Les résultats obtenus montrent qu’il est possible d’identifier une fonction independante de la vitesse de réchauffement et de la masse, ce qui valide la méthode. Une analyse des différentes sources d’erreurs dans le processus d’identification et leurs influences sur le résultat permet d’évaluer la qualité de la fonction enthalpie que l’on identifie. Enfin, cette même approche a été utilisée pour analyser une expérience réalisée sur un échantillon d’un matériau composite utilisé dans le bâtiment (ciment avec inclusion de MCP micro-encapsulé). Dans ce cas encore, nos méthodes permettent une caractérisation énergétique pertinente. / With the development of intermittent sources of energy and the depletion of fossil fuels, the subject of energy storage is becoming an important topic. One of the studied options is tthe latent hermal storage using of phase change materials (PCM). One application for this type of energy storage is to improve the thermal insulation in buildings. To make the best use of these materials it is necessary to be able to predict their energy behavior. This requires a precise knowledge of their thermophysical properties, first of all of the specific enthalpy function of the material . Currently, it is often suggested to approximate the enthalpy by the direct integration of the thermograms obtained through calorimetry experiments (notion of "equivalent" calorific capacity). This approach is false because thermograms are only a time related representation of complex phenomena where thermal transfers arise in the cell of the calorimeter acting with the thermophysical properties. As a result, for example, the shape of thermograms depends on the heating rate and on the mass of the sample, which is not the case for the enthalpy of the PCM, which depends, at constant pressure, only on the temperature or on the concentration (for the solutions). We propose to compare the results given by a of a numerical direct model with experimental thermograms. The main objective in this thesis is then to use this direct model in an inverse method in order to identify the parameters of the equation of state, which enables us to calculate the specific enthalpy . First of all, the detail of an enthalpy model is presented, and then validated by comparison with experiments, allowing us to reconstruct the thermograms of pure substances or of salt solutions, of which the enthalpies are known. A study of the influence of the various parameters ( , , , .,..) on the shape of thermograms is also undertaken in order to deduce their sensibilities. A reduced model is then developed in order to reduce the calculating time of the direct model. This optimized model allows the use of inverse methods with acceptable durations. Several inverses algorithms are then presented: Levenberg-Marquardt, evolutionary and Simplex which has proved to be the fastest). We shall then apply this algorithm to identify, from calorimetric experiments, the enthalpy function of pure substances or of salt solutions. The results that we obtain show that it is possible to identify a function independent of the heating rate and of the mass, which validates the method. An analysis of the various sources of errors in the identification process and of their influences on the result allows us to estimate the quality of the enthalpy function that we identify. Matériaux à changement de phase Fusion Caractérisation Modélisation Méthode inverse Validation expérimentale Phase change materials Melting Characterization Modelization Inverse method Experimental validation
184	Análise teórica-experimental do desempenho térmico de micro tubos de calor / A theoretical and experimental study on thermal performance of micro heat pipes Ilvandro Luiz Souza Sueth Júnior 26 October 2018 (has links) O objetivo deste trabalho consiste na análise teórica e experimental do desempenho térmico de dois arranjos de micro tubos de calor. Os arranjos diferem entre si pelo material base de fabricação, que são Acrilonitrila Butadieno Estireno (ABS) e latão, pelo número de canais e pelas dimensões. O fluido de trabalho utilizado foi R134a. A literatura indica micro tubos de calor como soluções proeminentes e de destaque para resfriamento de micro sistemas. Estes dispositivos podem ser adaptados a diferentes condições térmicas através da mudança de fluidos de trabalho, geometrias e materiais base do trocador. O estudo teórico foi baseado no modelo de circuitos térmicos proposto no presente trabalho, que visa calcular indicadores de desempenho térmico, sendo condutividade térmica efetiva e resistência térmica equivalente dos micro tubos de calor a partir das temperaturas obtidas experimentalmente. O estudo experimental foi baseado em obter distribuições de temperaturas dos dispositivos propostos sob diferentes condições de trabalho, variando-se a fração de enchimento de fluido de trabalho, inclinação e temperatura do condensador. Os resultados obtidos para o arranjo de micro tubos de calor em latão demonstrou uma razão de aumento de até 1482% na capacidade de transporte de calor, enquanto que o arranjo de micro tubos de calor em ABS apresentou uma razão de aumento de 247%. Os melhores desempenhos de ambos os casos foram observados para ângulos positivos com baixas frações de enchimento. / The purpose of this work is the theoretical and experimental study on the thermal performance of two micro heat pipes arrays. The differences between the arrays are the base substrate, which are Acrylonitrile Butadiene Styrene (ABS) and brass, the number of channels and their dimensions. The working fluid used was R134a. Previous works indicate micro heat pipes as prominent solutions for the cooling of micro systems. These devices can be adapted to different thermal conditions by changing the working fluids, geometries and base materials of the heat exchanger. The theoretical study was based on the thermal circuits model presented in this work, that aims on computing thermal performance indicators, such as the effective thermal conductivities and the equivalent thermal resistances of the micro heat pipes from the temperatures obtained experimentally. The experimental study was based on obtaining temperature distributions of the micro heat pipes under different working conditions, by varying the working fluid filling ratio, tilt angle and the temperature of the cooling water at the condenser. The results obtained for the brass micro heat pipe array showed a performance ratio increase up to 1482% in heat transfer capacity, while the ABS micro heat pipe array showed a performance ratio increase of 247%. The best performance for both cases were observed for positive tilt angles with low working fluid filling ratios. Micro sistemas Micro tubos de calor Mudança de fase Transporte de calor Heat transport Micro heat pipes Micro systems Phase change
185	Análise teórica-experimental do desempenho térmico de micro tubos de calor / A theoretical and experimental study on thermal performance of micro heat pipes Sueth Júnior, Ilvandro Luiz Souza 26 October 2018 (has links) O objetivo deste trabalho consiste na análise teórica e experimental do desempenho térmico de dois arranjos de micro tubos de calor. Os arranjos diferem entre si pelo material base de fabricação, que são Acrilonitrila Butadieno Estireno (ABS) e latão, pelo número de canais e pelas dimensões. O fluido de trabalho utilizado foi R134a. A literatura indica micro tubos de calor como soluções proeminentes e de destaque para resfriamento de micro sistemas. Estes dispositivos podem ser adaptados a diferentes condições térmicas através da mudança de fluidos de trabalho, geometrias e materiais base do trocador. O estudo teórico foi baseado no modelo de circuitos térmicos proposto no presente trabalho, que visa calcular indicadores de desempenho térmico, sendo condutividade térmica efetiva e resistência térmica equivalente dos micro tubos de calor a partir das temperaturas obtidas experimentalmente. O estudo experimental foi baseado em obter distribuições de temperaturas dos dispositivos propostos sob diferentes condições de trabalho, variando-se a fração de enchimento de fluido de trabalho, inclinação e temperatura do condensador. Os resultados obtidos para o arranjo de micro tubos de calor em latão demonstrou uma razão de aumento de até 1482% na capacidade de transporte de calor, enquanto que o arranjo de micro tubos de calor em ABS apresentou uma razão de aumento de 247%. Os melhores desempenhos de ambos os casos foram observados para ângulos positivos com baixas frações de enchimento. / The purpose of this work is the theoretical and experimental study on the thermal performance of two micro heat pipes arrays. The differences between the arrays are the base substrate, which are Acrylonitrile Butadiene Styrene (ABS) and brass, the number of channels and their dimensions. The working fluid used was R134a. Previous works indicate micro heat pipes as prominent solutions for the cooling of micro systems. These devices can be adapted to different thermal conditions by changing the working fluids, geometries and base materials of the heat exchanger. The theoretical study was based on the thermal circuits model presented in this work, that aims on computing thermal performance indicators, such as the effective thermal conductivities and the equivalent thermal resistances of the micro heat pipes from the temperatures obtained experimentally. The experimental study was based on obtaining temperature distributions of the micro heat pipes under different working conditions, by varying the working fluid filling ratio, tilt angle and the temperature of the cooling water at the condenser. The results obtained for the brass micro heat pipe array showed a performance ratio increase up to 1482% in heat transfer capacity, while the ABS micro heat pipe array showed a performance ratio increase of 247%. The best performance for both cases were observed for positive tilt angles with low working fluid filling ratios. Heat transport Micro heat pipes Micro sistemas Micro systems Micro tubos de calor Mudança de fase Phase change Transporte de calor
186	Testing large samples of PCM in water calorimeter and PCM used in room applications by night-air cooling Bellander, Rickard January 2005 (has links) <p>The latent-heat-storage capacity in Phase-Change Materials can be used for storing or releasing energy within a small temperature interval. Upon the phase transition taking place in a narrow temperature span, the material takes up or releases more energy compared to sensible heat storage. For an ideal phase-change material, the transition temperature is a single value, but for the most common phase-change materials on the market, used in building applications, the transition temperature is distributed within a temperature range of several degrees.</p><p>Integration of phase-change materials in building applications can be effected in several ways, for example by impregnating phase-change materials into porous building materials like concrete, wallboards, bricks or complements of the building structure. Integrating storages filled with phase-change materials makes other implementations, for instance accumulating tanks or envelopes as presented in this thesis, in an air heat exchanger. An appropriate phasetransition temperature of the supposed application is critical to the functionality of the material. For example, in cooling applications, the transition temperature of the material should be a few degrees lower than the requested comfort temperature in the building, and the opposite for heating applications.</p><p>In order to assess the thermal properties and the durability of the material, a watercalorimetric equipment was developed and employed in an accelerated testing programme. The heat capacity of the material and in particular possible change in the heat capacity over time, after thermal cycling of the material, were measured. In the thermal cycling of the material from solid to liquid phase, the temperature rise and required energy supply were recorded. The testing programme was undertaken according to control procedures and documents. In order to be able to utilize the heat-storage capacity in the best way, it is necessary to gain knowledge about thermal properties of the material, especially the long-term behaviour of the material and the deterioration rates of the thermal properties.</p><p>A semi-full-scale air heat exchanger based on phase-change material was developed and tested under real temperature conditions during the summer of 2004. The test results were used to compare and verify computer simulations made on a similar plant. The air heat exchanger utilises the ambient diurnal temperature swing to charge and discharge the phasechange material. The material tested in the calorimeter and in the air heat exchanger has an estimated phase-change temperature of about 24 °C.</p> phase-change material PCM water calorimeter air heat exchanger durability thermal properties heat capacity Building engineering Byggnadsteknik
187	Sub-Cooled Pool Boiling Enhancement with Nanofluids Rice, Elliott Charles 01 January 2011 (has links) Phase-change heat transfer is an important process used in many engineering thermal designs. Boiling is an important phase change phenomena as it is a common heat transfer process in many thermal systems. Phase change processes are critical to thermodynamic cycles as most closed loop systems have an evaporator, in which the phase change process occurs. There are many applications/processes in which engineers employ the advantages of boiling heat transfer, as they seek to improve heat transfer performance. Recent research efforts have experimentally shown that nanofluids can have significantly better heat transfer properties than those of the pure base fluids, such as water. The objective of this study is to improve the boiling curve of de-ionized water by adding aluminum oxide nanopthesiss in 0.1%, 0.2%, 0.3% and 0.4% wt concentrations in a sub-cooled pool boiling apparatus. Enhancement to the boiling curve can be quantified in two ways: (i) the similar heat fluxes of de-ionized water at smaller excess temperature, indicating similar quantity of heat removal at lower temperatures and (ii) greater heat fluxes than de-ionized water at similar excess temperatures indicating better heat transfer at similar excess temperatures. In the same fashion, the secondary objective is to increase the convective heat transfer coefficient due to boiling by adding different concentrations of aluminum oxide nanopthesiss. comsol heat flux heat transfer coefficient nanopthesiss phase change American Studies Arts and Humanities Mechanical Engineering Nanoscience and Nanotechnology
188	Experimental studies of Marangoni convection with buoyancy in simple and binary fluids Li, Yaofa 21 September 2015 (has links) The flow in a layer of volatile fluid driven by a horizontal temperature gradient is a fundamental transport model for numerous evaporative passive cooling applications. When a thin film of a volatile liquid is subject to a horizontal temperature gradient, changes in the surface tension at the free surface lead to Marangoni stresses that drive the flow. In a thicker liquid layer, the flow is also affected by buoyancy. This thesis describes experimental studies of convection driven by a combined action of Marangoni stresses and buoyancy in simple and binary volatile liquid layers confined in a sealed rectangular cavity heated at one end and cooled at the other. Experiments with varying concentrations of noncondensables (i.e., air) ca were performed to investigate their effect on the phase change and heat and mass transport. In the simple liquid, thermocapillary stresses drive the liquid near the free surface away from the heated end. Varying ca is shown to strongly affect the stability of this buoyancy-thermocapillary flow for Marangoni numbers Ma = 290 - 3600 and dynamic Bond numbers BoD = 0.56 - 0.82: removing air suppresses transition to multicellular and unsteady flow. The results are compared with numerical simulations and linear stability analysis. In the binary liquid considered here, a methanol-water (MeOH-H2O) mixture, solutocapillary stresses drive the flow near the free surface towards the heated end. Four distinct flow regimes are identified for this complex flow driven by thermocapillarity, solutocapillarity, and buoyancy, and are summarized in a flow regime map as a function of ca and the liquid composition (MeOH concentration). At low ca, solutocapillary effects are strong enough to drive the liquid near the free surface towards the heated end over the entire liquid layer, suggesting that binary-fluid coolants could significantly reduce film dryout. Marangoni convection Surface tension Thermocapillarity Solutocapillarity Buoyancy Phase change Noncondensables Flow stability Evaporative cooling Particle image velocimetry Flow visualization
189	Laser-induced heating, phase-shift, and damage : measurements and simulations Condit, Jonathan Christopher 07 July 2011 (has links) This research was a collaborative effort between the Air Force Research Laboratory (AFRL) and the University of Texas at Austin to study laser induced thermal lensing. Analysis with a high-frame rate thermal camera system in an optical cuvette determined rates of heating and cooling in water exposed to 1200, 1310 and 1318-nm wavelengths. Thermal modeling software (BTEC) developed at AFRL was used to simulate the beam parameters that were used experimentally. The simulation was also used to compute axial temperature for various power levels, beam diameters, and pulse durations. Laser-induced optical pathlength modulation or phase-shift was computed to study the thermal lensing effect. Power and irradiance damage thresholds were calculated for collimated and focused geometries to study the effect in a focusing eye on retinal damage thresholds. / text Laser-tissue interaction Propagation simulation Phase change Tissue damage Laser-induced thermal lensing Thermal cameras Retinal damage Eye Physiology
190	Phase Change Materials for Solar Thermal Energy Storage Allred, Paul 21 March 2014 (has links) Phase change materials (PCMs) are a viable option for compact thermal energy storage. Effective designs using PCMs require accurate knowledge of the thermal and physical properties, but for many PCMs these are not well known, and when known the knowledge is sometimes contradictory. Therefore, physical characteristics of several promising PCMs (K3PO4·7H2O, FeCl3·6H2O, Mn(NO3)2·4H2O) were determined. In addition, a life cycle assessment (LCA) of dodecanoic acid in a solar thermal energy storage system was carried out to determine the environmental impact for energy storage. This LCA showed that dodecanoic acid in a solar energy system would save energy and facilitate CO2 reductions. However, the economic cost is high and is unlikely to be implemented without incentives. Finally an experimental testbed for a solar thermal system utilizing dodecanoic acid was built. Preliminary measurements demonstrated the utility of this system. Phase change materials PCM heat storage thermal energy storage TES solar energy Life cycle assessment LCA Dodecanoic acid salt hydrates

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