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521	Experimental and numerical investigation into the natural convection of TiO2-water nanofluid Ottermann, Tanja Linda January 2016 (has links) This Master of Engineering investigation focuses on the natural convection of nanofluids in rectangular cavities. The governing equations applied to analyse the heat transfer and fluid flow occurring within the cavity are given and discussed. Special attention is given to the models that were developed to predict the thermal conductivity and dynamic viscosity of such nanofluids. A review concerning past investigations into the field of natural convection of nanofluids in cavities is made. The investigation is divided into experimental works and computational fluid dynamics (CFD) numerical investigations. Through the literature review, it was discovered that many numerical models exist for the prediction of the thermophysical properties of nanofluids, specifically thermal conductivity and viscosity. Depending on the nanofluid and the application, different models can be used. The literature study also revealed that most previous works were done in the CFD field. Very few experimental studies have been performed. Numerical CFD investigations, however, need experimental results for validation purposes, leading to the conclusion that more experimental work is needed. The heat transfer capability and thermophysical properties of the nanofluid are investigated based on models found in literature. The investigation incudes measuring the heat transfer inside a cavity filled with a nanofluid and subjected to a temperature gradient. The experiment is performed for several volume fractions of particles. An optimum volume fraction of 0.005 is obtained. At this volume fraction the heat transfer enhancement reaches a maximum for the present investigation. The investigation is repeated as a numerical investigation using the commercially available CFD software ANSYS-FLUENT. The same case as used in the experimental investigation is modelled as a two-dimensional case and the results are compared. The same optimum volume fraction and maximum heat transfer is obtained with an insignificantly small difference between the two methods of investigation. This error can be attributed to the minor heat losses experienced from the experimental setup as in the CFD adiabatic walls considered. It is concluded that, through the inclusion of TiO2 particles in the base fluid (deionised water), the thermophysical properties and the heat transfer capability of the fluid are altered. For a volume fraction of 0.005 and heat transfer at a temperature difference of 50 °C, the heat transferred through the fluid in the cavity is increased by more than 8%. From the results, it is recommended that the investigation is repeated with TiO2 particles of a different size to determine the dependency of the heat transfer increase on the particle size. Various materials should also be tested to determine the effect that material type has on the heat transfer increase. / Dissertation (MEng)--University of Pretoria, 2016. / Mechanical and Aeronautical Engineering / MEng / Unrestricted UCTD Nanofluid Natural convection Titanium dioxide Volume fraction
522	Global magneto-convection models of stars with varying rotation rate Viviani, Mariangela 24 January 2020 (has links) No description available. 530 Physik (PPN621336750) Magnetohydrodynamics Dynamo Convection Turbulence Solar and stellar dynamos
523	Velmi krátkodobá předpověď srážek pro teplou polovinu roku / Precipitation nowcasting for the warm part of the year Mejsnar, Jan January 2018 (has links) Current precipitation nowcasting systems primarily use the extrapolation of observed radar reflectivity. I used the extrapolation and studied limits of the forecast using the concept of the decorrelation time (DCT). I used data from two radars covering the territory of the Czech Republic from warm parts of four years and calculated DCT in dependence on several selected conditions describing the state of the atmosphere. I found that the mean DCT for the extrapolation is 45.4 minutes. On average the increase of the DCT in comparison when the persistence forecast is employed is 13.4 minutes. However, in dependence on current conditions the DCT may increase or decrease in more than 40 %. I also explored time evolution of the DCT during two storm events. I found that the DCT may significantly change in time, which is the consequence of changing character of the atmosphere during the storm development.
524	Influence of proton transfer kinetics and natural convection on Proton-Coupled Electron Transfer (PCET) reactions Papageorgiou, Alexia 25 January 2021 (has links) (PDF) Les phénomènes de transport de matière ainsi que la cinétique des réactions chimiques sont des processus importants en électrochimie car ceux-ci contrôlent le courant mesuré. Dans ce contexte, nous nous intéressons à de simples réactions électrochimiques et à la classe des réactions de transfert couplés électrons-protons (PCET), jouant un rôle important dans les phénomènes biologiques et la conversion d’énergie. Ces réactions impliquent le transfert d’électron(s) et de proton(s) et sont représentées par un schéma carré. Alors que la cinétique de transfert d’électrons est largement étudiée, la cinétique de transfert de protons l’est plus rarement. Ces réactions sont en effet supposées être très rapides alors qu’il existe des situations où les réactions de protonation constituent l’étape limitante. La première partie de la thèse consiste à étudier la cinétique des réactions de protonation en tenant compte de la catalyse de Brönsted. Par le biais de simulations numériques, nous montrons que la catalyse augmente la réversibilité des voltampérogrammes cycliques, à des pH où le transfert couplé s’opère. Les prédictions numériques ont été comparées aux données expérimentales et les résultats sont encourageants car une même tendance est observée. L’accord quantitatif n’est cependant pas satisfaisant à ce stade. Les phénomènes de transport étant connus pour affecter les processus à l’électrode, la seconde partie de la thèse est consacrée à l’étude de l’influence de la convection. Nous commençons par présenter les différentes raisons qui peuvent expliquer les déviations expérimentales par rapport à la diffusion seule, comme la convection naturelle induite par des gradients de densité ou de tension superficielle. Nous présentons le concept de convection spontanée associé aux mouvements microscopiques de la solution. Bien que les fondements théoriques de la convection spontanée soient discutables, la théorie permet de reproduire les résultats d’un certain nombre d’expériences, souvent pratiquées en conditions non contrôlées. Ensuite, nous évaluons l’influence de la convection naturelle sur de simples réactions électrochimiques, avant de passer à l’étude des réactions PCET. Les simulations numériques nous ont permis de prévoir la déviation des chronoampérogrammes par rapport à une situation diffusive en fonction de la durée de l’expérience et de la contribution de chaque espèce à la densité de la solution. Pour une électrode située au bord supérieur, la production d’espèces plus denses amène une déviation du courant plus importante, dû au développement d’instabilités hydrodynamiques. La convection due aux gradients de densité est supposée être accentuée lorsque que les réactions électrochimiques sont couplées avec des réactions chimiques, ce qui est la définition même des PCET. Cependant, nous avons conclu à un impact négligeable de celles-ci, sauf pour de faibles valeurs de constantes cinétiques. Pour conclure, nous avons évalué d’une part l’impact de la convection due aux effets Marangoni et d’autre part son couplage à la convection induite par des gradients de densité. L’influence de ces mouvements convectifs sur le courant résultant dépend des propriétés des réactifs et des produits de la réaction, mais également de la présence d’une surface libre. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished Chimie Mécanique des fluides Electrochemistry PCET reactions Natural convection
525	Heat exchange phenomena and COP evaluation in heat pump systems coupled to single borehole heat exchangers Casellato, Francesco January 2013 (has links) In recent years a growing interest in Borehole Heat Exchangers (BHEs) has been shown in Europe thanks to the increase of installations in systems connected to Ground Source Heat Pumps (GSHPs) used for heating and cooling needs. Different geometries and technical solutions have been de- veloped in order to improve heat exchange with the ground, accompanied by several descriptive models. Recently, innovative technologies as optical fiber for a new Distributed Thermal Response Test (DTRT) have been proposed. This method allows the quantification of the BHE local perfor- mances, so that a more accurate punctual analysis of thermal phenomena is allowed. The aim of this thesis is to locate an analytical model thanks to the most recent data, to achieve the definition of overall efficiency of a single BHE in terms of thermal resistance and of a BHE-GSHP system in terms of evaluation of the Coefficient of Performance. This model accuracy will be verified with new measures in a real installation. A particular attention will be given to the thermal-fluid-dynamics aspects, defining semi-empirical correlation for free and forced convection within the BHE groundwater filling. borehole COP convection geothermal heat pump Engineering and Technology Teknik och teknologier
526	Electrochemical Sensors Enhanced by Convection and by 3D Arrays of Vertically Aligned Carbon Nanotubes Brownlee, Benjamin James 04 June 2020 (has links) Early and accessible diagnostics are important elements to reducing the negative side-effects of untreated disease. One key advancement in diagnostic monitoring is through the development of highly sensitive sensors that have the capability to detect lower concentrations, while still remaining accessible for point-of-care use. This dissertation characterizes electrochemical sensing platforms that are enhanced by convection and by 3D electrodes made from high surface area, vertically aligned carbon nanotubes (VACNTs). Free-standing VACNTs were patterned into microchannel arrays for flow-through amperometric sensing. Convective mass transfer enhancement was shown to improve sensor performance in amperometric sensing through the use of high surface area to fluid volume structures and concentration boundary layer confinement. Through-flow sensing of hydrogen peroxide produced drastically higher signals than stirred sensing, with over 90% of the hydrogen peroxide being oxidized as it passed through the channels. Non-enzymatic sensing of glucose was achieved by chemical reaction of glucose with methyl viologen to produce on average 3.4 electrons per glucose molecule, significantly higher than that obtained with enzymatic sensing with glucose oxidase. A scaled down sensor enabled detection from 200 Î¼L of glucose by flow injection analysis with a limit of detection of 360 nM and a linear sensing range up to at least 150 Î¼M glucose. Such sensing range offers the potential to measure glucose levels found in saliva. This work demonstrates the utility of high aspect ratio electrodes made of VACNTs. Convection and surface area are shown to enhance the sensitivity of flow-through VACNT amperometric sensors by effectively utilizing the available analyte to increase the measured current density. Advances in nanomaterials, combined with electrochemical impedance spectroscopy, have allowed impedimetric biosensors to have high sensitivity while remaining label-free, pushing towards enabling portable diagnosis at the point-of-care. Porous, 3D VACNT electrodes for impedance-based biosensing were fabricated with different electrode height, gap width, and configuration. Sensitivity was characterized by functionalizing the representative protein streptavidin onto VACNT electrodes for detection of biotin. Tall, closely-spaced VACNT interdigitated electrodes are shown to have the highest electroactive surface area (15x the 2D geometric area) and the highest sensitivity, allowing for a 1 ng/mL limit of detection. Aspect ratio and surface area are shown to be important factors in determining the sensitivity of 3D VACNT interdigitated electrodes for impedimetric sensing of biomolecules bound to electrode surfaces. Although this biosensing platform is shown with streptavidin and biotin, it could be extended to other proteins, antibodies, viruses, and bacteria. carbon nanotubes electrochemical sensing interdigitated electrode flow sensing convection Engineering
527	Modeling of electric arc furnaces (EAF) with electromagnetic stirring Arzpeyma, Niloofar January 2011 (has links) The influence of electromagnetic stirring in an electric arc furnace (EAF) has been studied. Using numerical modeling the effect of electromagnetic stirring on the thermal stratification and fluid flow has been investigated. The finite element method (FEM) software was used to compute the electromagnetic forces, and the fluid flow and heat and mass transfer equations were solved using a finite volume method (FVM) software. The results show that electromagnetic stirring has a significant effect on temperature homogenization and mixing efficiency in the bath. The important part of this study was calculation of heat transfer coefficient. The results show, electromagnetic stirring improves the heat transfer from the melt to scrap which is dependent on the stirring direction and force magnitudes. electric arc furnace electromagnetic stirring natural convection Materials Engineering Materialteknik
528	The origin and development of a tropical mesoscale cloud line Marks, Frank Decatur January 1981 (has links) Thesis (Sc.D.)--Massachusetts Institute of Technology, Dept. of Meteorology and Physical Oceanography, 1981. / Microfiche copy available in Archives and Science. / Vita. / Bibliography: leaves 140-145. / by Frank Decatur Marks, Jr. / Sc.D. Meteorology and Physical Oceanography. Cumulus Convection (Meteorology) Clouds Tropics
529	A phenomenological model of the unstable planetary boundary layer Heinold, David William January 1978 (has links) Thesis (M.S.)--Massachusetts Institute of Technology, Dept. of Meteorology, 1978. / Microfiche copy available in Archives and Science. / Bibliography : leaves 116-119. / by David William Heinold. / M.S. Meteorology.
530	Numerical simulation of a long-lasting mesoscale convective line. Gordon, Neil David January 1978 (has links) Thesis. 1978. Sc.D.--Massachusetts Institute of Technology. Dept. of Meteorology. / Microfiche copy available in Archives and Science. / Vita. / Bibliography : leaves 213-218. / Sc.D. Meteorology Numerical weather forecasting Convection (Meteorology) Meteorology Mathematical models

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