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Author: Hyundo Lee Publisher: ISBN: Category : Languages : en Pages : 174
Book Description
Displacement of a fluid by an immiscible fluid occurs in various situations such as oil recovery in underground reservoirs, transport in the human body, and other interconnected network systems and porous media. We are motivated by oil recovery processes in geological porous media that take place at the micrometer scale, and focus in particular on the effects of wettability and geometry of microstructures on immiscible liquid-liquid displacements, that result from interactions in oil-water-rock systems. Microfluidic devices, micromodels, have been proposed as experimental test beds for reproducing flows in oil reservoirs in laboratory environments since they offer fine control over geometry and chemistry, and therefore provide insights into their effects on the process. These microfluidic devices are usually two-dimensional and transparent, with a simplified porous network designed to visualize and study fluid behavior in porous media. In oil reservoir research, the microfluidic test beds reflect underground oil reservoir conditions, for example, porosity, permeability, and wettability. The work in this thesis focuses on simple, additive micromodel fabrication techniques to build robust and reproducible structures in microfluidic channels and on the basic and fundamental understanding of immiscible displacement processes with simplified models and controlled flow conditions. We introduce two simple micromodel fabrication methods that can provide design flexibility with photopatterning, the ability to tailor wetting properties, and the calcium carbonate structure that is the most common constituent of oil reservoirs. We utilize a microscope projection lithography to construct polymeric structures with pre-defined wetting properties using a UV-initiated copolymerization method, and we are also able to make real-rock carbonate micromodels by incorporating calcium carbonate seed particles into microstructures and growing them with a supersaturated calcium carbonate solution. Using the micromodel fabrication methods thus developed, we have systematically explored oil-water immiscible displacement processes in a controlled manner with respect to various geometric and wettability conditions. With the fact that our flow experiment is in a small capillary number regime, we formulate a mathematical model for the oil-water displacement process with photopatterned structures of simple geometry and periodic patterns, and verify our theoretical model by matching it with our experimental observations, and we also conduct oil recovery model studies with encapsulated oil pockets with aqueous surfactant solution flooding. Lastly, based on the experience of calcium carbonate/hydrogel composite structuring and calcium carbonate growth from the structure, we expand our work and develop a method of making drug-laden hydrogel particles. By developing flexible methods to make microfluidic devices for immiscible fluids displacement study and investigation on the displacement process, we have been able to realize that microfluidic research with simplified conditions can enhance fundamental understanding of multiphase flow in natural, complex porous media.
Author: Hyundo Lee Publisher: ISBN: Category : Languages : en Pages : 174
Book Description
Displacement of a fluid by an immiscible fluid occurs in various situations such as oil recovery in underground reservoirs, transport in the human body, and other interconnected network systems and porous media. We are motivated by oil recovery processes in geological porous media that take place at the micrometer scale, and focus in particular on the effects of wettability and geometry of microstructures on immiscible liquid-liquid displacements, that result from interactions in oil-water-rock systems. Microfluidic devices, micromodels, have been proposed as experimental test beds for reproducing flows in oil reservoirs in laboratory environments since they offer fine control over geometry and chemistry, and therefore provide insights into their effects on the process. These microfluidic devices are usually two-dimensional and transparent, with a simplified porous network designed to visualize and study fluid behavior in porous media. In oil reservoir research, the microfluidic test beds reflect underground oil reservoir conditions, for example, porosity, permeability, and wettability. The work in this thesis focuses on simple, additive micromodel fabrication techniques to build robust and reproducible structures in microfluidic channels and on the basic and fundamental understanding of immiscible displacement processes with simplified models and controlled flow conditions. We introduce two simple micromodel fabrication methods that can provide design flexibility with photopatterning, the ability to tailor wetting properties, and the calcium carbonate structure that is the most common constituent of oil reservoirs. We utilize a microscope projection lithography to construct polymeric structures with pre-defined wetting properties using a UV-initiated copolymerization method, and we are also able to make real-rock carbonate micromodels by incorporating calcium carbonate seed particles into microstructures and growing them with a supersaturated calcium carbonate solution. Using the micromodel fabrication methods thus developed, we have systematically explored oil-water immiscible displacement processes in a controlled manner with respect to various geometric and wettability conditions. With the fact that our flow experiment is in a small capillary number regime, we formulate a mathematical model for the oil-water displacement process with photopatterned structures of simple geometry and periodic patterns, and verify our theoretical model by matching it with our experimental observations, and we also conduct oil recovery model studies with encapsulated oil pockets with aqueous surfactant solution flooding. Lastly, based on the experience of calcium carbonate/hydrogel composite structuring and calcium carbonate growth from the structure, we expand our work and develop a method of making drug-laden hydrogel particles. By developing flexible methods to make microfluidic devices for immiscible fluids displacement study and investigation on the displacement process, we have been able to realize that microfluidic research with simplified conditions can enhance fundamental understanding of multiphase flow in natural, complex porous media.
Author: Yu Lu Publisher: ISBN: Category : Microfluidics Languages : en Pages : 0
Book Description
Microfluidic systems attract attention because the benefit they offer such as very high surface area to volume ratio and the precise control of the flow features or droplets formation. However, the study of displacement flows has not been systematically explored. This thesis presents a study of the behaviour of liquid-liquid two-phase flows in microchannel during the displacement of one liquid by another. Liquid displacement using immiscible and miscible fluid pairs were carried out. The kinematic viscosities of the fluids used range from 1 to 100 cSt. Three types of straight channel and a T-junction channel were tested. The flow activities at the fluids interface, with the addition of surfactants, were mainly investigated. Flow regimes were identified and their occurrence was illustrated via flow pattern maps. CFD simulations are applied largely in the study of fluid mechanics aiming to confidently predict flow behaviour from computational methods. The experimental results were used to validate CFD simulations carried out using the Fluent package incorporating the VoF model. Good agreement between simulation and experiment results was achieved.
Author: Francisco José Galindo-Rosales Publisher: Springer ISBN: 3319595938 Category : Technology & Engineering Languages : en Pages : 116
Book Description
This monograph contains expert knowledge on complex fluid-flows in microfluidic devices. The topical spectrum includes, but is not limited to, aspects such as the analysis, experimental characterization, numerical simulations and numerical optimization. The target audience primarily comprises researchers who intend to embark on activities in microfluidics. The book can also be beneficial as supplementary reading in graduate courses.
Author: Hamideh Elekaei Behjati Publisher: ISBN: Category : Hydrodynamics Languages : en Pages : 208
Book Description
Microfluidic devices are utilized in a wide range of applications, including micro-electromechanical devices, drug delivery, biological diagnostics and micro-fuel cell systems. Of particular interest here are liquid-liquid microfluidic systems; which are used in drug discovery, food and oil industry amongst others. Increased understanding of the fundamentals of flows in such devices and an improved capacity to design them can come from modelling. In the case of liquid-liquid flows in microfluidic systems, it is necessary to explicitly model the behaviour of the individual liquid phases. Such explicit numerical simulation (ENS) as it is termed requires advanced numerical methods that are able to evaluate flow involving multiple deforming fluid domains within often complex boundaries. Smoothed Particle Hydrodynamics (SPH), a Lagrangian meshless method, is particularly suitable for such problems. This use of a CFD allows determination of parameters that are difficult to determine experimentally because of the challenges faced in microfabrication. The study reported in this thesis addresses these concerns through development of a new SPH-based model to correctly capture the immiscible liquid-liquid interfaces in general and for a microfluidic hydrodynamic focusing system in particular. The model includes surface tension to enforce immiscibility between different liquids based on a new immiscibility model, enforces strict incompressibility, and allows for arbitrary fluid constitutive models. This work presents a detailed study on the effects of various flow parameters including flowrate ratio, viscosity ratio and capillary number of each liquid phase, and geometry characteristics such as channel size, width ratio, and the angle between the inlet main and side channels on the flow dynamics and topological changes of the multiphase microfluidic system. According to our findings, both flowrate quantity and flowrate ratio affect the droplet length in the dripping regime and a large viscosity ratio imposes an increase in the flowrate of the continuous phase with the same capillary number of the dispersed phase to attain dripping regime in the outlet channel. Also, increasing the side channel width causes longer droplets, and the right-angled design makes the most efficient focusing behaviour. This study will provide great insights in designing microfluidic devices involving immiscible liquid-liquid flows.
Author: Patrick Tabeling Publisher: ISBN: 0199588163 Category : Science Languages : en Pages : 312
Book Description
Microfluidics deals with fluids flowing in miniaturized systems, and has practical applications in the pharmaceutical, biomedical and chemical engineering fields. This text provides an introduction to this emerging discipline.
Author: Ryan Kelly Publisher: BoD – Books on Demand ISBN: 9535101064 Category : Science Languages : en Pages : 254
Book Description
Advances in Microfluidics provides a current snapshot of the field of microfluidics as it relates to a variety of sub-disciplines. The chapters have been divided into three sections: Fluid Dynamics, Technology, and Applications, although a number of the chapters contain aspects that make them applicable to more than one section. It is hoped that this book will serve as a useful resource for recent entrants to the field as well as for established practitioners.
Author: Yujun Song Publisher: John Wiley & Sons ISBN: 352780062X Category : Science Languages : en Pages : 579
Book Description
The first book offering a global overview of fundamental microfluidics and the wide range of possible applications, for example, in chemistry, biology, and biomedical science. As such, it summarizes recent progress in microfluidics, including its origin and development, the theoretical fundamentals, and fabrication techniques for microfluidic devices. The book also comprehensively covers the fluid mechanics, physics and chemistry as well as applications in such different fields as detection and synthesis of inorganic and organic materials. A useful reference for non-specialists and a basic guideline for research scientists and technicians already active in this field or intending to work in microfluidics.
Author: Jacky Sai Ho Lee Publisher: ISBN: 9780494161678 Category : Languages : en Pages : 276
Book Description
With the advancement in electrokinetics and its applications to multiphase microfluidic systems, there lacks a fundamental understanding of electroosmotic flow with the presence of immiscible liquid-fluid interfaces. This thesis addresses the fundamentals of two-phase electroosmotic flow by theoretical development and experimentation. A theoretical model is proposed, which considers both the electrical double layer forces and the surface forces at liquid-fluid interfaces. A microfabrication method is also proposed, in which self-assembled monolayers of Octadecyltrichlorosilane and deep-UV irradiation were used to create surface energy (hydrophobic-hydrophilic) patterns simultaneously on all inner surfaces of a slit glass microchip. Liquid is confined by the surface energy on the glass surfaces, forming liquid-air interfaces sidewalls. Experimental observations indicated only the theoretical model that includes the consideration of surface charges is capable of fully describing all of the experimental results.
Author: William B. J. Zimmerman Publisher: Springer Science & Business Media ISBN: 9783211329948 Category : Science Languages : en Pages : 320
Book Description
Microfluidics is a microtechnological field dealing with the precise transport of fluids (liquids or gases) in small amounts (e.g. microliters, nanoliters or even picoliters). This book provides a useful introduction into this burgeoning field, and a specific application of microfluidics is presented. It also gives a survey of microfluidics.
Author: Hyundo Lee
Author: Hyundo Lee
Author: Yu Lu
Author: Francisco José Galindo-Rosales
Author: Hamideh Elekaei Behjati
Author: E. D. Chikhliwala
Author: Patrick Tabeling
Author: Ryan Kelly
Author: Yujun Song
Author: Jacky Sai Ho Lee
Author: William B. J. Zimmerman