Global ETD Search

121	Análise numérica da dinâmica do escoamento em circuitos de circulação natural / Numerical analysis of the fluid dynamics in a natural circulation loop ANGELO, GABRIEL 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:41:29Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:03:20Z (GMT). No. of bitstreams: 0 / Circuitos de convecção natural ou sistemas de circulação natural são empregados em diversas áreas da engenharia. Reatores nucleares refrigerados a água utilizam circuitos de circulação natural como método passivo de seguranca. Em situações críticas, sem qualquer controle externo, o sistema permanece em segurança por suas próprias características de funcionamento (intrinsecamente seguro). O trabalho proposto consiste em estudar numericamente o circuito de circulação natural de água, localizado no Instituto de Pesquisas Energéticas e Nucleares / Comissão Nacional de Energia Nuclear em São Paulo, por meio do uso de modelos matemáticos, objetivando determinar o padrão do escoamento em condições sem mudança de fase líquido-vapor. A comparação dos resultados de temperatura obtidos por cada um dos modelos de turbulência aos pontos instrumentados no circuito experimental, na condição transitória, revelou desvios significativos nas respostas do modelo de zero equação. Desvios intermediário foram observados nos modelos de transporte da viscosidade turbulenta (EVTE), k - ω, SST e SSG e resultados melhores foram vericados nos modelos k - ε e DES (com significativa superioridade do primeiro modelo). / Tese (Doutoramento) / IPEN/T / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP brazilian cnen natural convection fluid flow turbulence flow heat transfer hydrodynamics mathematical models reactor safety pwr type reactors
122	Estabelecimento de um sistema padrão primário para raios X de energias baixas com uma câmara de ionização de ar livre / Establishment a primary standard system for low energy X-rays using a free air ionization chamber SILVA, NATALIA F. da 22 June 2016 (has links) Submitted by Claudinei Pracidelli (cpracide@ipen.br) on 2016-06-22T12:43:46Z No. of bitstreams: 0 / Made available in DSpace on 2016-06-22T12:43:46Z (GMT). No. of bitstreams: 0 / Neste trabalho foi estabelecido um sistema padrão primário para raios X de energias baixas (10 kV a 50 kV), utilizando uma câmara de ionização de ar livre de cilindros concêntricos da marca Victoreen (modelo 481-5) no Laboratório de Calibração de Instrumentos (LCI) do Instituto de Pesquisas Energéticas e Nucleares (IPEN/CNEN-SP). Para isso foi desenvolvido um novo protocolo de alinhamento da câmara de ionização no sistema de radiação e foi feita uma modificação no suporte dos micrômetros utilizados para o movimento dos cilindros internos. Os resultados obtidos nos testes de estabilidade e de caracterização ficaram dentro dos limites estabelecidos pelas normas IEC 61674 e IEC 60731. Foram determinados também os fatores de correção para atenuação de fótons no ar, transmissão e espalhamento no diafragma, espalhamento e fluorescência, e recombinação iônica. Esses valores foram comparados com os valores obtidos pelo laboratório padrão primário alemão,Physikalisch-Technische Bundesanstalt (PTB), mostrando boa concordância. Por último, foi determinado o valor absoluto da grandeza taxa de kerma no ar para as qualidades padronizadas de mamografia de feixes diretos WMV28 e WMV35 e feixes atenuados WMH28 e WMH35; os resultados são compatíveis, com diferença máxima de 3,8% com os valores obtidos utilizando o sistema padrão secundário do LCI. / Dissertação (Mestrado em Tecnologia Nuclear) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP ionization chambers natural convection cylinders orbit stability phase stability control systems calibration cosmic photons electron diffraction calibration standard model
123	[en] NATURAL CONVECTION AND RADIATION HEAT TRANSFER FROM SHROUDED VERTICAL FINS / [pt] TRANSFERÊNCIA DE CALOR POR CONVECÇÃO NATURAL E RADIAÇÃO DE ALETAS VERTICAIS COM ANTEPARA CLAUDIO MARCELO DOS SANTOS FERREIRA 05 August 2015 (has links) [pt] Experimentos foram realizados para se determinar as características de transferência de calor de modo combinado, por convecção natural e radiação, de um conjunto de aletas retangulares e verticais, com antepara, em ar. Os seguintes parâmetros foram avariados durante o curso dos experimentos: comprimento longitudinal das aletas, diferença de temperatura aleta-ambiente, altura das aletas e a folga entre aletas/antepara. Anteparas possuindo características térmicas distintas foram empregadas (altamente condutora e isolante). Para cada configuração variou-se o Número de Rayleigh entre 4,0 x 10(1) a 7,0 x 10(2). Encontrou-se que o posicionamento de uma antepara próxima às alentas reduz a taxa de troca de calor de modo combinado quando comparado ao caso sem antepara. Encontrou-se, também, que as anteparas metálicas forneceram taxas de transferência de calor maiores que as isoladas. Cálculos mostraram que, quando a folga aleta/antepara era nula, a parcela convectiva era dominante. Para outros valores da folga, a contribuição da componente radiativa era da mesma ordem de grandeza da convectiva. A contribuição da parcela radiativa era maior para baixos valores do Número de Rayleigh e para valores da folga aleta/antepara diferentes de zero. / [en] Experiments were performed to determine the combined-mode natural convection/radiation heat transfer characteristics of a shrouded array of rectangular, vertical fins. The investigated parameters included the height and the longitudinal lenght of the fins, the clearance gap between the shroud and the fin tips and the fin to ambient temperature difference. Shroud walls having different thermal characteristics were used (highly conducting and insulated). For each configuration, the Rayleigh Number ranged from 4,0 x 10 (1) to 7,0 x 10 (2). It was found that the positioning of a shrouding surface close to the fins decreased the rate of combined mode heat transfer when compared to the unshrouded case. Greater heat transfer rates were found for the conducting wall shroud in comparison with the insulated one. Calculations performed showed that, when the clearance gap between the shroud and the fin tips was zero, the convective component was dominant. For other clearance gaps, the contribution of radiation was of the same order of magnitude of the convective one. The contribution of the radiative component was greater for small values of the Raileigh Number and for clearance gaps different from zero. [pt] CONVECCAO NATURAL [en] NATURAL CONVECTION [pt] TRANSFERENCIA DE CALOR [en] HEAT TRANSFER [pt] RADIACAO [en] RADIATION [pt] ALETAS VERTICAIS [en] VERTICAL FINS
124	Geometric optimization for the maximum heat transfer density rate from cylinders rotating in natural convection Page, L.G. (Logan Garrick) 25 June 2012 (has links) In this study we investigates the thermal behavior of an assembly of consecutive cylinders in a counter-rotating configuration cooled by natural convection with the objective of maximizing the heat transfer density rate (heat transfer rate per unit volume). A numerical model was used to solve the governing equations that describe the temperature and flow fields and an optimization algorithm was used to find the optimal structure for flow configurations with two or more degrees of freedom. The geometric structure of the consecutive cylinders was optimized for each flow regime (Rayleigh number) and cylinder rotation speed for one and two degrees of freedom. Smaller cylinders were placed at the entrance to the assembly, in the wedge-shaped flow regions occupied by fluid that had not yet been used for heat transfer, to create additional length scales to the flow configuration. It was found that the optimized spacing decreases and the heat transfer density rate increases as the Rayleigh number increases, for the optimized structure. It was also found that the optimized spacing decreases and the maximum heat transfer density rate increases, as the cylinder rotation speed was increased for the single scale configuration at each Rayleigh number. Results further showed that there was an increase in the heat transfer density rate of the rotating cylinders over stationary cylinders for a single scale configuration. For a multi scale configuration it was found that there was almost no effect of cylinder rotation on the maximum heat transfer density rate, when compared to stationary cylinders, at each Rayleigh number; with the exception of high cylinder rotation speeds, which serve to suppress the heat transfer density rate. It was, however, found that the optimized spacing decreases as the cylinder rotation speed was increased at each Rayleigh number. Results further showed that the maximum heat transfer density rate for a multi scale configuration (with stationary cylinders) was higher than a single scale configuration (with rotating cylinders) with an exception at very low Rayleigh numbers. / Dissertation (MEng)--University of Pretoria, 2012. / Mechanical and Aeronautical Engineering / unrestricted Rotating cylinders Optimal packing Mathematical optimization Natural convection Multi scale Counter-rotation Heat transfer density rate UCTD
125	Escoamento natural entre placas planas verticais com aquecimento assimetrico Martinelli, Valdisley Jose 04 September 1998 (has links) Orientador: Kamal Abdel Radi Ismail / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecanica / Made available in DSpace on 2018-07-24T07:44:11Z (GMT). No. of bitstreams: 1 Martinelli_ValdisleyJose_M.pdf: 3830645 bytes, checksum: fa60238d6afea2e97d6f6e2886a91fc4 (MD5) Previous issue date: 1998 / Resumo: O objetivo deste trabalho é estudar o desenvolvimento de transferência de calor laminar por convecção natural em canais de placas planas verticais sujeito a aquecimento assimétrico. São analisadas condições de contorno com fluxo de calor uniforme nas paredes das placas e temperatura da parede uniforme. Soluções para escoamento em regime permanente são obtidos para o ar para diferentes fluxos de calor e diferentes temperaturas nas paredes (acima da temperatura do fluido na entrada do canal); bem como para diferentes geometrias do canal (variação da distância entre as placas (b)). As equações foram escritas em diferenças finitas utilizando variáveis primitivas e resolvidas implicitamente, usando discretização central em todos os termos das equações governantes, exceto para o caso de fluxo de calor que foi utilizado diferença unilateral de três níveis nos termos da derivada da temperatma. Os resultados indicam que existe uma distância ótima entre as placas onde ocorre a máxima troca de calor entre as placas e o fluido. Os resultados foram comparados com a literatura, tanto trabalhos numéricos como experimentais / Abstract: This work studies the developm.entof laminar free convection in vertical flat parallel plates with asymmetric heating. Thermal boundary conditions of uniform wall heat fluxes and uniform wall temperature are considered. Solutions of the flow on steady state are obtained for air at different wall heat fluxes and wall temperature differences (above the temperature of the fluid at the channel) and also different geometries of the channel (distance between the plates (b)). The equations were written in finite difference using primitive variables and they were solved by implicitesqueme all the terms of the governing equations, and by means of a three point derivative formula the terms wall temperature at heat fluxes. The results show there is one optimal distance between the plates to maximize the heat transfer. The results were compared with the literature, both numerical and experimentalworks / Mestrado / Termica e Fluidos / Mestre em Engenharia Mecânica Calor - Convecção natural Fluxo laminar Calor - Transmissão Diferenças finitas Natural convection Laminar flow Transmission of heat Finite differences
126	Polymeric Hollow Fiber Heat Exchanger Design / Polymeric Hollow Fiber Heat Exchanger Design Astrouski, Ilya January 2016 (has links) This Ph.D. thesis is focused on theory and experimental investigations developing of new knowledge about polymeric hollow fiber heat exchanger (PHFHE). The state-of-the-art study of plastic heat exchangers shows that their usage is limited by several niches where their advantages significantly dominates, or where the use of non-plastic competitors is not impossible. On the other hand, plastic heat exchangers (and PHFHEs in particular) are devices of increasing interest. It is shown that use of small tubes (fibers) allows PHFHEs to be more competitive than conventional plastic heat exchangers. Small hydraulic diameter of a fiber causes high heat transfer coefficients, reduces thermal resistance of plastic wall and allows it to create light and compact design. Detailed study of fluid flow and heat transfer inside the hollow fiber showed that conventional approaches for single-phase laminar flow can be utilized. Poiseuille number equal to 64 and Nussel number about 4 are recommended to be used to predict pressure drops and heat transfer coefficient, respectively. Additional attention should be paid to careful determination of fiber diameter and liquid properties (viscosity). Scaling effects, such as axial heat conduction, thermal entrance region and viscous dissipation can be neglected. The study of outside heat transfer showed that heat transfer on fiber bunches are intense and are competitive to contemporary compact finned-tube heat exchangers. The Grimson approach showed clear correlation with experimental results and, thus is recommended to predict heat transfer coefficients on fiber bunches. Two types of fouling (particulate- and biofouling) of outer fiber surface were experimentally studied. It was found that particulate fouling by titanium oxide particles is not intense and deposits can be removed relatively easy. However, fouling is much more intense when it is associated with biofouling caused by wastewater. In this case, smooth and low-adhesive surface of plastic is not sufficient precaution to prevent deposit formation.
127	Stockage de la chaleur dans un lit de particules à changement de phase / Heat storage in a phase change particle bed Belot, Malik 21 November 2018 (has links) La thèse porte sur la caractérisation des transferts thermiques dans les milieux fluide-particules, notamment en proposant un modèle décrivant le changement de phase au sein de particules sous écoulement fluide. Les transferts thermiques sont modélisés en prenant en compte l'influence de la résistance aux transferts externes (échanges avec le fluide) et internes (conduction à travers la particule et sa paroi, convection naturelle dans la phase liquide de la particule, changement de phase) à la particule. Les échanges externes avec le fluide sont pris en compte à l’aide de corrélations liant un nombre de Nusselt externe aux nombres de Reynolds et de Prandtl. La conduction interne est décrite à l’aide de solutions analytiques. L’effet de la convection naturelle a été étudié sur une particule isolée soumise à un gradient de température sous différents nombres de Rayleigh et de Prandtl permettant son déclenchement. Les résultats obtenus ont permis d’établir une corrélation reliant un nombre de Nusselt interne aux nombres de Prandtl et Rayleigh de la particule. Cette corrélation permet de recalculer l’évolution temporelle de la température moyenne de la particule en prenant en compte l’effet de la convection naturelle. Le changement de phase est décrit grâce à un modèle local basé sur l’approche « Phase Field » moyenné sur l’ensemble de la particule et validé par comparaison avec des résultats numériques et expérimentaux issus de la littérature. Enfin, le modèle complet et l’influence des phénomènes pris en compte sont testés sur un lit fixe de particules à l’échelle moyennée (Discrete Element Method–Computional Fluids Dynamics). La conduction et la convection interne donnent une quantité totale d’énergie stockée relativement similaire dans le lit à nombre de Biot égal, mais dont la distribution est différente. Le changement de phase tend à grandement densifier le stockage. Une augmentation du nombre de Biot tend à augmenter la quantité d’énergie stockée. Enfin, il est montré que les transferts sont dépendants de la distribution de porosité. / This work intends to characterize heat transfer in fluid-particle flows, specifically when phase change occurs inside the particles. The proposed model takes into account the external heat resistance (heat transfer at the particle-fluid interface) and the internal heat resistance (conduction inside and at the wall of the particle, natural convection in the liquid phase of the particle, phase change). External transfer with the surrounding fluid is described by correlations linking an external Nusselt number to Reynolds and Prandtl numbers related to the surrounding fluid. Internal conduction is calculated thanks to analytical solutions. The influence of natural convection was studied on an isolated sphere for different combinations of Rayleigh and Prandtl numbers. A correlation between an internal Nusselt number, and particle Rayleigh and Prandtl numbers was established using these simulations. This correlation allows calculating the transient evolution of the average temperature of the particle when natural convection occurs. Phase change is taken into account by a Phase Field model averaged over the particle and validated by comparison with experimental and numerical studies from the literature. Finally, the whole model and the effects of the different phenomena it describes are tested on a fixed bed of particles at mesoscopic scale using a Discrete Element Method–Computional Fluids Dynamics (DEM-CFD) model. Internal conduction and natural convection gives similar quantities of total energy stored for the same Biot number, however heat transfer distribution is modified. Phase change greatly reduces the volume of storage. Increasing the Biot number leads to a greater amount of energy stored. Finally, heat transfer greatly depends on porosity distribution. Mécanique des fluides Transferts thermiques Changement de phase Convection naturelle MCP Fluid Mechanics Heat tansfer Phase change Natural convection PCM 530 620
128	Numerical Model of MeltingProblems Arosemena, Arturo January 2018 (has links) In the present study, a finite volume method is employed to modelthe advection-diffusion phenomenon during a pure substance meltingprocess. The exercise is limited to a benchmark problem consisting ofthe 2D melting from a vertical wall of a PCM driven by natural convectionin the melt. Numerical results, mainly the temporal evolutionof average Nusselt number at the hot wall and the average liquid fraction,are validated by available literature data and the effect of thermalinertia in the heat transfer is considered as well. Finally, motivatedby recent publications and the model presented here, possible new researchtopics are proposed. Phase change materials fluid dynamics heat transfer natural convection melting enthalpy-porosity technique. Engineering and Technology Teknik och teknologier
129	Application of probabilistic deep learning models to simulate thermal power plant processes Raidoo, Renita Anand 18 April 2023 (has links) (PDF) Deep learning has gained traction in thermal engineering due to its applications to process simulations, the deeper insights it can provide and its abilities to circumvent the shortcomings of classic thermodynamic simulation approaches by capturing complex inter-dependencies. This works sets out to apply probabilistic deep learning to power plant operations using historic plant data. The first study presented, entails the development of a steady-state mixture density network (MDN) capable of predicting effective heat transfer coefficients (HTC) for the various heat exchanger components inside a utility scale boiler. Selected directly controllable input features, including the excess air ratio, steam temperatures, flow rates and pressures are used to predict the HTCs. In the second case study, an encoder-decoder mixturedensity network (MDN) is developed using recurrent neural networks (RNN) for the prediction of utility-scale air-cooled condenser (ACC) backpressure. The effects of ambient conditions and plant operating parameters, such as extraction flow rate, on ACC performance is investigated. In both case studies, hyperparameter searches are done to determine the best performing architectures for these models. Comparisons are drawn between the MDN model versus standard model architecture in both case studies. The HTC predictor model achieved 90% accuracy which equates to an average error of 4.89 W m2K across all heat exchangers. The resultant time-series ACC model achieved an average error of 3.14 kPa, which translate into a model accuracy of 82%. Air-cooled condensers Deep learning Mixture density networks Recurrent neural networks
130	Étude paramétrique du procédé de dessalement de l’eau de mer par congélation sur paroi froide / Parametric study of sea water desalination process by indirect freezing Mandri, Youssef 13 December 2011 (has links) Une étude expérimentale sur la faisabilité du procédé de dessalement par congélation sur les parois d'un tube cylindrique est présentée. Le procédé se décompose en deux étapes essentielles : la cristallisation suivie par le ressuage. Les cristallisations sont conduites à partir d'une solution stagnante ou agitée par un bullage d'air. Les paramètres opératoires clés sont la rampe de refroidissement et la salinité de l’eau traitée. Leur effet sur la salinité de la glace produite a été quantifié, dans les deux modes de fonctionnement, statique et agité. Le dispositif expérimental permet également de contrôler le gradient thermique à travers la couche de solution pour les cristallisations effectuées en statique. L'absence de gradient thermique et donc de courant de convection mène à des couches de glace très contaminées en sels. Les résultats combinant la cristallisation et le ressuage montrent que dans tous les cas, on peut obtenir de l'eau potable mais avec un rendement plus élevé et une durée réduite si la cristallisation a lieu en mode dynamique. Les conditions opératoires optimales sont proposées. La modélisation des transferts de matière et de chaleur à travers les couches de glace et de solution en régime diffusionnel et convectif a permis d’interpréter l’influence des paramètres opératoires des cristallisations opérées sans agitation. Enfin, l’évaluation économique du procédé complet de dessalement, basées sur des points de fonctionnement expérimentaux, indique que la consommation énergétique d’une petite installation pourrait être très faible en utilisant une machine frigorifique idéale fonctionnant entre l’unité de ressuage et l’unité de congélation. / An experimental study on the feasibility of sea water desalination by indirect freezing is presented. The whole process of desalination involves a freezing step, followed by a purification of the ice layer by sweating. Crystallization is led from quiescent solution or from agitated solution by air bubbling. The key operating parameters are the cooling rate, and solution salinity. Their effect on ice purity has been quantified in the static and agitated modes. The experimental setup enables as well the control of temperature gradient through the solution when the freezing step is conducted in the static mode. In the absence of temperature gradient and consequently the absence of convection currents, the ice layers formed are very contaminated in salts. The results combining crystallization and sweating show that in all cases, we can obtain drinking water, but with high yield and reduced process time when the crystallization is led in agitated mode. The optimal operating conditions are presented. The modelling of mass and heat transfers in the two phases in the diffusional and convective regimes has enabled the interpretation of the influence of operating parameters of crystallizations operated without agitation. At last, the economic evaluation of the whole desalination process, based on experimental operating points, indicates that energetic consumption of a small scale unit maybe low when using an ideal refrigerating machine which works between the sweating and the crystallization unities. Dessalement Congélation Cristallisation sur paroi froide Ressuage Plan d’expérience Convection naturelle Simulation Calcul énergétique Desalination Freezing Crystallization cold wall Sweating Design of experiments Natural convection Simulation Energy calculation 663

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