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81	Mechanical Effects of Flow on CO2 Corrosion Inhibition of Carbon Steel Pipelines Li, Wei 21 September 2016 (has links) No description available. Chemical Engineering Engineering CO2 corrosion Carbon steel Wall shear stress Gas-liquid slug flow Flow visualization Corrosion inhibition Cavitation
82	Experimental and kinetic modelling of multicomponent gas/liquid ozone reactions in aqueous phase : experimental investigation and Matlab modelling of the ozone mass transfer and multicomponent chemical reactions in a well agitated semi-batch gas/liquid reactor Derdar, Mawaheb M. Zarok January 2010 (has links) Due to the ever increasing concerns about pollutants and contaminants found in water, new treatment technologies have been developed. Ozonation is one of such technologies. It has been widely applied in the treatment of pollutants in water and wastewater treatment processes. Ozone has many applications such as oxidation of organic components, mineral matter, inactivation of viruses, cysts, bacteria, removal of trace pollutants like pesticides and solvents, and removal of tastes and odours. Ozone is the strongest conventional oxidant that can result in complete mineralisation of the organic pollutants to carbon dioxide and water. Because ozone is unstable, it is generally produced onsite in gas mixtures and is immediately introduced to water using gas/liquid type reactors (e.g. bubble columns). The ozone reactions are hence of the type gas liquid reactions, which are complex to model since they involve both chemical reactions, which occur in the liquid phase, and mass transfer from the gas to the liquid phase. This study focuses on two aspects: mass transfer and chemical reactions in multicomponent systems. The mass transfer parameters were determined by experiments under different conditions and the chemical reactions were studied using single component and multicomponent systems. Two models obtained from the literature were adapted to the systems used in this study. Mass transfer parameters in the semi-batch reactor were determined using oxygen and ozone at different flow rates in the presence and absence of t-butanol. t-Butanol is used as a radical scavenger in ozonation studies and it has been found to affect the gas-liquid mass transfer rates. An experimental study was carried out to investigate the effects of t-butanol concentrations on the physical properties of aqueous solutions, including surface tension and viscosity. It was found that t-butanol reduced both properties by 4% for surface tension and by a surprising 30% for viscosity. These reductions in the solution physical properties were correlated to enhancement in the mass transfer coefficient, kL. The mass transfer coefficient increased by about 60% for oxygen and by almost 50% for ozone. The hydrodynamic behaviour of the system used in this work was characterised by a homogeneous bubbling regime. It was also found that the gas holdup was significantly enhanced by the addition of t-butanol. Moreover, the addition of t-butanol was found to significantly reduce the size of gas bubbles, leading to enhancement in the volumetric mass transfer coefficient, kLa. The multicomponent ozonation was studied with two systems, slow reactions when alcohols were used and fast reactions when endocrine disrupting compounds were used. ii These experiments were simulated by mathematical models. The alcohols were selected depending on their volatilization at different initial concentrations and different gas flow rates. The degradation of n-propanol as a single compound was studied at the lowest flow rate of 200 mL/min. It was found that the degradation of n-propanol reached almost 60% within 4 hours. The degradation of the mixture was enhanced with an increase in the number of components in the mixture. It was found that the degradation of the mixture as three compounds reached almost 80% within four hours while the mixture as two compounds reached almost 70%. The effect of pH was studied and it was found that an increase in pH showed slight increase in the reaction. Fast reactions were also investigated by reacting endocrine disrupting chemicals with ozone. The ozone reactions with the endocrine disrupters were studied at different gas flow rates, initial concentrations, ozone concentrations and pH. The degradation of 17β-estradiol (E2) as a single compound was the fastest, reaching about 90% removal in almost 5 minutes. However estrone (E1) degradation was the lowest reaching about 70% removal at the same time. The degradation of mixtures of the endocrine disruptors was found to proceed to lower percentages than individual components under the same conditions. During the multicomponent ozonation of the endocrine disruptors, it was found that 17β-estradiol (E2) converted to estrone (E1) at the beginning of the reaction. A MATLAB code was developed to predict the ozone water reactions for single component and multicomponent systems. Two models were used to simulate the experimental results for single component and multicomponent systems. In the case of single component system, good simulation of both reactions (slow and fast) by model 1 was obtained. However, model 2 gave good agreement with experimental results only in the case of fast reactions. In addition, model 1 was applied for multicomponent reactions (both cases of slow and fast reaction). In the multicomponent reactions by model 1, good agreement with the experimental results was also obtained for both cases of slow and fast reactions. 628
83	Etude du comportement de mousse céramique comme contacteur Gaz/Liquide à contre courant : application à la distillation et à la distillation réactive / Study of the behaviour of ceramic foam as gas/liquid contactor at counter current : application in distillation and reactive distillation Lévêque, Julien 05 November 2010 (has links) Ces travaux de thèse abordent la problématique du développement d'internes destinés à la distillation réactive. La méthodologie à suivre est appliquée dans le cas des mousses céramiques en Carbure de Silicium. Le comportement hydrodynamique a été étudié ainsi que la capacité en transfert de matière validant la possible application des mousses en tant que garnissage destiné à la distillation. L'activation catalytique du support a ensuite été développée afin de dégager la méthode la plus intéressante permettant d'approcher le garnissage de référence, le KATAPAK, en termes d'activité catalytique. Le greffage d'Amberlyst 15 est alors apparu comme la voie la plus intéressante pour la possible application des mousses greffées comme interne catalytique destiné à la distillation réactive. / This work of thesis approaches the problems of the development of packings intended for reactive distillation. Methodology to be followed is so applied in the case of ceramic foam in Silicon Carbide. The hydrodynamic behaviour was studied as well as the mass transfer efficiency demonstrating the possible application of ceramic foam as a packing for distillation. The aspect of the catalytic activation of the support was then developed in order to determine the most efficiency method in terms of catalytic activity making it possible to approach reference packing, the KATAPAK. The coating of Amberlyst 15 then appeared as the most interesting way for the possible application of coating foam as catalytic packing for reactive distillation. Mousse céramique Contacteur gaz/liquide Contre courant Catalyseur Greffage Distillation réactive Ceramic foam Gas/liquid contactor Counter current Catalyst Coating Reactive distillation.
84	Contacteurs à membranes denses pour les procédés d'absorption gaz-liquide intensifiés : application à la capture du CO₂ en post combustion. / Dense membrane contactors for intensified gas-liquid absorption processes : application to CO₂ capture by post combustion. Nguyen, Phuc Tien 11 March 2011 (has links) Dans le cadre de la recherche de procédés d'absorption gaz-liquide intensifiés, cette étude vise au développement des contacteurs membranaires pour la capture du CO₂ en post combustion, comparativement aux colonnes garnies. Les contacteurs à membranes fibres creuses microporeuses permettent un transfert de matière élevé mais sont confrontés à des problèmes de mouillage entraînant une dégradation importante des performances dans le temps. Notre but est de concevoir des fibres composites constituées d'une structure microporeuse et d'une peau dense fine et fortement perméable au CO₂ afin d'établir une barrière au passage du liquide et de limiter la résistance au transfert de matière. Pour cela, nous avons sélectionné des polymères super vitreux comme le PTMSP et le Téflon AF2400 qui se caractérisent par une très forte perméabilité au CO₂ et une bonne compatibilité chimique avec la MEA (liquide d'absorption de référence). Les fibres composites ont été réalisées par un procédé de recouvrement conduisant à une faible épaisseur de peau dense (1 à 2 microns). Des modules à fibres composites ont été testés pour séparer un mélange CO₂/N2 avec une solution aqueuse de MEA. Les fibres composites présentent des efficacités de capture similaires à celles des fibres microporeuses mais assurent en plus le maintien des conditions de non mouillage. Des simulations, reposant sur une modélisation 2D du transfert de matière, ont permis de prédire les performances des contacteurs membranaires à fibres composites dans des conditions plus proches de la réalité industrielle et ont mis en évidence un facteur d’intensification pouvant aller jusqu’à 6 par rapport aux colonnes garnies / The present work aims to explore the intensification of gas-liquid absorption processes. This study is applied to post combustion CO₂ capture by means of membrane contactors in comparison to packed columns. Microporous hollow fiber membrane contactors lead to high mass transfer but wetting problems are likely to occur and result in tremendous deterioration in performances with time. Our objective is to develop composite hollow fibers based on a microporous structure and a thin dense layer highly permeable to CO₂, in order to create a real barrier to liquid penetration and to limit mass transfer resistance. Super glassy polymers as PTMSP and Teflon AF2400 were selected for their extremely high CO₂ permeability and their chemical resistance to MEA (reference absorption liquid). Composite hollow fibers were made by coating and the dense layers obtained are thin (1 to 2 microns). Composite hollow fiber membrane contactors were tested for the separation of a CO₂/N2 mixture with an aqueous solution of MEA. Capture ratios achieved by composite hollow fibers are similar to those measured for microporous membranes and the dense layer prevents from wetting problems. Simulations based on 2D modeling of the mass transfer, show that the performances of composite hollow fiber membrane contactors, under operating conditions close to the industrial case, can lead to an intensification factor up to 6 compared to packed columns Intensification Absorption gaz-liquide Capture du CO₂ Contacteur membranaire Mouillage Membrane dense Intensification Gas-liquid absorption CO₂ capture Membrane contactor Wetting Dense membrane
85	Etude expérimentale et numérique de séparateurs gaz-liquide cyclindriques de type cyclone / Experimental and numerical investigation of cyclone gas-liquid separators Hreiz, Rainier 07 December 2011 (has links) Ce travail se penche sur l'étude expérimentale et la simulation numérique du GLCC, un séparateur gaz-liquide cyclonique destiné à de l'industrie pétrolière.Les expériences sont menées sur un pilote air-eau. Dans un premier temps, des observations visuelles ont permis de caractériser le fonctionnement du système en fonction des débits d'entrée. L'influence de la géométrie du système ainsi que des propriétés des fluides sont également considérées.Dans un second temps, l'hydrodynamique de l'écoulement tourbillonnaire dans le séparateur est étudiée par vélocimétrie laser Doppler.Cette étude expérimentale, en mettant l'accent sur le rôle important du fillament tourbillonnaire, a permis d'expliquer pour la première fois divers aspects des écoulements tourbillonnaires turbulents. L'analyse des résultats met également en évidence les nombreuses limites du modèle théorique utilisé pour dimensionner les GLCCs.Côté numérique, les écoulements tourbillonnaires en conduite sont étudiés par une approche CFD utilisant le code commercial Fluent 6.3. Les résultats montrent que la CFD peut reproduire correctement les écoulements tourbillonnaires monophasiques. Cependant, en diphasique, les techniques de simulation actuelles ne conviennent pas pour simuler ce type d'écoulement. / This work focuses on the experimental study and numerical simulation of the GLCC, a gas-liquid cyclone separator developed for the oil industry.The experiments are conducted on an air-water pilot. In a first step, visual observations were used to characterize the system operation according to the incoming flow rates. The influence of system's geometry and the fluid's properties are also considered.In a second step, the hydrodynamics of the vortex flow in the separator is studied by laser Doppler velocimetry.This experimental study, focusing on the important role of the vortex filament, allowed to explain for the first time various aspects of turbulent swirling flows. The analysis of the results also highlights the many limitations of the theoretical model used to design the GLCC.On the numerical side, the swirling flows in pipes are studied via the CFD commercial code Fluent 6.3. The results show that CFD can correctly reproduce the single-phase vortex flow.However, for multiphase flow simulations, it is shown that the current simulation techniques are not suitable to simulate this type of flow. GLCC Cyclone gaz-liquide Ecoulement tourbillonnaire Ecoulement diphasique LDV CFD GLCC Gas-liquid cyclone Swirl flow Vortex flow Multiphase flow LDV CFD 620
86	Modélisation et simulation de contacteurs membranaires pour les procédés d'absorption de gaz acides par solvant chimique / Modeling and simulation of membrane contactors for acid gas absorption processes by chemical solvents Boucif, Noureddine 30 November 2012 (has links) L'objectif primordial de cette thèse est la recherche de modèles mathématiques qui sont à mieux de décrire le processus d'absorption gaz-liquide dans un contacteur membranaire à fibres creuses poreuses ou denses. La configuration géométrique de ces contacteurs combinée à leur compacité, et de leur faible consommation d'énergie leur permet de se substituer progressivement aux procédés conventionnels tels les colonnes à garnissage et autres tours d'absorption. Notre but est d'étudier la performance de ces processus novateurs par l'élaboration de modèles mathématiques de plus en plus rigoureux. Pour cela, nous avons étudié plusieurs cas de figures où l'hydrodynamique d'écoulement des fluides, la nature du soluté et/ou du solvant ont été changées. Dans un premier temps, il n'a été tenu compte que de l'hydrodynamique du compartiment côté fibre pour deux types de processus d'absorption avec et sans réaction chimique. Par la suite, l'hydrodynamique d'écoulement des fluides dans le côté fibre comme côté calandre a été prise en considération. Des modèles ont été développés pour l'absorption classique de gaz carbonique dans des solutions de monoéthanolamine (liquide d'absorption de référence) où l'écoulement du fluide côté calandre est assimilé à un écoulement piston dans un premier cas, obéissant au modèle dit de surface libre "modèle de Happel" dans un deuxième cas, et enfin caractérisé par des équations de moments de Navier-Stokes dans un troisième cas. La comparaison des résultats numériques de ces modèles a montré que ceux du troisième cas de figure sont les plus proches des résultats d"essais expérimentaux / The overarching objective of this thesis is the research of mathematical models which are better to describe the process of gas-liquid absorption in a membrane contactor with porous or dense hollow fibers. The geometric configuration of these contactors, combined with their low energy consumption and their compactness, allows them to gradually replace conventional processes such as packing towers and absorption columns. Our goal is to study the performance of these innovative processes by developing more rigorous mathematical models. In this scope, we studied several cases where the hydrodynamics of fluid flow, the nature of the solute or solvent have been changed. First, only the hydrodynamics of the fibre side compartment has been taken into account for two types of an absorption process with and without chemical reaction. Subsequently, the hydrodynamics of fluid flow in both the fiber side as shell side were taken into consideration. Models have been developed for classical carbon dioxide absorption in monoéthanolamine solutions (liquid absorption of reference) where the flow fluid in the shell were is assumed to obey a plug-flow in a first case, described by the surface free model known as "Happel model" in a second case, and finally characterized by the momentum Navier-Stokes equations in a third case. The comparison of the numerically simulated results collected from the three models showed that those of the third case matched very closely with the laboratory experimental results Absorption gaz-liquide Contacteur membranaire Capture de CO2 Modélisation mathématique Simulation numérique Gas-liquid Absorption Membrane Contactor CO2 Capture Mathematical Modelling Numerical Simulation 660.284 24
87	Mass transfer in intermittent horizontal gas-liquid flow and application to photobioreactors / Transfert de masse dans les écoulements gaz-liquide horizontaux intermittents et application aux photobioréacteurs Valiorgue, Pierre 03 December 2012 (has links) Sécuriser un approvisionnement fiable de micro-algues est récemment devenu un enjeu industriel. Pour assurer la croissance de micro-algues dans des photobioréacteurs clos, un transfert de masse optimum de l'oxygène et du dioxyde de carbone doit être assuré. Dans cette thèse, une étude du transfert de masse gaz-liquide dans les conduites horizontales a été menée. Dans les trois premiers chapitres, un modèle unidimensionnel de transfert de masse dans le photobioréacteur a été développé. Tout d'abord, le transfert de masse entre une bulle de gaz allongée et un écoulement liquide turbulent a été 'étudié expérimentalement. En considérant l'interface comme étant plane, les coefficients de transfert de masse mesurés sont proches d'une corrélation de Lamourelle (1972). Le modèle de Taitel pour les écoulements stratifiés a été comparé à des modèles plus complets pour la prédiction de l'interface des bulles allongées. Une approche analytique basée sur un bilan de masse et utilisant les modèles testés a ensuite été développée et adaptée à un photobioréacteur afin de prédire l'efficacité de la conversion du CO2 en biomasse en fonction des paramètres d'exploitation. Les deux derniers chapitres visent à développer une simulation numérique du transfert de masse gaz-liquide. Une mesure de la concentration en CO2 dans le sillage d'une bulle de gaz ascendante a été effectuée à l'aide d'une méthode améliorée de traitement des données de Fluorescence Induite par Plan Laser (FIPL). Enfin, une simulation numérique a été réalisée sous COMSOL / Securing a reliable supply of microalgae has recently become an industrial stake. To ensure successful growing of microalgae in enclosed, tubular photobioreactor systems as in Microphyt, an optimum mass transfer of oxygen and carbon dioxide should be secured. In this thesis an investigation of the gas-liquid mass transfer in horizontal pipes has been conducted. In the first three chapters, a one dimensional mass transfer model in horizontal gas-liquid flows will be developed and applied to horizontal photobioreactors. Firstly, a study of mass transfer between an elongated gas bubble under a turbulent liquid flow immobilized in a duct has shown that under the hypothesis considering the interface as a flat plane estimated, the measured mass transfer coefficients appear to be well fitted by a correlation from Lamourelle (1972). The interface prediction for stratified flows have been compared to more complete unit-cell models for intermittent flow interface and found to be a good first estimate. The photobioreactor’s conversion efficiency of CO2 into biomass as a function of operating parameters is investigated using an analytical approach to complete the mass balance and classical two-phase flow approach from Taitel (1976). The last two chapters aim at developing a numerical simulation of gas-liquid mass transfer. A measurement of CO2 wake structures behind free rising bubbles have realized using an improved data treatment method for Planar laser-induced fluorescence (PLIF) and pH sensitivity of fluorescein sodium. Finally, an implementation of the experimental measurements under COMSOL has been realised Transfert de masse Bulle allongée Bioconversion du CO2 Écoulement gaz-liquide Photobioréacteur Microalgue FIPL Mass transfer Elongated bubble CO2 bioconversion Gas-liquid flow Photobioreactor Microalgae PLIF 532
88	Modeling Of Liquid Flow In A Packed Bed Under Influence Of Gas Flow Singh, Vikrant 09 1900 (has links) The aim of the current study is to model (non-wetting) liquid flow in a packed bed under the influence of gas flow. It has been observed experimentally that non-wetting liquid flows in a packed bed in form of small droplets and rivulets falling through the void regions. Continuum models have not been successful in predicting liquid flow paths when the liquid is injected through a point source in the packed bed. In the current study, we present a discrete deterministic model for modeling the liquid flow in a packed bed, under the influence of gas flow. When a high velocity gas blast in injected into a dry packed bed, a cavity or a void is formed in front of the nozzle. The cavity size increases with increasing gas velocity and exhibits hystersis in size upon increasing and decreasing gas flow rate. The cavity size is very important in determining the gas penetration into the packed bed. A proper gas flow profile prediction is necessary for determining it’s effect on the liquid flow behavior. Attempts at modeling cavity sizes have mostly been confined to experimental studies and development of correlations. Different correlations show different dependence on operating as well as bed parameters and a fundamental understanding of the cavity formation and hystersis phenomena is missing. We adopt a combined Eulerean-Lagrangian approach to study the above mentioned phenomena mathematically. Gas is modeled as a continua and solid as discrete (soft sphere D.E.M. approach). Hystersis and cavity formation studies are carried out in a 2D-slot rectangular packed bed. A discrete deterministic liquid flow model (developed and validated under structured packing conditions using x-ray radiography flow visualization technique), is used to study the effect of presence of liquid on the dry bed void size, when liquid is injected in a packed bed through a point source. It is found that the gas pushes the liquid away from the nozzle side wall. Also, the cavity sizes during gas velocity decreasing case are found to be larger in size than the void size obtained during velocity increasing case for the same inlet gas flow rate. This difference is void size leads to more gas penetration into the bed and thus more liquid shift away from the nozzle side wall. Presence of liquid is found to affect the void size (compared to dry bed size) negligibly. Liquid Flow - Modelling Gas Flow Blast Furnace Fluid Dynamics Gas Dynamics Cavity Size Hysteresis Packed Bed Liquid Flow Model Gas Liquid Flow Metallurgy
89	Innovating microstructured gas-liquid-solid reactors : a contribution to the understanding of hydrodynamics and mass transfers Tourvieille, Jean-Noël 26 February 2014 (has links) (PDF) To meet the new challenges of the chemical indutries, the developpement of new heterogeneous catalytic reactors and their understanding are mandatory. From these perspectives, new reactor designs based on structuring at micro or millimeter scales have emerged. They have sparked interest for their ability to decrease physical limitations for heat and mass transfers. Thus, two advanced reactor technologies for gas-liquid-solid catalysed reactions are studied. The first reactor is a micro-structured falling film (FFMR) in which vertical sub millimetric grooves are etched and coated with a catalyst. This structuration allows stabilizing the gas-liquid interface of a down flow liquid phase. A thin liquid film is generated leading to high specific surface areas. Commercially available, it represents a very good potential for performing demanding reactions (i.e.fast, exothermic) for small scale productions such as pharmaceuticals. In a second part, a new reactor concept is proposed. Open cell foams are used as catalyst support and inserted in a milli-square channel. The reactor is then submitted to a preformed gas-liquid Taylor flow. In both cases, hydrodynamics features are studied by using microscopy based methods. Their potential in terms of mass transfers are also studied by performing catalyzed α-methylstyren hydrogenation. For both reactors, it comes out that the particular flow induced by micro or milli structures leads to at least one order of magnitude higher mass transfers performances than mutliphase reactors currently used in the industry albeit it remains to be demonstrated at such scale. From all these studies, correlations, models and methods for chemical engineers (hydrodynamics, pressure drops, mass transfer) are proposed for the two reactors Microstructuring Gas-liquid-solid Mass transfer Hydrodynamics Heterogeneous catalysis Open cell foams Falling film
90	Heat transfer in upward flowing two-phase gas-liquid mixtures : an experimental study of heat transfer in two-phase gas-liquid mixtures flowing upwards in a vertical tube with liquid phase being driven by a pump or air injection Alahmad, Malik I. N. January 1987 (has links) An experimental investigation has been carried out to study the heat transfer in a two-phase two-component mixture flowing upward inside a 1" double pipe heat exchanger. The heat transfer coefficient was measured using either air to lift the liquid (air-lift system) or a mechanical pump. The heat transfer coefficient results have been extensively studied and compared with other workers' results. An attempt was made to correlate the present heat transfer data in dimensionless correlations. Possible factors affecting the two-phase heat transfer coefficient have been studied with special attention being given to the fluid properties, particularly the liquid viscosity. Experiments were also carried out to investigate the effect of solid particles added to a liquid flow on the measured heat transfer coefficient. The present investigation was carried out using air as the gas-phase ranging from 2x 10-5 up to 80 x 10-5 m3/s. Liquids used were water and glycerol solutions with viscosity ranging from 0.75 up to 5.0 C. P. and flowrates between 4x 10-5 and 25 x 10-5 m3/s. Void fraction and pressure drop were also measured during the heat transfer process. Flow pattern in gas-liquid mixture was investigated in a perspex tube of identical dimensions to the heat exchanger tube. 536.7

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