Phase fraction distribution measurement of oil-water flow using a capacitance wire-mesh sensor

In this paper, a novel wire-mesh sensor based on permittivity (capacitance) measurements is applied to generate images of the phase fraction distribution and investigate the flow of viscous oil and water in a horizontal pipe. Phase fraction values were calculated from the raw data delivered by the wire-mesh sensor using different mixture permittivity models. Furthermore, these data were validated against quick-closing valve measurements. Investigated flow patterns were dispersion of oil in water (Do/w) and dispersion of oil in water and water in oil (Do/w&w/o). The Maxwell-Garnett mixing model is better suited for Dw/o and the logarithmic model for Do/w&w/o flow pattern. Images of the time-averaged cross-sectional oil fraction distribution along with axial slice images were used to visualize and disclose some details of the flow.

Hybrid modeling of convective laminar flow in a permeable tube associated with the cross-flow process

The confined flows in tubes with permeable surfaces arc associated to tangential filtration processes (microfiltration or ultrafiltration). The complexity of the phenomena do not allow for the development of exact analytical solutions, however, approximate solutions are of great interest for the calculation of the transmembrane outflow and estimate of the concentration, polarization phenomenon. In the present work, the generalized integral transform technique (GITT) was employed in solving the laminar and permanent flow in permeable tubes of Newtonian and incompressible fluid. The mathematical formulation employed the parabolic differential equation of chemical species conservation (convective-diffusive equation). The velocity profiles for the entrance region flow, which are found in the connective terms of the equation, were assessed by solutions obtained from literature. The velocity at the permeable wall was considered uniform, with the concentration at the tube wall regarded as variable with an axial position. A computational methodology using global error control was applied to determine the concentration in the wall and concentration boundary layer thickness. The results obtained for the local transmembrane flux and the concentration boundary layer thickness were compared against others in literature. (C) 2007 Elsevier B.V. All rights reserved.

Magnetic suspension of the rotor of a ventricular assist device of mixed flow type

This work presents results of preliminary studies concerning application of magnetic bearing in a ventricular assist device (VAD) being developed by Dante Pazzanese Institute of Cardiology-IDPC (Sao Paulo, Brazil). The VAD-IDPC has a novel architecture that distinguishes from other known VADs. In this, the rotor has a conical geometry with spiral impellers, showing characteristics that are intermediate between a centrifugal VAD and an axial VAD. The effectiveness of this new type of blood pumping principle was showed by tests and by using it in heart surgery for external blood circulation. However, the developed VAD uses a combination of ball bearings and mechanical seals, limiting the life for some 10 h, making impossible its long-term use or its use as an implantable VAD. As a part of development of an implantable VAD, this work aims at the replacement of ball bearings by a magnetic bearing. The most important magnetic bearing principles are studied and the magnetic bearing developed by Escola Politecnica of Sao Paulo University (EPUSP-MB) is elected because of its very simple architecture. Besides presenting the principle of the EPUSP-MB, this work presents one possible alternative for applying the EPUSP-MB in the IDPC-VAD.

Evaluation of flow regimes in a semi-cylindrical spouted bed through statistical, mutual information, spectral and Hurst`s analysis

Hydrodynamic studies were conducted in a semi-cylindrical spouted bed column of diameter 150 mm, height 1000 mm, conical base included angle of 60 degrees and inlet orifice diameter 25 mm. Pressure transducers at several axial positions were used to obtain pressure fluctuation time series with 1.2 and 2.4 mm glass beads at U/U-ms from 0.3 to 1.6, and static bed depths from 150 to 600 mm. The conditions covered several flow regimes (fixed bed, incipient spouting, stable spouting, pulsating spouting, slugging, bubble spouting and fluidization). Images of the system dynamics were also acquired through the transparent walls with a digital camera. The data were analyzed via statistical, mutual information theory, spectral and Hurst`s Rescaled Range methods to assess the potential of these methods to characterize the spouting quality. The results indicate that these methods have potential for monitoring spouted bed operation.

Moderately strong vorticity in a bathtub-type flow

Theoretical and numerical analysis is performed for an inviscid axisymmetric vortical bathtub-type flow. The level of vorticity is kept high so that the image of the flow on the radial-axial plane (r-z plane) is not potential. The most significant findings are: (1) the region of validity of the strong vortex approximation is separated from the drain by a buffer region, (2) the power-law asymptote of the stream function, specified by Delta Psi similar to r(4/3) Deltaz, appears near the axis when vorticity in the flow is sufficiently strong and (3) the local Rossby number in the region of the 4/3 power-law the initial vorticity level in the flow and the global Rossby number.

On the effect of tracer density on axial dispersion in a batch oscillatory baffled column

In this paper, we report our modelling evaluation on the effect of tracer density on axial dispersion in a batch oscillatory baffled column (OBC). Tracer solution of potassium nitrite, its specific density ranged from 1.0 to 1.5, was used in the study, and was injected to the vertical column from either the top or bottom. Local concentration profiles are measured using conductivity probes at two locations along the height of the column. Using the experimental measured concentration profiles together with both 'Tank-in-Series' and 'Plug Flow with Axial Dispersion' models, axial dispersion coefficients were determined and used to describe the effect of specific tracer density on mixing in the OBC. The results showed that the axial dispersion coefficients evaluated by the two models are very similar in both magnitudes and trends, and the range of variations in such coefficients is generally larger for the bottom injection than for the top one. Empirical correlations linking the mechanical energy for mixing, the specific density of tracer and axial dispersion coefficient were established. Using these correlations, we identified the enhancements of up to 269% on axial dispersion for various specific tracer densities. (C) 2002 Elsevier Science B.V. All rights reserved.

Wells turbine: fiberglass flanges

A introdução desta tese começa por realizar um enquadramento do projecto em mão, apresentando a central de energia das ondas em que se encontram os componentes em fibra de vidro a projectar. Esta central usa o princípio de variação de coluna de água, e encontra-se localizada na ilha do Pico, Açores. São de seguida apresentados os objectivos deste trabalho, que consistem na selecção de materiais de fabrico dos componentes, desenvolvimento de uma metodologia para projectar juntas aparafusadas em materiais compósitos, dimensionamento e comparação de duas juntas concorrentes em materiais compósitos: junta solicitada à tracção e junta solicitada ao corte, validação da análise e estudo das causas dos vários tipos de falha destas juntas. A parte I deste trabalho é o resultado da pesquisa bibliográfica efectuada para levar a cabo os objectivos definidos. Assim, começa por se fazer uma descrição dos materiais e processos de fabrico que mais se adequam ao presente projecto, nomeadamente fibra de vidro, resinas, tecidos, impregnação manual, RTM e infusão por vácuo. Daqui resultou que os materiais mais adequados para esta aplicação são fibra de vidro do tipo E e resina polyester devido ao seu baixo custo e larga utilização em aplicações estruturais marinhas. O processo de fabrico mais eficiente é a infusão por vácuo devido á sua vocação para pequenas séries de produção, a poupança que permite em termos de mão-de-obra, a complacência com normas de emissão de voláteis e as boas propriedades das partes produzidas. No capítulo II da parte I são discutidos os tópicos relacionados com juntas em materiais compósitos. Da pesquisa levada a cabo conclui-se que as grandes vantagens das juntas aparafusadas são a sua facilidade de montagem e desmontagem, facilidade de inspecção e capacidade de ligar quaisquer tipos de materiais. Quanto à furação de compósitos é importante referir a necessidade de utilizar ferramentas resistentes e parâmetros de maquinação que minimizem o dano infligido aos laminados. Isto é possível através da selecção de ferramentas com passos baixos que reduzam igualmente a dimensão do seu centro estático responsável pela força axial exercida sobre o laminado - principal factor causador de dano. Devem-se igualmente utilizar baixas velocidades de avanço e elevadas velocidades de rotação. É importante salientar a importância da realização de pré-furação, de utilização de um prato de suporte na superfície de saída do laminado e a existência de ferramentas especialmente concebidas para a furação de compósitos. Para detectar e quantificar o dano existente num furo destacam-se os métodos de inspecção ultrasónica e a radiografia. Quanto aos parâmetros que influenciaram o comportamento de juntas aparafusadas destacam-se os rácios largura/diâmetro, distância ao bordo/diâmetro, espessura/diâmetro, pré-tensão, fricção, sequência de empilhamento e respectivas proporções, dimensão das anilhas e folga entre o parafuso e o furo. A pesquisa efectuada visando metodologias de projecto fiáveis ditou a necessidade de utilizar métodos que permitiram determinar o parafuso mais carregado de uma junta, efectuar o cálculo de tensões no mesmo, e ainda métodos que permitam determinar a primeira falha que ocorre no laminado bem como a falha final no mesmo. O capítulo III da primeira parte descreve os métodos de análise de tensões necessários para as metodologias de projecto utilizadas. Aqui é apresentada a teoria clássica da laminação, um método para determinação do parafuso mais carregado, um método analítico baseado na teoria da elasticidade anisotrópica de um corpo e o método dos elementos finitos. O método para determinar o parafuso mais carregado - análise global - consiste num modelo bidimensional de elementos finitos em que 2 laminados coincidentes são modelados com elementos lineares de casca com 4 nós, sendo a extremidade de um laminado restringida em todos os graus de liberdade e a extremidade oposta do segundo laminado carregada com a carga pretendida. Os laminados são ligados através de elementos mola que simulam os parafusos, sendo a sua constante de rigidez previamente calculada para este fim. O método analítico modela o contacto assumindo uma distribuição de pressão cosinoidal ao longo de metade do furo, e é válido para laminados simétricos e quasi-isotrópicos. O método dos elementos finitos é o que mais factores permite ter em conta, sendo os modelos tridimensionais com um elemento por camada os que melhor modelam o estado de tensões experienciado por uma junta aparafusada em materiais compósitos. O tópico de análise de falha é abordado no capítulo 4 da primeira parte. Aqui são apresentados os resultados do world wide failure exercice que compara vários critérios de falha existentes até 2004, fazendo-se referência a desenvolvimentos recentes que têm ocorrido nesta área. O critério de Puck surge como aquele que permite previsões de falha mais exactas. O critério de falha de Hashin 3D foi o escolhido para o presente trabalho, devido à sua facilidade de implementação num modelo de elementos finitos, à sua capacidade para detectar modos de falha subcríticos e à sua utilização em trabalhos anteriores que apresentaram previsões de falha muito próximas dos dados experimentais. Também neste capítulo se apresentaram os vários tipos de falha de uma junta aparafusada em materiais compósitos, apresentando as causas de cada uma. Por fim, na última secção, apresenta-se o método de dano progressivo que se desenvolveu para prever a primeira falha final do laminado. Este é muito interessante tendo permitido previsões de falha muito próximas dos resultados experimentais em trabalhos anteriores. Este método é iterativo e encontra-se dividido em 3 passos: Análise de tensões, análise de falha utilizando o critério de Hashin 3D e degradação de propriedades, de acordo com o tipo de falha detectada. Para além dos passos referidos, existe ainda um quarto responsável pelo fim da análise que consiste na aferição da existência ou não de falha final e respectivo tipo de falha (por pressão de contacto, por tensão ou por esforços de corte). No capítulo V da primeira parte é apresentado o resultado de uma pesquisa das normas de teste necessárias para obter as propriedades dos materiais requeridas para a aplicação dos métodos descritos neste trabalho. A parte II deste trabalho consiste na aplicação dos métodos apresentados na parte I ao caso concreto em estudo. Os softwares Microsoft Excel, Matlab e ANSYS foram utilizados para este fim. A junta começa por ser dimensionada estimando a espessura necessária do componente e o número e características dos parafusos. De seguida foi feita uma análise global à flange em estudo determinando a força suportada pelo parafuso mais carregado. Após esta análise desenvolveu-se um modelo tridimensional de elementos finitos da zona em que se encontra o parafuso mais carregado, utilizando elementos sólidos lineares e isoparamétricos de 8 nós e uma malha gerada pelo método directo. Aplicou-se a este modelo o algoritmo de dano progressivo descrito na primeira parte. Começou por se incluir explicitamente o parafuso, anilhas, pré-tensão e a modelação dos vários contactos com fricção posteriormente simplificado o modelo restringindo radialmente os nós da porção carregada do furo, excluindo os factores mencionados inicialmente. Procurou-se validar o modelo utilizando o método de cálculo de tensões descrito na primeira parte, desenvolvendo um programa em Matlab para o efeito. Tal não foi possível tendo-se incluído a tentativa realizada em anexo. Para efeitos de dimensionamento, desenvolveu-se um modelo de elementos finitos de duas dimensões da junta em causa, utilizando elementos de casca lineares de quatro nós isoparamétricos com uma espessura unitária. Através da análise de tensões efectuada com este modelo, e utilizando um método combinado programado em linguagem paramétrica, foi possível dimensionar as duas juntas concorrentes pretendidas. Este método combinado consistiu no cálculo de tensões em pontos localizados sobre uma curva característica e utilização de um critério de falha quadrático para cálculo da espessura necessária para a junta. O dimensionamento ditou que a junta solicitada à tensão necessita de pelo menos 127% das camadas e do custo de uma junta solicitada ao corte equivalente.

Analytical and numerical study of the electro-osmotic annular flow of viscoelastic fluids

In this work we present semi-analytical solutions for the electro-osmotic annular flow of viscoelastic fluids modeled by the Linear and Exponential PTT models. The viscoelastic fluid flows in the axial direction between two concentric cylinders under the combined influences of electrokinetic and pressure forcings. The analysis invokes the Debye-Hückel approximation and includes the limit case of pure electro-osmotic flow. The solution is valid for both no slip and slip velocity at the walls and the chosen slip boundary condition is the linear Navier slip velocity model. The combined effects of fluid rheology, electro-osmotic and pressure gradient forcings on the fluid velocity distribution are also discussed.

Flow and transport in electrochromatography

Analyte retention, analyte transport, axial dispersion, adsorption, charge-selectivity, concentration polarization, confocal laser scanning microscopy, donnan-exclusion, electrical double layer; electrochromatography; electrohydrodynamics, electrokinetic instability, electroosmosis; electroosmotic flow; electroosmotic mobility, electroosmotic perfusion, electrophoresis, hierarchical porous media, hydrodynamic flow, induced-charge electroosmosis, ion-permselectivity, ion-permselective transport, monolith, nonequilibrium electrical double layer, nonequilibrium electrokinetic effects, nonlinear electroosmosis, plate height, plate number, porous media, pore-scale dispersion, refractive index matching, space charge effects, sphere packing, quantitative imaging, wall effect, zeta-potential

Bi-ventricular axial micropump: impact on blood cell integrity.

BACKGROUND AND OBJECTIVE: Off-pump coronary artery bypass grafting has stimulated the development of micro-pumps designed to prevent the hemodynamic instability induced by heart luxation for the exposure of target vessels of the posterior wall. Impella (Aachen, Germany) developed micro-pumps with a miniaturized propeller system for both sides of the heart. The aim of this study was to analyze the impact of both pumps working together on blood cell integrity. MATERIALS AND METHODS: Both right and left-sided micro-pumps were implanted in 5 calves (body weight, 72_4 Kg) during 3 h. Blood samples for hematology and hemolysis parameters were drawn hourly. RESULTS: Both pumps performed well with a flow of 3.6 L +/- 0.3 L during the 3 h of the experiment with stable hemodynamic conditions. Mixed venous oxygen saturation was 63.4 +/- 15.2% at baseline and 63.8 +/- 16.3% at the end of the experiment (P = ns). Red cell count, LDH and free plasma hemoglobin were 6.7 +/- 2.1 x 10(12)/L, 1807 +/- 437 IU/L, and 32 +/- 9 mg/L at baseline vs. 6.1 +/- 2.1 x 10(12)/L, 1871 +/- 410 IU/L, and 52 +/- 9 mg/L at the end of the experiment (P = ns for all comparisons). Platelet count exhibited a non-significant drop (872 +/- 126 vs. 715 +/- 22 x 10(9)/L). CONCLUSIONS: This double pump system based on the Archimed screw principle is hematologically well tolerated under conditions of prolonged cardiac assist.

Simultaneous measurement of regional cerebral blood flow by perfusion CT and stable xenon CT: a validation study.

BACKGROUND AND PURPOSE: Knowledge of cerebral blood flow (CBF) alterations in cases of acute stroke could be valuable in the early management of these cases. Among imaging techniques affording evaluation of cerebral perfusion, perfusion CT studies involve sequential acquisition of cerebral CT sections obtained in an axial mode during the IV administration of iodinated contrast material. They are thus very easy to perform in emergency settings. Perfusion CT values of CBF have proved to be accurate in animals, and perfusion CT affords plausible values in humans. The purpose of this study was to validate perfusion CT studies of CBF by comparison with the results provided by stable xenon CT, which have been reported to be accurate, and to evaluate acquisition and processing modalities of CT data, notably the possible deconvolution methods and the selection of the reference artery. METHODS: Twelve stable xenon CT and perfusion CT cerebral examinations were performed within an interval of a few minutes in patients with various cerebrovascular diseases. CBF maps were obtained from perfusion CT data by deconvolution using singular value decomposition and least mean square methods. The CBF were compared with the stable xenon CT results in multiple regions of interest through linear regression analysis and bilateral t tests for matched variables. RESULTS: Linear regression analysis showed good correlation between perfusion CT and stable xenon CT CBF values (singular value decomposition method: R(2) = 0.79, slope = 0.87; least mean square method: R(2) = 0.67, slope = 0.83). Bilateral t tests for matched variables did not identify a significant difference between the two imaging methods (P >.1). Both deconvolution methods were equivalent (P >.1). The choice of the reference artery is a major concern and has a strong influence on the final perfusion CT CBF map. CONCLUSION: Perfusion CT studies of CBF achieved with adequate acquisition parameters and processing lead to accurate and reliable results.

Computational Analysis and Optimization of Real Gas Flow In Small Centrifugal Compressors

Small centrifugal compressors are more and more widely used in many industrialsystems because of their higher efficiency and better off-design performance comparing to piston and scroll compressors as while as higher work coefficient perstage than in axial compressors. Higher efficiency is always the aim of the designer of compressors. In the present work, the influence of four partsof a small centrifugal compressor that compresses heavy molecular weight real gas has been investigated in order to achieve higher efficiency. Two parts concern the impeller: tip clearance and the circumferential position of the splitter blade. The other two parts concern the diffuser: the pinch shape and vane shape. Computational fluid dynamics is applied in this study. The Reynolds averaged Navier-Stokes flow solver Finflo is used. The quasi-steady approach is utilized. Chien's k-e turbulence model is used to model the turbulence. A new practical real gas model is presented in this study. The real gas model is easily generated, accuracy controllable and fairly fast. The numerical results and measurements show good agreement. The influence of tip clearance on the performance of a small compressor is obvious. The pressure ratio and efficiency are decreased as the size of tip clearance is increased, while the total enthalpy rise keeps almost constant. The decrement of the pressure ratio and efficiency is larger at higher mass flow rates and smaller at lower mass flow rates. The flow angles at the inlet and outlet of the impeller are increased as the size of tip clearance is increased. The results of the detailed flow field show that leakingflow is the main reason for the performance drop. The secondary flow region becomes larger as the size of tip clearance is increased and the area of the main flow is compressed. The flow uniformity is then decreased. A detailed study shows that the leaking flow rate is higher near the exit of the impeller than that near the inlet of the impeller. Based on this phenomenon, a new partiallyshrouded impeller is used. The impeller is shrouded near the exit of the impeller. The results show that the flow field near the exit of the impeller is greatly changed by the partially shrouded impeller, and better performance is achievedthan with the unshrouded impeller. The loading distribution on the impeller blade and the flow fields in the impeller is changed by moving the splitter of the impeller in circumferential direction. Moving the splitter slightly to the suction side of the long blade can improve the performance of the compressor. The total enthalpy rise is reduced if only the leading edge of the splitter ismoved to the suction side of the long blade. The performance of the compressor is decreased if the blade is bended from the radius direction at the leading edge of the splitter. The total pressure rise and the enthalpy rise of thecompressor are increased if pinch is used at the diffuser inlet. Among the fivedifferent pinch shape configurations, at design and lower mass flow rates the efficiency of a straight line pinch is the highest, while at higher mass flow rate, the efficiency of a concave pinch is the highest. The sharp corner of the pinch is the main reason for the decrease of efficiency and should be avoided. The variation of the flow angles entering the diffuser in spanwise direction is decreased if pinch is applied. A three-dimensional low solidity twisted vaned diffuser is designed to match the flow angles entering the diffuser. The numerical results show that the pressure recovery in the twisted diffuser is higher than in a conventional low solidity vaned diffuser, which also leads to higher efficiency of the twisted diffuser. Investigation of the detailed flow fields shows that the separation at lower mass flow rate in the twisted diffuser is later than in the conventional low solidity vaned diffuser, which leads to a possible wider flow range of the twisted diffuser.

An experimental and theoretical study of multiphase flow in a circulating fluidized bed

A systematic averaging procedure has been derived in order to obtain an integral form of conservation equations for dispersed multiphase flow, especially applicable to fluidized beds. A similar averaging method is applied further to formulate macroscopic integral equations, which can be used in one-dimensional and macroscopic multi dimensional models. Circulating fluid bed hydrodynamics has been studied experimentally and both macroscopic and microscopic flow profiles have been measured in a cold model. As an application of the theory, the one dimensional model has been used to study mass and momentum conservation of gas and solid in a circulating fluid bed. Axial solid mixing has also been modelled by the one dimensional model and mixing parameters have been evaluated.

Pulsatile Blood Flow Simulations in Computed Tomography(CT) Scan-Based and Idealized Geometries of Human Aorta

Blood flow in human aorta is an unsteady and complex phenomenon. The complex patterns are related to the geometrical features like curvature, bends, and branching and pulsatile nature of flow from left ventricle of heart. The aim of this work was to understand the effect of aorta geometry on the flow dynamics. To achieve this, 3D realistic and idealized models of descending aorta were reconstructed from Computed Tomography (CT) images of a female patient. The geometries were reconstructed using medical image processing code. The blood flow in aorta was assumed to be laminar and incompressible and the blood was assumed to be Newtonian fluid. A time dependent pulsatile and parabolic boundary condition was deployed at inlet. Steady and unsteady blood flow simulations were performed in real and idealized geometries of descending aorta using a Finite Volume Method (FVM) code. Analysis of Wall Shear Stress (WSS) distribution, pressure distribution, and axial velocity profiles were carried out in both geometries at steady and unsteady state conditions. The results obtained in thesis work reveal that the idealization of geometry underestimates the values of WSS especially near the region with sudden change of diameter. However, the resultant pressure and velocity in idealized geometry are close to those in real geometry

Modeling of turbulent flow through radial diffuser

The work considers the modeling of turbulent flow in radial diffuser with axial feeding. Due to its claimed capability to predict flow including features such as separation, curvature and adverse pressure gradient, the RNG k-epsilon model of Orzag et al. (1993) is applied in the present analysis. The governing equations are numerically solved using the finite volume methodology. Experiments were conducted to assess the turbulence model. Numerical results of pressure distribution on the front disk surface for different flow conditions when compared to the experimental data indicated that the RNG k-epsilon model is adequate to predict this class of flow.