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31	Approche expérimentale d’écoulement gaz/liquide en milieu poreux modèle : application aux lits fixes pour la catalyse hétérogène / Experimental approach of gaz/liquid flow in a model porous medium : application to packed beds for the heterogeneous catalysis François, Marie 08 November 2016 (has links) Les réactions de catalyse hétérogène impliquant un gaz et un liquide sont mises en oeuvre dans des réacteurs à lit fixes. Ces réacteurs peuvent être assimilés à un milieu poreux. La nature complexe de ce milieu rend la compréhension des interactions entre phases difficile, et nécessite une étude exhaustive à l’échelle globale et locale afin d’identifier les paramètres clés de l’hydrodynamique, des transferts de chaleur et de matière. Nous avons donc développé une cellule miniaturisée bidimensionnelle transparente, qui permet l’observation directe des écoulements avec une très bonne résolution spatiale et temporelle. En faisant varier le débit total et le rapport des débits gaz/liquide, nous avons mis en évidence l’apparition des régimes ruisselant et pulsé, observés par ailleurs dans des systèmes tridimensionnels. Grâce à une méthode d’analyse d’image, nous sommes capables de quantifier et cartographier la saturation liquide locale apparente et la morphologie des phases. L’analyse des variances a permis d’étudier les transitions de régimes pour différentes propriétés de la phase liquide. Cette approche a permis de comparer avec la littérature, mais aussi de s’intéresser aux mécanismes de génération et propagation des instabilités lors des transitions. Il a été mis en évidence que l’apparition des instabilités responsables de la déstabilisation du régime ruisselant intervient pour un nombre deWeber liquide fixé, indiquant que le régime pulsé apparait suite à la déstabilisation des interfaces gaz /liquides par les forces inertielles. Enfin, une étude préliminaire des transferts thermiques dans la cellule a été réalisée. La cellule est utilisée pour réaliser la réaction exothermique d’hydrogénation de l’alpha-methylstyrène. Un modèle simple de transferts thermique a été utilisé pour caractériser l’augmentation de température dans la cellule. Bien que cette approche ne permette pas des mesures quantitatives, elle ouvre à la perspective de suivi de transferts thermiques par caméra infra-rouge. / Heterogeneously catalyzed reactions involving a gas and a liquid phase are frequently achieved in fixed bed reactors. These reactors can be described as a porous medium. The complex nature of this medium makes the understanding of the interplay between phases difficult, and requires a thorough study at the global andlocal scale to identify the key parameters of hydrodynamics, mass and heat transfers. Therefore, we have developed a miniaturized two-dimensional system that is transparent to allow the direct observation of the flow with very high spatial and temporal resolution. While varying the total flow rate and the gas/liquid flow rate ratio, we observe the appearance of the trickle and the pulse flow regime, which can be observed in threedimensional beds. Thanks to some image analysis techniques, we are able to quantify and to map the local apparent liquid saturation and the morphology of the phases. Variances analysis allowed the study of the transition for different liquid properties. This approach allowed the comparison with the existing state of art, but also the study of the onset and propagation mechanisms of the instabilities during the transition. We report that the onset of instabilities responsible for the destabilization of the trickle flow regime occurs at a fixed Weber number. This indicates that the pulsed regime is due to the destabilization of the gas/liquid interface by inertial forces. Finally, a preliminary study of thermal transfers in the device was realized. The device was used to perform the exothermic hydrogenation of alpha-methylstyrene. A simple model is used to characterize the temperature increase in the device. Although this approach does not allow quantitative measurements, it opens up the perspective of monitoring thermal transfers with an infra-red camera. Écoulements gaz/liquide Transition de régime Approche locale Milieux poreux Lit fixe Catalyse hétérogène Gas/liquid flow Regime transition Local approach Porous media Packed bed Heterogeneous catalysis
32	Écoulements liquide-liquide dispersés homogènes en conduite horizontale : approche locale en milieu concentré / Homogeneous dispersed liquid-liquid flow in a horizontal pipe : local approach in concentrated medium Pouplin, Amélie 16 December 2009 (has links) Dans ce travail, des écoulements liquide-liquide dispersés homogènes (c'est-à-dire sans gradient de concentration) ont été étudiés dans une conduite horizontale de 7.5m de long et de 50mm de diamètre interne. Les expériences ont été réalisées dans une large gamme de paramètres opératoires (vitesses de mélange comprises entre 0.28 et 1.2m/s et concentration volumique en phase dispersée, f, de 0.08 à 0.7). Le facteur de frottement de ces écoulements a été mesuré et modélisé en régime turbulent, intermédiaire et laminaire. Ces différents régimes ainsi que l’effet de la concentration en phase dispersée ont été identifiés à partir des mesures locales de vitesse par une technique de vélocimétrie par image de particules (PIV). Lorsque f=0.56, les dispersions se comportent comme des fluides newtoniens auxquels le concept de viscosité effective peut s’appliquer. Le modèle de viscosité de Krieger et Dougherty (1959) décrit l’ensemble des émulsions formées. Le facteur de frottement mesuré suit les lois de frottement classiques en régime laminaire et turbulent (Hagen-Poiseuille et Blasius respectivement) en fonction du nombre de Reynolds basé sur les propriétés de mélange des émulsions (densité et viscosité). Toutefois, la concentration en phase dispersée induit un retard à l’apparition de la turbulence. En milieu très concentré (f=0.7), la dispersion a un comportement rhéofluidifiant et suit la loi d’Ostwald avec un exposant, n=0.5. Tous ces écoulements ont été étudiés, en détail, par l’analyse locale des vitesses. / Homogeneous dispersed flows have been investigated in a horizontal pipe (7.5m long and 50mm internal diameter) in a wide range of flow parameters (mixture velocity from 0.28 to 1.2m/s and concentration, f, up to 0.7). In this work, the wall friction of this emulsion has been measured and modeled in turbulent, intermediate and laminar regime. The different flow regime and the effect of dispersed phase volume fraction have been determined from the velocity profiles measured by PIV measurements in a refractive index matched medium. When f=0.56, emulsion behaves as newtonian fluid. It was shown that the concept of effective viscosity is relevant to scale the wall friction of the emulsion flow. The effective viscosity follows the classical trend of low inertia suspension of hard spheres (Krieger & Dougherty 1959). The friction factor is described by the classical single phase laws in turbulent and laminar regime (Hagen-Poiseuille and Blasius respectively) as a function of Reynolds number based on mixture properties (density and viscosity). Compared to single phase flow, the transition to turbulence is delayed as dispersed phase fraction is increased. For higher dispersed phase fraction (f=0.7), emulsion behaves as a shear-thinning fluid. Emulsion follows the Ostwald law with an exponent equal to 0.5. All these homogeneous dispersed flow have been studied in details. Ecoulement dispersés Ecoulement liquide-liquide Viscosité effective PIV Facteur de frottement Conduite horizontale Liquid-liquid flow Dispersed flow Effective viscosity Friction factor PIV Horizontal pipe.
33	Měření průtoku kapalin / Liquid flow measurement Hradil, Jiří January 2011 (has links) In my master’s thesis, I consider with flow measurement. In shortness is described principle of flow sensors functionality, its advantages and disadvantages. I designed and made device for practice measurement of flow. On this device are installed three flowmeters The characteristic of this flowmeters were measured and evaluated. I made program in LabVIEW to collect and analyze information from instaled flowmeters.
34	Étude hydrodynamique d'un écoulement gaz-liquide dans un milieu poreux confiné / Hydrodynamic study of a gas-liquid flow in a confined porous medium Serres, Marion 22 June 2017 (has links) Cette thèse se focalise sur les écoulements gaz-liquide dans un milieu poreux, problématique rencontrée dans des domaines variés allant de la physique fondamentale à la chimie appliquée. Nous avons caractérisé expérimentalement les régimes hydrodynamiques dans deux géométries différentes : un canal millifluidique (écoulement quasi-1D) et une cellule de Hele-Shaw (écoulement quasi-2D). L’originalité de ce travail est d’analyser l’effet du milieu poreux (lits de billes polydisperses ou mousses solides à cellules ouvertes), du confinement (1D/2D) et de la gravité en couplant des approches locales et globales développées dans les communautés de physique expérimentale et de génie chimique. D’une part, une analyse globale a permis de quantifier les pertes de charge [1] et, basée sur le transport d’un traceur fluorescent, les distributions de temps de séjour [2] et le transfert gaz-liquide dans l’expérience 1D ; d’autre part, une analyse locale de la fraction liquide et l’évolution spatio-temporelle de son contenu fréquentiel ont permis de mettre en évidence deux régimes hydrodynamiques dans le canal millifluidique [3-5] : un régime pseudo-Taylor, où les caractéristiques de l’écoulement périodique amont sont conservées, et un régime modulé, pour lequel l’écoulement se désorganise à l’entrée du milieu poreux. Un modèle phénoménologique basé sur la propagation des bulles dans le milieu est proposé, et rend compte de l’existence de ces deux régimes [4,5]. Enfin, ces deux analyses sont couplées pour étudier les écoulements dans la cellule de Hele-Shaw, et une analyse dimensionnelle de l’effet du confinement et de la gravité sur les écoulements gaz-liquide dans un milieu poreux est proposée.Références –[1] M. Serres, R. Philippe & V. Vidal, to be submitted to Geophys. Res. Lett. (2017). [2] M. Serres, D. Schweich, R. Philippe & V. Vidal, to be submitted to Chem. Eng. Sci. (2017).[3] M. Serres, R. Philippe & V. Vidal, Compte-rendus de la 19e Rencontre du Non-Linéaire, Eds. E. Falcon, M. Lefranc, F. Pétrélis & C.-T. Pham, Non-Linéaire Publications, 109-114 (2016).[4] M. Serres, M.-L. Zanota, R. Philippe & V. Vidal, Int. J. Multiphase Flow 85, 157-163 (2016).[5] M. Serres, T. Maison, R. Philippe & V. Vidal, to be submitted to Int. J. Multiphase Flow (2017). / This thesis focuses on gas-liquid flow in porous media, a common problem encountered in various domains from fundamental physics to applied chemical engineering. We have characterized the hydrodynamic regimes based on two different experimental devices geometry: a millichannel (1D flow) and a Hele-Shaw cell (2D flow). The originality of this work is to analyze the influence of the porous medium (monodisperse micro-packed beds or open cell solid foams), confinement (1D/2D) and gravity by coupling global and local analysis from either chemical engineering or fundamental physics community. On the one hand, a global analysis made it possible to quantify pressure drops, residence time distributions (RTD) based on fluorescent dye transport and gas-liquid mass transfer on the 1D device. On the other hand, a local analysis of the liquid fraction and the spatio-temporal evolution of its frequency pointed out the existence of two hydrodynamic regimes: a Taylor-like regime in which the characteristics of the periodic flow upstream are conserved in the porous medium and a modulated regime characterized by the flow disorganization at the porous medium entrance. A phenomenological model is developed based on bubbles propagation inside the medium and reproduces well both regimes. These two analyses are finally coupled to study multiphase flows inside the Hele-Shaw cell. The effects of gravity and confinement are discussed. Écoulements gaz-liquide Interfaces gaz-liquide Milieux poreux Mousses solides Milieux granulaires Gas-liquid flow Fluid hydrodynamics Porous midia Solid foams Granular media
35	Experimental Investigations on Bubbly Two-Phase Flow in a Constricted Vertical Pipe Neumann-Kipping, Martin 05 September 2022 (has links) Gas-liquid two-phase flows occur in many industrial applications and apparatuses. The design and optimization of such apparatuses and processes requires the numerical simulation of two-phase flows. However, two-phase flow simulations are still a challenging task, especially for industrial scales. Here, the simulation of large flow domains and high Reynolds number flows require a reduction of the resolved time-scales and length-scales by a high level of modeling to decrease the computational effort. Therefore, physics-based models are needed to depict the complex transport processes between the phases. Thus, two-phase flows are the object of ongoing research. Up to now, the majority of closure models for turbulence, interfacial forces or bubble breakup and coalescence were validated against experimental data derived from experiments in simple flow channel geometries like straight pipes. Their application for the simulation of two-phase flows with three-dimensional flow structures like e.g. recirculating areas, flow separation or strong velocity gradients requires constant experimental validation and further development. Hence, improved experimental methods are required for investigations of gas-liquid two-phase flows to provide reliable data for further development and validation of numerical flow simulation models. Therefore, experiments were performed in a constricted pipe under bubbly two-phase flow conditions. Three-dimensional flow structures were created by two types of flow constrictions for a variety of gas and liquid superficial velocities up to jg = 0.1400 m⋅s-1 and jl = 1.6110 m⋅s-1. The flow fields upstream and downstream of the flow constrictions were studied using ultrafast X-ray tomography and hot-film anemometry to obtain cross-sectional phase distribution, bubble characteristics and liquid velocity. The analysis of the ultrafast X-ray tomography image data was significantly improved by development of a histogram-based gas holdup calculation. Furthermore, the spatial dependence of the axial image plane distance was studied to improve the determination of axial bubble velocities and, thus, bubble sizes. The experimental method was advanced by simultaneous application of ultrafast X-ray tomography and hot-film anemometry. Eventually, the experimental data was compared to state-of-the-art Euler/Euler two-fluid simulations. The simulations were performed in the framework of a parallel doctoral thesis in the Experimental Thermal Fluid Dynamics department at the Helmholtz-Zentrum Dresden – Rossendorf by Ms. Sibel Tas-Koehler following the baseline approach. The results were compared in terms of the phase distribution, bubble sizes and gas velocity for two operating conditions using the homogeneous multiple size group model. / Zweiphasenströmungen aus Gasen und Flüssigkeiten treten in vielen industriellen Anwendungen und Apparaten auf. Um einen sicheren, zuverlässigen und optimalen Betrieb einzelner Komponenten und gesamter Anlagen zu gewährleisten, sind die Strömungen Gegenstand zahlreicher Untersuchungen. Numerische Simulationen sind ein unverzichtbares Instrument, um Prozesse unter diesen Aspekten zu bewerten. Die Simulation von Zweiphasenströmungen, insbesondere im industriellen Maßstab, ist jedoch nach wie vor eine anspruchsvolle Aufgabe. Um den Rechenaufwand zu verringern und die Simulation von großen Strömungsgebieten und Strömungen mit hohen Reynoldszahlen zu ermöglichen, ist ein hohes Maß an Modellierung notwendig. Gleichzeitig wurden die meisten Schließungsmodelle zur Beschreibung von Turbulenz, Grenzflächenkräften oder Blasenzerfall und -koaleszenz für einfache Geometrien wie beispielsweise gerade Rohre entwickelt. Die Anwendung dieser Modelle für die Simulation von Zweiphasenströmungen mit dreidimensionalen Strömungsstrukturen, wie z.B. Rezirkulationsgebieten, Strömungsablösungen oder starken Geschwindigkeitsgradienten, erfordert eine ständige experimentelle Validierung und Weiterentwicklung. Dies wiederum erfordert eine immer höhere Auflösung der eingesetzten Messsysteme und steigende Qualität der experimentellen Daten. Um verlässliche Daten für die Weiterentwicklung und Validierung von Modellen für die numerische Strömungssimulation zu erhalten sind daher verbesserte experimentelle Methoden zur Untersuchung von Gas-Flüssig-Strömungen erforderlich. Aus diesem Grund wurden Experimente an einer Blasenströmung in einem Rohr mit einer Strömungsverengung durchgeführt. Zwei Arten von Verengungen wurden genutzt, um dreidimensionale Strömungsstrukturen für eine Vielzahl von Betriebsbedingungen zu erzeugen. Diese sind durch Gas- und Flüssigkeitsleerrohrgeschwindigkeiten bis zu jg = 0.1400 m⋅s-1 und jl = 1.6110 m⋅s-1 definiert. Um die Phasenverteilung im Querschnitt der Strömung, Blaseneigenschaften und die Flüssigphasengeschwindigkeit stromauf- und -abwärts der Verengung zu ermittelt, wurde die Strömung mit Hilfe der ultraschnellen Röntgentomographie und Heißfilm-Anemometrie untersucht. Die Datenanalyse für die Bilddaten der ultraschnellen Röntgentomographie wurde durch die Entwicklung einer Histogramm-basierten Gasgehaltsberechnung erheblich verbessert. Um die Bestimmung der axialen Blasengeschwindigkeiten und damit der Blasengrößen zu verbessern, wurde außerdem die räumliche Abhängigkeit des axialen Bildebenenabstands untersucht. Die experimentellen Methoden wurden durch die gleichzeitige Anwendung von ultraschneller Röntgentomographie und Heißfilm-Anemometrie weiterentwickelt. Die experimentellen Daten wurden mit dem Stand der Technik von Euler/Euler-Zweiphasen-Simulationen verglichen. Die Simulationen wurden im Rahmen eines parallelen Promotionsvorhabens in der Abteilung Experimentelle Thermofluiddynamik am Helmholtz-Zentrum Dresden – Rossendorf von Frau Sibel Tas-Köhler durchgeführt und folgten der Baseline-Modell Strategie. Die Ergebnisse wurden unter Verwendung des homogenen Modells mehrerer Größenklassen bezüglich der Phasenverteilung, der Blasengrößen und der Gasgeschwindigkeit für zwei Betriebsbedingungen verglichen. info:eu-repo/classification/ddc/620 ddc:620
36	Meso-Scale Wetting of Paper Towels Abedsoltan, Hossein 31 July 2017 (has links) No description available. Materials Science Mechanical Engineering Forestry Chemical Engineering Porous Materials Low-density Materials Paper Science Liquid flow Wetting Absorption Absorption Models and Methods Paper towel absorption properties Image processing and analysis
37	[pt] MEDIÇÃO DO CAMPO TRI-DIMENSIONAL DE VELOCIDADE DA FASE LÍQUIDA DE ESCOAMENTOS TURBULENTOS, GAS-LÍQUIDO, INTERMITENTES EM TUBO HORIZONTAL / [en] THREE-COMPONENT LIQUID VELOCITY FIELD MEASUREMENTS IN TURBULENT, GAS-LIQUID, INTERMITTENT FLOWS IN HORIZONTAL PIPES RODRIGO DOS SANTOS NAVARRO DE MESQUITA 30 June 2020 (has links) [pt] O estudo do escoamento intermitente de gás e líquido é de enorme relevância. Devido a sua vasta ocorrência em diversos problemas industriais, como na indústria do petróleo, em escoamentos de água e vapor em trocadores de calor e em sistemas de refrigeração de usinas nucleares, diversos estudos experimentais e numéricos buscam obter um conhecimento mais profundo deste complexo fenômeno. Devido a esta complexidade, se fazem necessários experimentos detalhados de maneira a dar suporte aos modelos matemáticos desenvolvidos. O presente trabalho descreve um estudo experimental de um escoamento turbulento gás-líquido no regime intermitente para tubo horizontal. As técnicas de velocimetria por imagem de partícula estereoscópica de alta frequência (SPIV ) e fluorescência induzida por laser (LIF) foram usadas para medir todos os três componentes do vetor de velocidade em diferentes seções do tubo, referenciadas pelo nariz da bolha de gás. A seção de testes consistiu de uma tubulação de acrílico com diâmetro interno de 40mm e 17,7m de comprimento. Os fluidos de trabalho utilizados foram água e ar, com velocidades superficiais de jL igual 0,3 0,4 e 0,5m/s e jG igual 0,5m/s que formaram o padrão de escoamento intermitente. Um sistema de sensores fotossensíveis foi utilizado para medir a velocidade de translação da bolha de gás, além de acionar o sistema SPIV. Desta forma, foi possível determinar os campos médios das três componentes de velocidade da fase líquida do escoamento turbulento gás-líquido em regiões de interesse na vizinhança da bolha alongada. Os dados obtidos revelaram a influência das bolhas de gás de maior velocidade, na dinâmica do campo de velocidade do líquido. Tais dados contém informações valiosas que contribuem não apenas para uma melhor compreensão da física que rege o escoamento, mas também como forma de validação e aprimoramento de modelos numéricos. / [en] The analysis of gas-liquid intermittent flow in horizontal pipes is of great relevance importance due its applications in many industrial problems, such as in the petroleum industry, boiler and heat exchanger tubes and cooling systems of nuclear power plants. A considerable number of experimental and analytical studies have been carried out on the pursuit of a deeper knowledge of this complex phenomenon. The present work describes an experimental study of a horizontal, gas-liquid pipe flow in the intermittent regime. Experimental techniques such as high frequency stereoscopic particle image velocimetry (SPIV ) and laser induced fluorescence (LIF), were applied in order to obtain all three components of the velocity vector at different pipe sections, referred to the gas bubble nose tip. A 40mm inner diameter, 17.7m long acrylic pipe was used as test section (L/D approximately 450). The working fluids, water and air formed the intermittent flow pattern, with superficial velocities of jL equal 0.3, 0.4 and 0.5 m/s and jG equal 0.5 m/s. A set of three photogate sensors, equally-spaced along the pipe, were used to measure the bubble translational velocities, and to trigger the SPIV system, allowing for the determination of ensemble-averaged, threecomponent velocity fields of the turbulent liquid flow in cross-stream planes around the gas bubble. The original data obtained revealed the influence of the faster-moving gas bubbles on the dynamics of the liquid velocity field, providing valuable information that contribute to a better understanding of the physics governing the flow, also serving for the validation of numerical simulations. [pt] ESCOAMENTO INTERMITENTE [pt] CAMPOS DE VELOCIDADE 3D [pt] ESCOAMENTO GAS-LIQUIDO [pt] PIV ESTEREOSCOPICO [en] INTERMITTENT FLOW [en] THREE-COMPONENT VELOCITY FIELD [en] GAS-LIQUID FLOW [en] STEREO PIV
38	Separação gravitacional de gás em um duto anular inclinado: estudo experimental e modelagem fenomenológica / Gravitational gas separation in an inclined annular channel: experimental study and phenomenological modeling Vidal, Luis Enrique Ortiz 22 April 2010 (has links) O presente trabalho apresenta um estudo associado à separação de gás para escoamento gás-líquido em um duto anular inclinado. Esse tipo de escoamento e geometria são encontrados em separadores de gás do tipo shroud invertido na indústria de petróleo quando utilizadas técnicas de bombeamento para a exploração de poços. A presença de gás livre a montante da bomba é uma das maiores limitações dos sistemas de bombeamento, por acarretar cavitação e falhas dinâmicas nos equipamentos. O presente estudo tem por objetivo garantir a separação total de gás livre a montante da bomba através da proposição de um separador do tipo shroud invertido em tubulação inclinada para aplicação na exploração de petróleo em poços direcionais. Um estudo experimental com ar e água como fluidos de trabalho a pressão quase atmosférica foi desenvolvido visando a compreensão da fenomenologia do separador shroud invertido. Foram observados escoamentos em duto anular do tipo: bifásico gás-líquido ascendente, monofásico em canal livre e bifásico gás-líquido descendente devido ao fenômeno de aeração; foram coletados também dados de eficiência de separação em função do ângulo de inclinação, vazão do líquido e queda de pressão entre o shroud e a saída do tubo de produção. Encontrou-se uma variável de extrema importância no fenômeno de separação até agora não reportada na literatura: o nível do anular interno do shroud (NAI). Um modelo fenomenológico que prevê a separação total do gás foi desenvolvido a partir da interpretação dos fenômenos físicos observados experimentalmente. Uma correlação inédita para a modelagem do fenômeno de dissipação de energia cinética turbulenta vinculado à separação do gás é proposta. O modelo foi validado qualitativamente com dados da literatura e ajustado com os dados coletados neste trabalho, mostrando boa concordância. / This paper presents a study associated with gas separation in an inclined gas-liquid annular-duct flow. This type of flow and geometry are found in shroud-inverted gas separators applied to petroleum industries when using pumping technique for oil production. High void fraction at the pump suction of is one of the most important limitations of the SCP technique, causing cavitation and dynamics failures in the equipment. The present study aims to provide a solution for the total gas separation through the use of an innovative inclined inverted-shroud separator for directional wells. An experimental study, where air and water at near atmospheric pressure constituted the working fluids, was carried out to understand the phenomenology of the inclined inverted-shroud separator. Different annular-duct flows were observed: upward gas-liquid flow, single-phase open channel flow, downward gas-liquid flow due to the phenomenon of aeration; also new data of separation efficiency were collected as a function of inclination angle, liquid flow rate and pressure drop between the shroud and production pipe outlet. One of the most significant findings is that the liquid level of the inner annular channel (NAI) of the shroud is a very important variable in the phenomenon of separation; so far this was not reported in the literature. Based on the observations, a phenomenological model that predicts total gas separation is proposed. A new correlation for the modeling of the dissipation of turbulent kinetic energy associated with the gas separation is presented. The model was qualitatively compared with available data from the literature and quantitatively adjusted against the new experimental data obtained in this work, and the agreement was quite good. Annular channel Duto anular Duto inclinado Escoamento bifásico Escoamento gás-líquido Gas separator Gas-liquid flow Gravitational gas separation Inclined channel Separação gravitacional de gás Separador de gás Two-phase flow
39	Estudo experimental e modelagem do escoamento de emulsão inversa em tubulações / Experimental study and modeling of flow of inverse emulsion in pipes Rodriguez, Iara Hernandez 18 November 2014 (has links) O escoamento líquido-líquido, em especial o escoamento óleo-água, vem atraindo a atenção de pesquisadores devido à alta demanda pelo combustível fóssil no atual cenário petrolífero mundial e nacional. Os desafios tecnológicos colocados pelas descobertas de reservas de óleos pesados e altamente viscosos consideram, em especial, a preocupação por minimizar as perdas energéticas nas linhas. Emulsões inversas ou dispersões óleo-em-água, na qual o óleo se encontra disperso de maneira uniforme em água, caracteriza-se pela baixa viscosidade aparente, tornando-se um tipo de emulsão desejável em algumas etapas do transporte de petróleo. Esses fatos tornam essencial o estudo deste tipo de padrão para o dimensionamento e operação ótima de dutos de produção de petróleo. Contudo, não existe ainda um número abrangente de trabalhos sobre padrão disperso líquido-líquido, ao comparar com escoamento em fases separadas. Trabalhos sobre dispersões têm reportado redução de atrito sem a adição de substâncias químicas em regime turbulento. No entanto, não há ainda um entendimento satisfatório do fenômeno. Na maioria dos trabalhos, sendo quase todos realizados com óleos leves e pouco viscosos, a redução é reportada em dispersões água-em-óleo, com escassos trabalhos reportando o fenômeno em dispersões óleo-em-água. A pesquisa realizada tratou do estudo experimental e teórico de dispersões óleo-em-água em tubulações. O escoamento foi caracterizado a partir da obtenção de dados de holdup, gradiente de pressão por fricção, distribuição das fases e padrão de escoamento. Uma teoria foi proposta para explicar a redução de atrito detectada neste trabalho, baseada na existência de um filme fino de água que escoa em contato com a parede do tubo, a baixos números de Reynolds, evitando o contato direto do núcleo turbulento (mistura bifásica) com a parede do tubo. O referido filme líquido foi detectado e quantificado utilizando-se técnica visual. Além disso, um modelo dinâmico baseado na teoria de lubrificação hidrodinâmica foi desenvolvido como tentativa de explicar a formação do filme líquido parietal no escoamento turbulento de dispersões óleo-água. / Liquid-liquid flow, especially oil-water flow, has attracted the attention of researchers due to the high demand for petroleum in the current global scenario. The discovery of reserves of heavy and highly viscous oils creates new challenges which are mainly concerned with reducing the significant pressure drop in pipes. Inverse emulsion or oil-in-water dispersions in which the oil is dispersed in water is characterized by its low effective viscosity, making it a desirable type of emulsion in some steps of oil production. These facts make the study of dispersed liquid-liquid flow essential for the design and optimal operation of oil pipelines. However, the studies on such flow pattern are scanty in comparison to those on separate flows, as stratified and annular flow patterns. Drag reduction in oil-water turbulent flow without the addition of any chemical substance has been reported in some studies. This phenomenon has received increasing attention in recent years, because there is not a satisfactory understanding of its dynamics yet. Most studies, almost all using light oils, report drag reduction in dispersion of water-in-oil, with few studies reporting the phenomenon in oil-in-water dispersions. This research comprises an experimental and theoretical study on oil-in-water dispersions in pipes. Pressure gradient, holdup, phase distribution and flow patterns data were obtained to characterize the two-phase flow. A theory was proposed to explain the drag reduction detected in this work, based on the existence of a thin water film flowing in contact with the pipe wall at low Reynolds numbers, avoiding contact between the turbulent core (mixture) and the pipe wall. The liquid film was detected and quantified using visual technique. In addition, a dynamic model based on the hydrodynamic lubrication theory was developed as an attempt to explain the formation of the liquid film. Dispersed flow Dispersões óleo-água Drag reduction Escoamento disperso óleo-água Escoamento líquido-líquido Filme líquido Gradiente de pressão Liquid film Liquid-liquid flow Oil-water dispersions Pressure gradient Redução de atrito
40	Modélisation et étude expérimentale du comportement thermo hydraulique des fluides frigoporteurs diphasiques / Modelling and experimental study of the thermo hydraulic behavior of two-phase secondary refrigerants El Boujaddaini, Mohamed Najib 18 February 2011 (has links) L’objectif de ce travail consiste en l'étude expérimentale et la modélisation du comportement thermo-hydraulique d'un fluide frigoporteur diphasique (FFD) particulier : le coulis de paraffine, en écoulement dans un canal rectangulaire simulant un échangeur à plaques. Les coulis de paraffine sont constitués de particules millimétriques de paraffine, stabilisées dans une matrice poreuse el mises en suspension dans de l'eau. Les particules de paraffines sont composées de 75% en masse de Norpar®15 et de 25% de polymère tri-block qui sert à gélifier la paraffine. Les résultats expérimentaux issus de bilans sur les veines d'essai de l'installation développée el mise en place au Centre de Thermique de Lyon (CETHIL), mettent en évidence une intensification importante du coefficient d'échange thermique, due a la présence des particules dans le fluide porteur. Pour un écoulement laminaire du coulis de paraffine dans le canal de refroidissement, une multiplication moyenne par 1 ,25 à 1 ,5 du coefficient d'échange global par rapport au fluide monophasique a été enregistrée pour des fractions massiques en particules de 6 à 12 %. Par régression linéaire des résultats expérimentaux, des corrélations pour le calcul des nombres de Nusselt local et moyen sont proposées. Une approche théorique basée sur le modèle de mélanges (Mixture Mode!) a été élaborée pour étudier le comportement hydraulique et thermique du fluide frigoporteur diphasique FFD pendant son refroidissement en écoulement laminaire dans un canal rectangulaire. L'évolution des valeurs expérimentales et théoriques pour la température moyenne du fluide et le coemcien1 d'échange thermique paroi - fluide montrent qu'ils sont en bon accord. Le modèle peut être considéré comme satisfaisant car les écarts entre résultats théoriques et expérimentaux n'excèdent jamais 14 %. / This work concerns the experimental investigation and modelling of the thermo hydraulic behaviour of a new Iwo-phase secondary refrigerant, the paraffin slurry, flowing through a rectangular channel of a heat plate exchanger type. The paraffin slurries are made of millimetric bullets of paraffin, stabilized in an organic porous polymeric matrix, in suspension in water serving as a carrying fluid. The paraffin particles used contain 75% of paraffin called NORPAR®15 and 25% of a tri-block polymer of styrene with High Molecular Weight (HMW). The experimental results generated by the heat balances on the test sections of the experimental setup built in the Thermal Center of Lyon (CETHIL), highlight an important increase of the heat transfer coefficient, due to the particles presence in the carrying fluid. For a laminar flow of the paraffin slurry in the cold channel, an average multiplication by 1 .25 to 1.5 of the global heat transfer coefficient compared to the single-phase fluid was recorded for particles mass fractions of 6 to 12%. By regression of the experimental results, correlations for the local and average Nusselt number calculation for the laminar flows are proposed. The particularity of the presented correlations is their validity in the case of a pure fluid as we\l as for a two-phase fluid containing so\id particles. A model for the hydraulic and thermal behaviours studies of a Iwo-phase secondary refrigerant fluid during its cooling in laminar flow through a rectangular channel was developed it is based on the mixture model and to king the slip velocity into account. The evolution of the experimental and theoretical values for the fluid average temperature, the heat flow which crosses the walls and the heat transfer coefficient between the wall and fluid shows good agreement and the model is satisfactory since the variations never exceed 14%. Energétique Thermodynamique Fluides frigoporteurs Ffd Coulis paraffine Transferts thermiques Ecoulement laminaire Echanges thermiques Perte de charge Modélisation Paraffin slurry Phase change material Secondary refrigerant Heat transfer Solid-liquid flow Simulation Pressure drop 536.230 72

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