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Simulação numérica do campo de tensões na microestrutura do aço ferramenta AISI H13 durante o forjamento a quente. / Numerical simulation of the stress field in the AISI H13 steel microstructure during hot forging.Seriacopi, Vanessa 28 March 2013 (has links)
A falha devido à ocorrência de fadiga térmica de materiais utilizados como ferramentas para trabalho a quente é identificada durante serviço e ocorre devido ao acúmulo de dano localizado. O aço AISI H13 é comumente utilizado em ferramentas para a conformação a quente devido à sua boa tenacidade à fratura e resistência ao desgaste, e considerável resistência à perda de dureza a quente. Este trabalho teve como motivação estudar a relação entre a microestrutura do aço H13 e os carregamentos térmicos e mecânicos, que possam levar à falha de ferramentas para forjamento a quente. Para este estudo, fez-se uso de meios computacionais (simulação numérica) aliados aos conhecimentos de caracterização microestrutural e do comportamento mecânico dos materiais. Nesta abordagem, elabora-se uma malha na microestrutura do referido aço no software OOF2®, do NIST, e as análises são feitas a partir da aplicação do método dos elementos finitos com o emprego do software Abaqus®. Com isso, torna-se possível examinar o efeito de aspectos microestruturais, como a influência dos precipitados, na ocorrência de tensões e de deformações na microestrutura de forma a obter um mapeamento de regiões críticas ao dano e à falha na ferramenta de forjar a quente. Os estudos são baseados e comparados com trabalhos já publicados, e simulam carregamentos e variações de temperatura no material em questão de modo a verificar as condições que favorecem a nucleação de trincas por fadiga térmica. Como principais conclusões e contribuições obtidas da análise realizada, podem ser destacadas: (i-) as regiões críticas que vêm a propiciar a nucleação de trincas térmicas são os precipitados e as interfaces; (ii-) no campo de tensões, a propriedade das fases que exerce a maior influência é o módulo de elasticidade; (iii-) os diferentes coeficientes de expansão térmica das fases geram deformações térmicas mais elevadas e tensões compressivas nas interfaces; (iv-) as deformações térmicas nos precipitados são superiores às da matriz devido à influência no campo de tensões; (v-) em termos de tensões térmicas, o momento do ciclo térmico mais crítico para a matriz é o resfriamento; e (vi-) ao passo que, nos precipitados, a etapa mais crítica é o aquecimento. / Failure due to thermal fatigue can occur in hot working tool materials and its onset takes place in the regions where the highest stress and strain are reached. AISI H13 steel is often used as a hot working tool since it has good toughness and wear resistance, and also a sensible resistance to loss of hot hardness. This study was carried out by means of finite element method (FEM) combined with microstructural characterization and mechanical behavior of materials analysis. According to this approach, H13 steel microstructure, in which carbides could be observed, was meshed by means of OOF2® (NIST). Moreover, the ABAQUS® commercial FEM software was used to simulate thermal and mechanical loading applied in the tool throughout mechanical processing. The conducted analysis allowed to observe the effect of precipitates on stress-strain distribution at different temperatures and loads. Hence, critical regions, in which damage could be favored as well failure onset in the microstructure of the hot forging tool, are displayed. The investigation was based on and compared to literature results and it showed that it can be possible to design the microstructure of hot forging materials, in which an improvement in the thermal fatigue resistance could be improved. The main remarks and conclusions of this work are as follows: (i-) precipitates and interfaces are preferential regions to nucleation and growth of cracks, and they seem to work as stress concentrators; (ii-) modulus of elasticity of phases has the strongest influence in the stress fields of the microstructure; (iii-) the mismatch between thermal expansion coefficients of the phases leads to compressive stresses on interfaces and also the highest thermal strain; (iv-) thermal strains are higher on the precipitates than on the steel matrix; (v-) elastic-plastic properties of steel matrix influenced on thermal cycles. In addition, cooling is the most critical condition of thermal stresses by analyzing each thermal cycle in this phase; and (vi-) whereas the precipitates have elastic behavior, and the most critical step is the heating, in which the maximum temperature of the cycle is reached.
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Estudo numérico do comportamento de emendas de barras por meio de laço em juntas de estruturas de concreto armado / Numerical study of bars overlappings behaviour by loop in joints of reinforced concrete structuresVasconcelos, Thiago Delfino Lima 09 March 2017 (has links)
O surgimento de juntas é inevitável em certas construções em concreto armado e para garantir que a estrutura trabalhe de forma monolítica, deve-se proporcionar uma adequada transferência de esforços entre os elementos, para isso, faz-se necessário dispor de uma emenda adequada entre os elementos. Emendas com barras retas ocupam muito espaço devido ao comprimento de traspasse necessário, dessa forma, em situações em que há uma limitação de espaço para a emenda, uma armação que constitui uma boa solução é a emenda por meio de laço, que, apesar de ter poucos estudos relacionados, vem sendo bastante difundida na construção civil. O objetivo desse trabalho é estudar o comportamento de emendas em laço em juntas de estruturas de concreto armado submetidas à tração. Para isso, realizam-se simulações numéricas no software DIANA® em modelos numéricos 3D. Inicialmente, fez-se a calibração do modelo numérico com base em ensaios experimentais da literatura, depois foi realizada uma análise paramétrica variando parâmetros geométricos das peças e da armação em laço. Os resultados mostraram que traspasses menores que o diâmetro de dobra dos laços e espaçamentos maiores que 100 mm se mostram insuficientes para a formação de bielas de compressão entre laços. Dessa forma, ao se utilizar emendas em laço em juntas de concreto armado, recomenda-se dispor as barras o mais próximo possível até um espaçamento máximo de 60 mm entre eixos, como também um traspasse mínimo igual ao diâmetro de dobra dos laços. / The appearance of joints is inevitable in certain constructions of reinforced concrete and aiming to guarantee that the structure works monolithically, it is important to provide an appropriate transfer of stresses between elements, for that, it is necessary using a proper overlapping between them. Straight bars overlappings take up too much space due to the required overlapping length, therefore, in limited space situations, a reinforcement that represents a good solution is the loop joint, which has spread a lot in civil construction, although there are very few studies about it. The aim of the present work is to study the loop joint behaviour in reinforced concrete structures under tension. In order to do so, numerical simulations with numerical 3D models are made using the software DIANA®. Initially, it was made the calibration of the numerical model based on experimental tests of the literature, after that, parametric analyses were performed, varying geometric parameters of the elements and of the loop reinforcement. The results showed that overlapping lengths smaller than the loop diameter and distances between loops axes greater than 100 mm are not sufficient for the development of compression struts between loops. Thus, when the loop joint in reinforced concrete structures is used, it is recommended that the bars are placed as near as possible until a distance between the loops axes of 60 mm and a minimum overlapping length equal to the loop diameter of the reinforcement.
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Aérodynamique instationnaire pour l'analyse de la tenue à la mer des éoliennes flottantes / Unsteady aerodynamic modelling for seakeeping analysis of Floating Offshore Wind TurbinesLeroy, Vincent 06 December 2018 (has links)
La simulation numérique des éoliennes flottantes est essentielle pour le développement des Energies Marines Renouvelables. Les outils de simulation classiquement utilisés supposent un écoulement stationnaire sur les rotors. Ces théories sont généralement assez précises pour calculer les forces aérodynamiques et dimensionner les éoliennes fixes (à terre ou en mer) mais les mouvements de la plateforme d’une éolienne flottante peuvent induire des effets instationnaires conséquents. Ceux-ci peuvent par exemple impacter la force de poussée sur le rotor. Cette thèse de doctorat cherche à comprendre et à quantifier les effets de l’aérodynamique instationnaire sur la tenue à la mer des éoliennes flottantes, dans différentes conditions de fonctionnement. L’étude montre que les forces aérodynamiques instationnaires impactent les mouvements de la plateforme lorsque le rotor est fortement chargé. Les modèles quasi-stationnaires arrivent néanmoins à capturer la dynamique des éoliennes flottantes avec une précision suffisante pour des phases de design amont. Les éoliennes flottantes à axe vertical sont elles aussi étudiées pour des projets offshore puisqu’elles pourraient nécessiter des coûts d’infrastructure réduits. Après avoir étudié l’influence de l’aérodynamique instationnaire sur la tenue à la mer de ces éoliennes, une comparaison est menée entre éoliennes flottantes à axe horizontal et à axe vertical. Cette dernière subit une importante poussée aérodynamique par vents forts, induisant de très grands déplacements et chargements. / Accurate numerical simulation of thesea keeping of Floating Wind turbines (FWTs) is essential for the development of Marine Renewable Energy. State-of-the-art simulation tools assume a steady flow on the rotor. The accuracy of such models has been proven for bottom-fixed turbines, but has not been demonstrated yet for FWTs with substantial platform motions. This PhD thesis focuses on the impact of unsteady aerodynamics on the seakeeping of FWTs. This study is done by comparing quasi-steady to fully unsteady models with a coupled hydro-aerodynamic simulation tool. It shows that unsteady load shave a substantial effect on the platform motion when the rotor is highly loaded. The choice of a numerical model for example induces differences in tower base bending moments. The study also shows that state of the art quasi-steady aerodynamic models can show rather good accuracy when studying the global motion of the FWTs. Vertical Axis Wind Turbines (VAWTs) could lower infrastructure costs and are hence studied today for offshore wind projects. Unsteady aerodynamics for floating VAWT sand its effects on the sea keeping modelling have been studied during the PhD thesis,leading to similar conclusions than for traditional floating Horizontal Axis Wind Turbines (HAWTs). Those turbines have been compared to HAWTs. The study concludes that, without blade pitch control strategy, VAWTs suffer from very high wind thrust at over-rated wind speeds, leading to excessive displacements and loads. More developments are hence needed to improve the performance of such floating systems.
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A Two-Dimensional Numerical Simulation of Plasma Wake Structure Around a CubeSatMitharwal, Rajendra 01 August 2011 (has links)
A numerical model was developed to understand the time evolution of a wake structure around a CubeSat moving in a plasma with transonic speed. A cubeSat operates in the F2 layer of ionosphere with an altitude of 300 − 600 Km. The average plasma density varies between 10−6cm−3 − 10−9cm−3 and the temperature of ions and electrons is found between 0.1−0.2 eV. The study of a wake structure can provide insights for its effects on the measurements obtained from space instruments. The CubeSat is modeled to have a metal surface, which is a realistic assumption, with a negative electric potential. To solve the equations of plasma, the numerical difference equations were obtained by discretizing the fluid equations of the plasma along with nonlinear Poisson’s equation. The electrons were assumed to follow the Boltzmann’s relation and the dynamics of ions was followed using the fluid equations. The initial and boundary conditions for the evolution of the structure are discussed. The computation was compared to the analytical solution for a 1D problem before being applied to the 2D model. There was a good agreement between the numerical and analytical solution. In the 2D simulation, we observe the formation of plasma wake structure around the CubeSat. The plasma wake structure consists of rarefaction region where ion density and ion velocity decreases compared to the initial density and velocity.
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Analysis of Fluid Circulation in a Spherical Cryogenic Storage Tank and Conjugate Heat Transfer in a Circular MicrotubeRao, P Sharath Chandra 08 July 2004 (has links)
The study considered development of a finite-element numerical simulation model for the analysis of fluid flow and conjugate heat transfer in a zero boil-off (ZBO) cryogenic storage system. A spherical tank was considered for the investigation. The tank wall is made of aluminum and a multi-layered blanket of cryogenic insulation (MLI) has been attached on the top of the aluminum. The tank is connected to a cryocooler to dissipate the heat leak through the insulation and tank wall into the fluid within the tank. The cryocooler has not been modeled; only the flow in and out of the tank to the cryocooler system has been included. The primary emphasis of this research has been the fluid circulation within the tank for different fluid distribution scenario and for different level of gravity to simulate all the potential earth and space based applications. The steady-state velocity, temperature, and pressure distributions were calculated for different inlet positions, inlet velocities, and for different gravity values. The simulations were carried out for constant heat flux and constant wall temperature cases. It was observed that a good flow circulation could be obtained when the cold entering fluid was made to flow in radial direction and the inlet opening was placed close to the tank wall.
The transient and steady state heat transfer for laminar flow inside a circular microtube within a rectangular substrate during start up of power has also been investigated. Silicon, Silicon Carbide and Stainless Steel were the substrates used and Water and FC-72 were the coolants employed. Equations governing the conservation of mass, momentum, and energy were solved in the fluid region. Within the solid wafer, the heat conduction was solved. The Reynolds number, Prandtl number, thermal conductivity ratio, and diameter ranges were: 1000--1900, 6.78--12.68, 27--2658, and 300 µ m--1000 µ m respectively. It was found that a higher aspect ratio or larger diameter tube and higher thermal conductivity ratio combination of substrate and coolant requires lesser amount of time to attain steady state. It was seen that enlarging the tube from 300 µ m to 1000 µ m results in lowering of the fluid mean temperature at the exit. Nusselt number decreased with time and finally reached the steady state condition. It was also found that a higher Prandtl number fluid attains higher maximum substrate temperature and Nusselt number. A correlation for peripheral average Nusselt number was developed by curve-fitting the computed results with an average error of 6.5%. This correlation will be very useful for the design of circular microtube heat exchangers.
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Etude expérimentale et numérique de la résistance à l'effondrement progressif de sous-assemblages poteaux-poutres en béton armé / Experimental and numerical investigation of the progressive collapse resistance of reinforced concrete beam-column sub-assemblagesZhao, Guoqiang 03 July 2019 (has links)
Au cours de leur durée de vie, les bâtiments importants sont susceptibles d’être soumis à des charges accidentelles, telles que des explosions ou des impacts. Evaluer leur stabilité vis-à-vis de charges traditionnelles statiques et sismiques ne suffit pas. Leurs performances structurelles liées à des scénarios d’effondrement progressif doivent également être examinées.L’étude de l’effondrement progressif est un problème dynamique. Malheureusement, les expériences sur le comportement des structures de génie civil dans des conditions dynamiques sont rares car difficiles à réaliser. Dans cette étude, des sous-assemblages poteaux-poutres en béton armé ont été testés sous chargement dynamique. Le chargement a consisté à placer une masse importante jouant le rôle de « charge morte » sur la colonne centrale d’un sous-assemblage simulant la liaison de 3 poteaux avec 2 poutres. Une pièce fusible jouant le rôle de support sous la colonne centrale est brutalement déverrouillée pour simuler la perte de portance soudaine de cette colonne. Le comportement dynamique et les dommages locaux causés à la structure ont été mesurés et étudiés. Le bâti de chargement et les dispositifs de support ont été conçus spécialement pour cet essai. La charge morte supérieure peut être modifiée et appliquées à différents spécimens. Les supports des colonnes latérales ont une rigidité horizontale contrôlée et sont conçus pour limiter la rotation de ces mêmes colonnes. Ainsi, les conditions aux limites des essais réalisés sont supposées être représentatives de situations réalistes. Au cours des essais, un laser a été installé sous la colonne centrale pour mesurer la vitesse de chute. Une caméra numérique rapide a été utilisée pour visualiser l'ensemble du processus de ruine du sous-assemblage. Les images obtenues de la caméra ont été traitées par une technique de DIC (Digital Image Correlation) afin d’obtenir le champs de déplacement et les déformations correspondantes. Grâce à ces mesures dynamiques, des données importantes ont été produites et enregistrées, notamment la période de vibration, la fréquence, la vitesse et le déplacement des différents échantillons testés. Sur la base de ces données expérimentales, l’effet de la section et de la portée des poutres sur la réponse dynamique et sur le mode d’endommagement des sous-assemblages a été discuté. Cette étude montre que les résultats expérimentaux obtenus, en termes de mécanismes structurels, de schéma de fissuration, de mode d'endommagement, peuvent être utilisés pour analyser le comportement de sous-assemblages de structures réelles.De plus, une modélisation numérique des essais a été réalisée pour simuler le processus de ruine de la structure. Une technique appelée «connecteur» a été proposée dans le modèle aux éléments finis du sous-assemblage poteaux-poutres. Cette technique consiste à ajouter une série de ressorts pour étudier le rôle de l’interaction entre les armatures en acier et le béton. Un modèle d'endommagement anisotrope, appelé modèle DFH-KST, a été utilisé pour caractériser l'évolution de la fissuration et l’endommagement du béton.La polyvalence de la méthodologie adoptée permet d’évaluer l’influence du comportement non-linéaire du matériau et celle de la géométrie de la structure testée. Les études numériques de calibration et de validation montrent que le modèle proposé peut reproduire le comportement et la résistance de la structure avec succès. / Important buildings may be subjected to accidental loads, such as explosions or impacts, during their service life. It is, therefore, necessary not only to evaluate their safety under traditional loads and seismic action. The structural performances related to progressive collapse scenarios need to be investigated.The study of progressive collapse involves a dynamic problem, but unfortunately dynamic experiments on the behavior of the civil engineering structures under dynamic conditions are rare. In this research, beam-column sub-assemblage specimens were tested under dynamic load. The loading program consists in placing a large mass, as a dead load, on the top of the middle column of a beam-column sub-assemblage. The support under the middle column is suddenly removed for simulating the sudden loss of a column and the damage that will result in the structure. The loading system and supporting devices were designed specially for this test. The upper dead load can be changed by increasing or decreasing the applied masse to different specimens. The supports for the side column have a controlled rigidity in the horizontal direction and are designed to restrain rotation of the side-column. Thus, the boundary conditions are supposed to be similar to real situations. During the test, a laser was installed under the middle pillar to collect the falling velocity and a high-speed camera was used to visualize the whole process of the component failure process. The images obtained from the camera were processed by Digital Image Correlation (DIC) technology to get the corresponding displacements and strain fields. By these means, all the information of the structure under dynamic loading was captured and recorded, such as the period of vibration, frequency, velocity and displacement. Based on these experimental data, the effect of section and span of the specimen on dynamic response and damage mode was discussed. Time history of resistance force curves was produced. Compared with previous published quasi-static experiments in terms of structural mechanisms, crack patterns, damage mode, it shows the experimental results from beam-column assemblage with the designed support device can be used to analyze the behavior of the local structure in the entire frame.In addition, numerical simulations were developed for simulating the failing process of the structure. A technique named “connector” was proposed into beam-column finite element model by adding a series of springs to investigate the interaction between steel rebars and concrete. A concrete damage model, named DFH-KST model, was used to characterize the development of concrete crack and damage. The versatility of the adopted methodology allows assessing the influence of the material nonlinear behavior and the geometry of the tested structure. Calibration and validation studies show that the proposed model can successfully represent the resistance of structure and behavior. Furthermore, the transverse component effect on the resistance to progressive collapse was discussed.
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DNS and LES of Scalar Transfer Across an Air-water Interface during Inception and Growth of Langmuir CirculationHafsi, Amine 17 November 2017 (has links)
Direct numerical simulations (DNS) of an initially quiescent coupled air-water interface driven by an air flow with free stream speed of 5 m/s have been conducted. The DNS solves a scalar advection-diffusion equation for dissolved gas (or scalar) concentration in order to determine the impact of the water-side turbulence on scalar (mass) transfer from the air side to the water side and subsequent vertical transport in the water column. Two simulations are compared: one with a freely deforming interface and a second one with a flat interface. In the first simulation, the deforming interface evolves in the form of gravity-capillary waves generating aqueous Langmuir turbulence characterized by small-scale (centimeter-scale) Langmuir cells (LCs). The second simulation is characterized by pure shear-driven turbulence in the absence of LCs as the interface is intentionally held flat. It is concluded that the Langmuir turbulence serves to enhance vertical transport of the scalar in the water side and in the process increases scalar transfer efficiency relative to the shear-dominated turbulence in the flat interface case. Furthermore, transition to Langmuir turbulence was observed to be accompanied by a spike in scalar flux via molecular diffusion across the interface characterized by an order of magnitude increase. Such episodic flux increases, if linked to gusts and overall unsteadiness in the wind field, are expected to be an important contributor in determining the long-term average of the air-sea gas fluxes. The effectiveness of popular transfer velocity models, namely the small eddy model and the surface divergence model, in predicting this spike is evaluated via the DNS. In addition to LCs, DNS reveals that the water side turbulence is characterized by smaller, shear-driven turbulent eddies at the surface embedded within the LCs. LES with momentum equation augmented with the well-known Craik-Leibovich (C-L) vortex force is used to understand the roles of the wave and shear-driven LCs (i.e. the Langmuir turbulence) and the smaller shear-driven eddies (i.e. the shear turbulence) in determining molecular diffusive scalar flux from the air side to the water side and vertical scalar transport beneath. The C-L force consists of the cross product between the Stokes drift velocity (induced by the interfacial waves) and the flow vorticity. It is observed that Stokes drift shear intensifies the smaller eddies (with respect to purely wind-driven flow, i.e. without wave effects) leading to enhanced diffusive scalar flux at the air-water interface. LC leads to increased vertical scalar transport at depths below the interface and thus greater scalar transfer efficiency.
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Large-eddy Simulation of the Inner Continental Shelf Under the Combined Effects of Surface Temperature Fluxes, Tidal Currents and Langmuir CirculationWalker, Rachel 07 April 2015 (has links)
In a shallow shelf region, turbulent motion can have a major effect on coastal processes including ecosystem functioning, surface gas exchange and sediment resuspension. Many factors contribute to such turbulence; wind and wave forcing, buoyancy induced by surface heat fluxes and tidal forcing all play a key role in generating vertical mixing in this shallow region. Alongside these independent sources of turbulence, combinations thereof can lead to full-depth turbulent structures acting secondary to the mean flow and leading to enhanced vertical mixing throughout the entire water column.
Field and laboratory experiments can often prove to be costly and time consuming, and reproducing or maintaining the complex flow dynamics of real world ocean flows is a constant challenge to these methods of research. As such, those interested in developing realistic and useful models of the marine environment to further understand its behavior often rely on 3-dimensional mathematical modeling and simulation. In this dissertation, simulations will be presented of turbulent flow and associated vertical mixing in a domain representative of the shallow coastal ocean, sufficiently far off shore that the land-ocean boundary does not significantly affect the flow behavior. This will be done using a large-eddy simulation (LES) method; solving the governing Navier-Stokes equations over a finite grid designed to capture the large, energy containing turbulent scales, and modeling the smaller, sub-grid scales.
The simulations to be presented feature combinations of coastal forcing mechanisms which are either presently unexplored or the analysis of which has been hindered by the complexity of field measurements and the challenge of isolating independent causes of turbulent motion. This will include surface heat fluxes, tidal forcing and Langmuir (or wave) forcing, acting both in isolation and in conjunction with each other, in order to bridge existing gaps in knowledge and provide a more complete understanding of the generation of full-depth turbulent structures in this shallow coastal water column.
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Numerical modeling and simulation of chemical reaction effect on mass transfer through a fixed bed of particlesSulaiman, Mostafa 19 October 2018 (has links) (PDF)
We studied the effect of a first order irreversible chemical reaction on mass transfer for two-phase flow systems in which the continuous phase is a fluid and the dispersed phase consists in catalystspherical particles. The reactive solute is transported by the fluid flow and penetrates through the particle surface by diffusion. The chemical reaction takes place within the bulk of the particle. Wehandle the problem by coupling mass balance equations for internal-external transfer with two boundary conditions: continuity of concentration and mass flux at the particle surface. We start with the case of a single isolated sphere. We propose a model to predict mass transfer coefficient (`reactive' Sherwood number) accounting for the external convection-diffusion along with internal diffusion-reaction. We validate the model through comparison with fully resolved Direct Numerical Simulations (DNS) performed by means of a boundary-fitted mesh method. For the simulation of multi-particle systems, we implemented a Sharp Interface Method to handle strong concentration gradients. We validate the implementation of the method thoroughly thanks to comparison with existing analytical solutions in case of diffusion, diffusion-reaction and by comparison with previously established correlations for convection-diffusion mass transfer. In case of convectiondiffusion- reaction, we validate the method and we evaluate its accuracy through comparisons with single particle simulations based on the boundary-fitted method. Later, we study the problem of three aligned-interacting spheres with internal chemical reaction. We propose a `reactive' Sherwood number model based on a known non-reactive prediction of mass transfer for each sphere. We validate the model by comparison with direct numerical simulations for a wide range of dimensionless parameters. Then, we study the configuration of a fixed bed of catalyst particles. We model the cup-mixing concentration profile, accounting for chemical reaction within the bed, and the mean surface and volume concentration profiles of the particles. We introduce a model for `reactive' Sherwood number that accounts for the solid volume fraction, in addition to the aforementioned effects. We compare the model to numerical simulations to evaluate its limitations
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[en] DESIGN, NUMERICAL SIMULATION AND EXPERIMENTAL EVALUATION OF AN INERTIAL IMPACTOR USED TO COLLECT ATMOSPHERIC AEROSOLS / [pt] PROJETO, SIMULAÇÃO NUMÉRICA E TESTE EXPERIMENTAL DE UM IMPACTADOR INERCIAL EM CASCATA PARA AMOSTRAGEM DE AEROSSÓIS ATMOSFÉRICOSCLAUDIA MARCIA FERREIRA COSTA 14 March 2006 (has links)
[pt] O impactador inercial em cascata é um instrumento no
qual
uma amostra
de ar e poluentes (aerossóis) é obrigada a percorrer um
trecho contendo
obstáculos, chamados placas de impactação. Os obstáculos
forçam o jato a
mudar de direção, mas como as partículas têm maior
inércia
do que o fluido, não
acompanham as linhas de corrente do escoamento e acabam
por depositar-se
sobre estes obstáculos. Diferenças na geometria
envolvendo
diminuição de área
de passagem de escoamento e conseqüente aumento de
velocidades, fazem
com que, a cada estágio, partículas de diâmetros menores
sejam coletadas. O
desafio é projetar um instrumento que maximize a
eficiência de coleta,
diminuindo as perdas por deposição indesejável de
partículas nas paredes,
recirculações e outros efeitos. Nesta Dissertação de
Mestrado foi realizado o
projeto de um impactador de três estágios coletando,
respectivamente, partículas
com diâmetro aerodinâmico de 10, 2,5 e 1 (mi)m, operando
com
vazão de 30 lpm
(litros por minuto) e pressão atmosférica. Na análise de
desempenho do
instrumento, foram realizadas simulações numéricas com o
objetivo de analisar
características do escoamento e da trajetória de
partículas e levantar as curvas
de eficiência de coleta. Foram realizados, também,
testes
experimentais
reproduzindo condições de uso com o intuito de levantar
as
curvas de eficiência
reais. Os resultados numéricos e experimentais foram
comparados e
apresentam-se ao final, conclusões sobre o desempenho do
instrumento e
recomendações para trabalhos futuros. / [en] Impactors are simple devices in which a sample flows of
air and pollutants
flow around an obstacle, called impaction plate. Particles
with sufficient inertia will
slip across the flow streamlines and impact on the
obstacle. Particles with less
inertia will follow the airflow away from the impaction
surface. Inertial cascade
impactors have more than one impaction area. Each one has
an impaction plate
and a nozzle plate. From one stage to the other, the
nozzle diameters become
smaller and, consequently, the velocities are higher. This
allows for the collection
of smaller particles. The challenge is to design an
instrument with the higher
collection efficiency as possible, reducing wall losses,
recirculation regions and
other effects. In this study a 3-stages inertial cascade
impactor was designed and
tested. The cut-point aerodynamic diameters for each stage
were 10, 2.5 and 1
(mi)m, respectively, when operating with a flow rate of 30
l/min at atmospheric
pressure. To evaluate the instrument, some numerical
simulations were
performed. They provided results for the flow field,
particle trajectories and the
collection efficiency curves. Experimental tests were also
done to allow for the
determination of the real efficiency curves. The numerical
and experimental data
were compared. Finally, the conclusions of the work and
recommendations for
future studies are presented.
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