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Interface tracking using Lagrangian-Eulerian methodsSims, Paul January 1999 (has links)
No description available.
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Numerical simulations that characterize the effects of surfactant on droplets in shear flowDrumright-Clarke, Mary Ann 17 April 2002 (has links)
Numerical simulations utilizing the code SURFER++ with the incorporation of an insoluble surfactant in the VOF scheme were conducted to characterize the effects of surfactant on a drop in shear flow. The drop is suspended in a matrix liquid. A parameter called reduction, which specifically relates to a percentage decrease in effective surface tension, is used to measure the surfactant amount on the interface. In a model system where reduction = 0.1, viscosity ratio = 1 and density ratio = 1, it was found that stable drops tend to be more elongated and less inclined to the primary flow direction than drops unexposed to surfactant. This can be explained by the location of surfactant at the interface as the drop evolves. Breaking drops also show a flattened angle, but exhibit shorter necks and faster time to break than similar drops without surfactant. As reduction increases, various physical characteristics of the drops change across Reynolds number. / Ph. D.
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Estudo numérico da fabricação de células fotovoltaicas pelo método de revestimento por extrusãoGARUZZI, R. P. 08 March 2017 (has links)
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Previous issue date: 2017-03-08 / A energia solar fotovoltaica é uma opção bastante atrativa, entretanto ainda é cara se
comparada com as fontes tradicionais. Uma forma de tornar a fabricação da célula
solar fotovoltaica mais competitiva no mercado é diminuindo a quantidade de material
utilizado. A diminuição da espessura encontra limites físicos e operacionais
associados com o método de deposição. Um deles, e que é objeto de estudo neste
trabalho, é o limite de vazão mínima (low-flow limit). Este trabalho apresenta a
simulação numérica do processo de revestimento por extrusão de fluidos newtoniano,
não-newtoniano e newtoniano com partículas utilizando a técnica VOF (Volume Of
Fluid) para determinar o limite de vazão mínima deste processo. No caso de
newtoniano com partículas além do VOF é utilizada a técnica DPM (Discrete Phase
Model). O domínio de solução das equações governantes no plano bidimensional se
restringe a parte à jusante da barra de revestimento. Como resultados tem-se que o
aumento do número de capilaridade resulta em um aumento da espessura mínima, e
com o aumento da importância do comportamento não-newtoniano a espessura
mínima de filme diminui. Para as partículas tem-se uma análise da sua concentração,
com a ocorrência de um problema de alta quantidade na região do revestimento,
sendo desejado que ocorra na região de interesse do filme depositado. Os trabalhos
relacionados ao escoamento com fluido newtoniano foram publicados em duas
revistas, como mostra os APÊNDICE A e APÊNDICE B. Além disso foi realizada uma
análise econômica, também publicada, como pode ser visto no APÊNDICE C, e os
detalhes constam no APÊNDICE E: GESTÃO FINANCEIRA.
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VOF Based Multiphase Lattice Boltzmann Method Using Explicit Kinematic Boundary Conditons at the Interface / VOF Based Multiphase Lattice Boltzmann Method Using Explicit Kinematic Boundary Conditions at the InterfaceMaini, Deepak 10 July 2007 (has links)
A VOF based multiphase Lattice Boltzmann method that explicitly prescribes kinematic boundary conditions at the interface is developed. The advantage of the method is the direct control over the surface tension value. The details of the numerical method are presented. The Saffman instability, Taylor instability, and flow of deformable suspensions in a channel are used as example-problems to demonstrate the accuracy of the method. The method allows for relatively large viscosity and density ratios.
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Slice-Based Water Simulation for Breaking WavesWu, Jyun-ming 04 September 2009 (has links)
The simulation of breaking wave has a computationally intensive application. In order to reduce the computation, this thesis presents a slice-based water simulation method for ocean breaking waves on natural simulation by generating the 2D simulations and then integrating these 2D simulation results into a 3D shape. We first simulate a 2D wave by a 2D Navier-Stokes solver to obtain the varying of ocean. Then, we combine VOF (Volume of fluid) with a new reconstruct free surface method that is a fast 2D simulation. We use linear interpolation with noise function to construct a complete 3D ocean simulation from these 2D simulations. By doing these, one can reduce the computation time and achieve better efficiency.
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Volume of Fluid Simulations for Droplet Impact on Dry and Wetted Hydrophobic and Superhydrophobic SurfacesBurtnett, Emily Nicole 11 August 2012 (has links)
An aircraft may experience inlight ice accretion and corresponding reductions in performance and control when the vehicle encounters clouds of super-cooled water droplets. The EADS-IW Surface Engineering Group is investigating passive anti-icing possibilities, such as functional and ice phobic coatings. Ice-resistant coatings require investigating droplet impact on dry surfaces and wet films, including microscopic effects such as droplet splashing. To investigate droplet impacts, a volume of fluid (VOF) flow solver was used for droplets impacting dry and wetted hydrophobic and superhydrophobic surfaces, focusing on meso-scale simulations. The effects of structured, micro-scale surface roughness and the effects of a thin wet film on the surface, corresponding to a saturated surface under high humidity conditions, were investigated. Axisymmetric domains produced acceptable results for smooth, dry surfaces. It was determined that in order to properly predict behavior of droplets impacting surfaces with structured micro-scale roughness, three-dimensional simulations are recommended.
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A Numerical Model for Oil/Water Separation from a Solid ParticleFan, Eric Sheung-Chi 26 July 2010 (has links)
A computational fluid dynamics model has been developed to study an oil-coated particle immersed in a uniform aqueous flow, to determine the conditions that favour oil separation. The governing flow equations are discretized using a finite volume approach, and the oil/water interface is captured using the Volume-of-Fluid (VOF) method in a 2D spherical coordinate system. The model predicts different mechanisms for oil separation. At a Reynolds number, Re, equal to 1, and at a low capillary number, Ca << 1, the high interfacial tension can induce rapid contact line motion, to the extent that the oil film can advance past its equilibrium position and separate from the particle. This mechanism requires that the contact angle measured through the oil phase is large. On the other hand, as Ca approaches 1, the shear exerted by the external flow stretches the oil into a thread that will eventually rupture and separate.
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A Numerical Model for Oil/Water Separation from a Solid ParticleFan, Eric Sheung-Chi 26 July 2010 (has links)
A computational fluid dynamics model has been developed to study an oil-coated particle immersed in a uniform aqueous flow, to determine the conditions that favour oil separation. The governing flow equations are discretized using a finite volume approach, and the oil/water interface is captured using the Volume-of-Fluid (VOF) method in a 2D spherical coordinate system. The model predicts different mechanisms for oil separation. At a Reynolds number, Re, equal to 1, and at a low capillary number, Ca << 1, the high interfacial tension can induce rapid contact line motion, to the extent that the oil film can advance past its equilibrium position and separate from the particle. This mechanism requires that the contact angle measured through the oil phase is large. On the other hand, as Ca approaches 1, the shear exerted by the external flow stretches the oil into a thread that will eventually rupture and separate.
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Modeling Three-dimensional Flow and Heat Transfer in Variable Surface Tension Two-phase FlowsSamareh Abolhassani, Babak 12 August 2013 (has links)
In the present study a parallel three dimensional Volume of Fluid (VOF) method is developed to simulate Marangoni force in immiscible fluids with variable surface tension. Conservation equations are solved based on cell-averaged one-field volume tracking scheme. Evaluating the convective term in the energy equation along the boundary between the fluids highly depends on the position and orientation of the interface; hence, using average cell values simply ignores the interface shape and leads to computational uncertainty. As a remedy to this issue, the original idea behind the volume tracking method is used not only to advect mass and momentum but also energy across cells. To verify the proposed algorithm, results are compared against theoretically predicted thermocapillary migration velocity of a droplet at the limit of zero Marangoni number. However, at relatively high Marangoni numbers, thermal boundary layers are very thin and challenging to resolve. To demonstrate the capabilities of the heat transfer module, simulations of a Fluorinert droplet moving in silicon oil under applied temperature gradient in microgravity are compared against the available experimental results and the migration velocity of the droplet are reported.
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Modeling Three-dimensional Flow and Heat Transfer in Variable Surface Tension Two-phase FlowsSamareh Abolhassani, Babak 12 August 2013 (has links)
In the present study a parallel three dimensional Volume of Fluid (VOF) method is developed to simulate Marangoni force in immiscible fluids with variable surface tension. Conservation equations are solved based on cell-averaged one-field volume tracking scheme. Evaluating the convective term in the energy equation along the boundary between the fluids highly depends on the position and orientation of the interface; hence, using average cell values simply ignores the interface shape and leads to computational uncertainty. As a remedy to this issue, the original idea behind the volume tracking method is used not only to advect mass and momentum but also energy across cells. To verify the proposed algorithm, results are compared against theoretically predicted thermocapillary migration velocity of a droplet at the limit of zero Marangoni number. However, at relatively high Marangoni numbers, thermal boundary layers are very thin and challenging to resolve. To demonstrate the capabilities of the heat transfer module, simulations of a Fluorinert droplet moving in silicon oil under applied temperature gradient in microgravity are compared against the available experimental results and the migration velocity of the droplet are reported.
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