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Author: Amir Kianinejad
Publisher:
ISBN:
Category :
Languages : en
Pages : 492
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Book Description
Three-phase flow occurs in many petroleum recovery processes, especially during tertiary recovery. One of the most important parameters to accurately model these complex processes at large scale is relative permeability to each of the flowing fluids. However, relative permeability in three-phase systems becomes extremely complicated due to different flow mechanisms involved with three-phase flow as well as dependence of relative permeability on saturation path (water and oil saturations at each time in three-phase saturation space). During the past several decades, many studies reported experimental measurements of relative permeabilities in three-phase systems under different rock and fluid properties. Based on these measurements, several empirical models have been developed to predict relative permeabilities in three-phase space. However, the performance of these models have been frequently reported to be poor in reproducing experimental data. This indicates that despite the great effort during the past decades, there are still some aspects of three-phase space that have not been completely understood. Therefore, in this study we attempt to obtain a better physical understanding of three-phase relative permeability through extending relative permeability measurements over the entire three-phase phase space with different fluids and porous media. To do so, we use a gravity drainage method to measure three-phase relative permeabilities. However, previous applications of this method suffered from three main issues: a) relative permeabilities at medium to high saturations were not accessible due to quick saturation changes at early times of experiments, b) saturation path of experiments was out of control, and c) it was only applicable to unconsolidated sandpacks. In this study, we develop new procedures and methods to overcome the mentioned shortcomings of this method, by combining the method with steady-state method and applying a small gas pressure gradient. These improvements to the method allows us to measure relative permeabilities along different saturation paths, in both consolidated and unconsolidated porous media while extending the relative permeability measurements to higher saturation regions. In particular, we measure three-phase relative permeabilities along several saturation paths during unsteady-state gravity drainage experiments in two consolidated and unconsolidated media, with oils varying in composition, viscosity, and spreading coefficient. The method involves measurement of in-situ saturations along the porous media at different times during the experiments. These saturation profiles are then used to directly obtain three-phase relative permeabilities. We find that in our water-wet media, oil relative permeability varies significantly depending on the saturation path, while water relative permeability remains unchanged. In addition, oil relative permeabilities along different saturation paths extrapolate to different residual oil saturations. Interestingly, we find that once the measured relative permeabilities along different saturation paths are plotted as a function of mobile oil saturation, So-Sor, all of the differences between relative permeabilities vanish and they all form a single relative permeability curve. We compare our data with the relative permeability data published over the past several decades. We find that literature data are in complete agreement with our data. In addition, literature data for water-wet media suggest that for each media, experiments which end up at a different residual saturation result in a different relative permeability curve. This is while the experiments which reach to the same residual oil saturation result in the same oil relative permeability, regardless of their saturation paths. We examine the importance of residual oil saturation using three most commonly used relative permeability models against our data. These models consist of Corey, saturation weighted interpolation (SWI), and Stone. The idea is simply to change residual oil saturation while keeping all the other parameters constant, to fit experimental data along different saturation paths. We find that, by changing residual saturations, Corey and SWI models fit the data well, while the Stone model fails at low saturations. Overall, we find that the key to modeling relative permeability of water-wet media in three-phase space is residual oil saturation. Our data suggests that three-phase oil relative permeability is only a function of mobile oil saturation, and residual oil saturation is a non-linear function of water saturation.
Author: Amir Kianinejad
Publisher:
ISBN:
Category :
Languages : en
Pages : 492
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Book Description
Three-phase flow occurs in many petroleum recovery processes, especially during tertiary recovery. One of the most important parameters to accurately model these complex processes at large scale is relative permeability to each of the flowing fluids. However, relative permeability in three-phase systems becomes extremely complicated due to different flow mechanisms involved with three-phase flow as well as dependence of relative permeability on saturation path (water and oil saturations at each time in three-phase saturation space). During the past several decades, many studies reported experimental measurements of relative permeabilities in three-phase systems under different rock and fluid properties. Based on these measurements, several empirical models have been developed to predict relative permeabilities in three-phase space. However, the performance of these models have been frequently reported to be poor in reproducing experimental data. This indicates that despite the great effort during the past decades, there are still some aspects of three-phase space that have not been completely understood. Therefore, in this study we attempt to obtain a better physical understanding of three-phase relative permeability through extending relative permeability measurements over the entire three-phase phase space with different fluids and porous media. To do so, we use a gravity drainage method to measure three-phase relative permeabilities. However, previous applications of this method suffered from three main issues: a) relative permeabilities at medium to high saturations were not accessible due to quick saturation changes at early times of experiments, b) saturation path of experiments was out of control, and c) it was only applicable to unconsolidated sandpacks. In this study, we develop new procedures and methods to overcome the mentioned shortcomings of this method, by combining the method with steady-state method and applying a small gas pressure gradient. These improvements to the method allows us to measure relative permeabilities along different saturation paths, in both consolidated and unconsolidated porous media while extending the relative permeability measurements to higher saturation regions. In particular, we measure three-phase relative permeabilities along several saturation paths during unsteady-state gravity drainage experiments in two consolidated and unconsolidated media, with oils varying in composition, viscosity, and spreading coefficient. The method involves measurement of in-situ saturations along the porous media at different times during the experiments. These saturation profiles are then used to directly obtain three-phase relative permeabilities. We find that in our water-wet media, oil relative permeability varies significantly depending on the saturation path, while water relative permeability remains unchanged. In addition, oil relative permeabilities along different saturation paths extrapolate to different residual oil saturations. Interestingly, we find that once the measured relative permeabilities along different saturation paths are plotted as a function of mobile oil saturation, So-Sor, all of the differences between relative permeabilities vanish and they all form a single relative permeability curve. We compare our data with the relative permeability data published over the past several decades. We find that literature data are in complete agreement with our data. In addition, literature data for water-wet media suggest that for each media, experiments which end up at a different residual saturation result in a different relative permeability curve. This is while the experiments which reach to the same residual oil saturation result in the same oil relative permeability, regardless of their saturation paths. We examine the importance of residual oil saturation using three most commonly used relative permeability models against our data. These models consist of Corey, saturation weighted interpolation (SWI), and Stone. The idea is simply to change residual oil saturation while keeping all the other parameters constant, to fit experimental data along different saturation paths. We find that, by changing residual saturations, Corey and SWI models fit the data well, while the Stone model fails at low saturations. Overall, we find that the key to modeling relative permeability of water-wet media in three-phase space is residual oil saturation. Our data suggests that three-phase oil relative permeability is only a function of mobile oil saturation, and residual oil saturation is a non-linear function of water saturation.
Author: Manoochehr Akhlaghinia
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Author: M.M. Honarpour
Publisher: CRC Press
ISBN: 1351093223
Category : Technology & Engineering
Languages : en
Pages : 243
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Book Description
This book enables petroleum reservoir engineers to predict the flow of fluids within a hydrocarbon deposit. Laboratory techniques are described for both steady-state and unsteady state measurements, and the calculation of relative permeability from field data is illustrated. A discussion of techniques for determing wettability is included, along with theoretical and empirical methods for the calculation of relative permeability, and prediction techniques. Contents include: Measurement of Rock Relative Permeability; Two-Phase Relative Permeability; Factors Affecting Two-Phase Relative Permeability; Three-Phase Relative Permeability; and Index.
Author: Lee W. Thomas
Publisher:
ISBN:
Category :
Languages : en
Pages : 446
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Book Description
Author: Abhijit Y. Dandekar
Publisher: CRC Press
ISBN: 1439876363
Category : Technology & Engineering
Languages : en
Pages : 547
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Book Description
A strong foundation in reservoir rock and fluid properties is the backbone of almost all the activities in the petroleum industry. Suitable for undergraduate students in petroleum engineering, Petroleum Reservoir Rock and Fluid Properties, Second Edition offers a well-balanced, in-depth treatment of the fundamental concepts and practical aspects that encompass this vast discipline. New to the Second Edition Introductions to Stone II three-phase relative permeability model and unconventional oil and gas resources Discussions on low salinity water injection, saturated reservoirs and production trends of five reservoir fluids, impact of mud filtrate invasion and heavy organics on samples, and flow assurance problems due to solid components of petroleum Better plots for determining oil and water Corey exponents from relative permeability data Inclusion of Rachford-Rice flash function, Plateau equation, and skin effect Improved introduction to reservoir rock and fluid properties Practice problems covering porosity, combined matrix-channel and matrix-fracture permeability, radial flow equations, drilling muds on fluid saturation, wettability concepts, three-phase oil relative permeability, petroleum reservoir fluids, various phase behavior concepts, phase behavior of five reservoir fluids, and recombined fluid composition Detailed solved examples on absolute permeability, live reservoir fluid composition, true boiling point extended plus fractions properties, viscosity based on compositional data, and gas-liquid surface tension Accessible to anyone with an engineering background, the text reveals the importance of understanding rock and fluid properties in petroleum engineering. Key literature references, mathematical expressions, and laboratory measurement techniques illustrate the correlations and influence between the various properties. Explaining how to acquire accurate and reliable data, the author describes coring and fluid sampling methods, issues related to handling samples for core analyses, and PVT studies. He also highlights core and phase behavior analysis using laboratory tests and calculations to elucidate a wide range of properties.
Author: Martin J. Blunt
Publisher: Cambridge University Press
ISBN: 1107093465
Category : Science
Languages : en
Pages : 503
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Book Description
This book provides a fundamental description of multiphase fluid flow through porous rock, based on understanding movement at the pore, or microscopic, scale.
Author: Prakash Purswani
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
Relative permeability (kr) is a transport property used for characterizing the flow of multiple phases through a porous medium. Inputs of kr are integral for reservoir simulations. Multiple parameters such as phase saturation, wettability of the medium, fluid properties, flow characteristics, pore topology, fluid phase topology, and fluid/fluid interfacial areas are known to affect relative permeabilities. Current kr models are functions of phase saturation that are matched for specific flow/experimental conditions. The other parameters affecting relative permeabilities are inherently captured through these saturation functions. Representation of relative permeabilities only in the saturation space causes non-uniqueness and path dependency in relative permeabilities which often cause simulations to fail because they lack generality and are not physically based. As a result, hysteresis in relative permeabilities arises, which is a major modeling issue for reservoir simulations. In this dissertation, models for relative permeabilities are presented by considering functional forms that include the effects of the key controlling parameters on relative permeabilities. The purpose of this dissertation is twofold, to (a) understand how different parameters, specifically, phase saturation, phase connectivity, capillary number, and wettability affect relative permeabilities; (b) propose physically-based kr models by including the effects of these parameters. Relative permeabilities are modeled using an equation-of-state (EOS) approach where the exact differential for relative permeability is written in phase connectivity and saturation. A quadratic response-based EOS for relative permeability is modeled in the connectivity-saturation space. Physical limiting conditions on the state parameters are considered to constrain the EOS model. This model is tested for different capillary numbers ranging from one to 10^-6. In addition, we calculated the partial derivatives of relative permeabilities in the state parameters using numerical data sets generated with pore-network modeling. A response for relative permeability is derived in the connectivity-saturation space following the state function approach. The locus bounded by residual nonwetting phase connectivity and residual nonwetting phase saturation is presented for two contact angles in the water-wet regime. Finally, we investigated the role of wettability on phase trapping also using pore-network modeling. An extended Land-based hysteresis trapping model is presented and compared against models from the literature. In addition, models are presented to capture the trends of residual loci for different contact angles. Results show that a simple quadratic response for relative permeability in the connectivity-saturation space captures trends across different capillary numbers. The model tuned for a capillary number in the capillary dominated regime can show predictive capability for other capillary numbers within the same regime. The linear kr-S paths for high capillary numbers (small Corey exponents) and nonlinear kr-S paths for low capillary numbers (high Corey exponents) are found to occur due to fast and slow changes in phase connectivity, respectively. Limiting constraints help in the identification of the physical region in the connectivity-saturation state space. Results also show that the response derived for relative permeability from relative permeability partial derivatives using the state function approach can predict relative permeabilities over the entire numerical data sets, regardless of the direction of flow, thus mitigating hysteresis. Further, the analysis of the effect of wettability shows that both phase trapping as well as the locus of residual saturation and residual phase connectivity are sensitive to contact angle changes. For low receding phase contact angles, the residual locus remains fairly constant, but at higher contact angles, the shape of the residual locus resembles a closed loop. Pore structure constraint at negligible saturation is found to control the shape of the residual locus. Phase trapping was found to reduce significantly for high contact angles owing to pore-scale mechanisms of layer flow of the receding phase and piston-like advance of the invading phase. A newly proposed extended Land-based model is able to capture residual saturation trends for all contact angles. Overall, through this research endeavor, we gain insight into the different intrinsic parameters that affect relative permeability. Through the application of pore-scale measures, these insights are further manifested into practical models that helps describe relative permeabilities physically.
Author: Abhijit Y. Dandekar
Publisher: CRC Press
ISBN: 1420004549
Category : Science
Languages : en
Pages : 472
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Book Description
A strong foundation in reservoir rock and fluid properties is the backbone of almost all the activities in the petroleum industry. Petroleum Reservoir Rock and Fluid Properties offers a reliable representation of fundamental concepts and practical aspects that encompass this vast subject area. The book provides up-to-date coverage of vari
Author: Jacob H. Dane
Publisher: John Wiley & Sons
ISBN: 089118841X
Category : Technology & Engineering
Languages : en
Pages : 1744
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Book Description
The best single reference for both the theory and practice of soil physical measurements, Methods, Part 4 adopts a more hierarchical approach to allow readers to easily find their specific topic or measurement of interest. As such it is divided into eight main chapters on soil sampling and statistics, the solid, solution, and gas phases, soil heat, solute transport, multi-fluid flow, and erosion. More than 100 world experts contribute detailed sections.
Author: Ali Danesh
Publisher: Elsevier
ISBN: 0080540058
Category : Technology & Engineering
Languages : en
Pages : 401
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Book Description
This book on PVT and Phase Behaviour Of Petroleum Reservoir Fluids is volume 47 in the Developments in Petroleum Science series. The chapters in the book are: Phase Behaviour Fundamentals, PVT Tests and Correlations, Phase Equilibria, Equations of State, Phase Behaviour Calculations, Fluid Characterisation, Gas Injection, Interfacial Tension, and Application in Reservoir Simulation.
