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Accurate Numerical Simulation Of Reaction Diffusion Processes For Heavy Oil Recovery
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Book Synopsis Accurate Numerical Simulation of Reaction-diffusion Processes for Heavy Oil Recovery by : Pradeep Ananth Govind
Download or read book Accurate Numerical Simulation of Reaction-diffusion Processes for Heavy Oil Recovery written by Pradeep Ananth Govind and published by . This book was released on 2008 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Efficient Simulation of Thermal Enhanced Oil Recovery Processes by : Zhouyuan Zhu
Download or read book Efficient Simulation of Thermal Enhanced Oil Recovery Processes written by Zhouyuan Zhu and published by Stanford University. This book was released on 2011 with total page 237 pages. Available in PDF, EPUB and Kindle. Book excerpt: Simulating thermal processes is usually computationally expensive because of the complexity of the problem and strong nonlinearities encountered. In this work, we explore novel and efficient simulation techniques to solve thermal enhanced oil recovery problems. We focus on two major topics: the extension of streamline simulation for thermal enhanced oil recovery and the efficient simulation of chemical reaction kinetics as applied to the in-situ combustion process. For thermal streamline simulation, we first study the extension to hot water flood processes, in which we have temperature induced viscosity changes and thermal volume changes. We first compute the pressure field on an Eulerian grid. We then solve for the advective parts of the mass balance and energy equations along the individual streamlines, accounting for the compressibility effects. At the end of each global time step, we account for the nonadvective terms on the Eulerian grid along with gravity using operator splitting. We test our streamline simulator and compare the results with a commercial thermal simulator. Sensitivity studies for compressibility, gravity and thermal conduction effects are presented. We further extended our thermal streamline simulation to steam flooding. Steam flooding exhibits large volume changes and compressibility associated with the phase behavior of steam, strong gravity segregation and override, and highly coupled energy and mass transport. To overcome these challenges we implement a novel pressure update along the streamlines, a Glowinski scheme operator splitting and a preliminary streamline/finite volume hybrid approach. We tested our streamline simulator on a series of test cases. We compared our thermal streamline results with those computed by a commercial thermal simulator for both accuracy and efficiency. For the cases investigated, we are able to retain solution accuracy, while reducing computational cost and gaining connectivity information from the streamlines. These aspects are useful for reservoir engineering purposes. In traditional thermal reactive reservoir simulation, mass and energy balance equations are solved numerically on discretized reservoir grid blocks. The reaction terms are calculated through Arrhenius kinetics using cell-averaged properties, such as averaged temperature and reactant concentrations. For the in-situ combustion process, the chemical reaction front is physically very narrow, typically a few inches thick. To capture accurately this front, centimeter-sized grids are required that are orders of magnitude smaller than the affordable grid block sizes for full field reservoir models. To solve this grid size effect problem, we propose a new method based on a non-Arrhenius reaction upscaling approach. We do not resolve the combustion front on the grid, but instead use a subgrid-scale model that captures the overall effects of the combustion reactions on flow and transport, i.e. the amount of heat released, the amount of oil burned and the reaction products generated. The subgrid-scale model is calibrated using fine-scale highly accurate numerical simulation and laboratory experiments. This approach significantly improves the computational speed of in-situ combustion simulation as compared to traditional methods. We propose the detailed procedures to implement this methodology in a field-scale simulator. Test cases illustrate the solution consistency when scaling up the grid sizes in multidimensional heterogeneous problems. The methodology is also applicable to other subsurface reactive flow modeling problems with fast chemical reactions and sharp fronts. Displacement front stability is a major concern in the design of all the enhanced oil recovery processes. Historically, premature combustion front break through has been an issue for field operations of in-situ combustion. In this work, we perform detailed analysis based on both analytical methods and numerical simulation. We identify the different flow regimes and several driving fronts in a typical 1D ISC process. For the ISC process in a conventional mobile heavy oil reservoir, we identify the most critical front as the front of steam plateau driving the cold oil bank. We discuss the five main contributors for this front stability/instability: viscous force, condensation, heat conduction, coke plugging and gravity. Detailed numerical tests are performed to test and rank the relative importance of all these different effects.
Book Synopsis The Journal of Canadian Petroleum Technology by :
Download or read book The Journal of Canadian Petroleum Technology written by and published by . This book was released on 2010 with total page 516 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Numerical Simulation in Oil Recovery by : Mary E. Wheeler
Download or read book Numerical Simulation in Oil Recovery written by Mary E. Wheeler and published by Springer. This book was released on 2012-08-14 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: The papers of this book are based on a Symposium on Numerical Simulation in Oil Recovery held at the Institute for Mathematics and its Applications. The major research emphasis is on the modeling of fractures, heterogeneities, viscous fingering, and diffusion-dispersion effects in the flow in porous media. This volume contains seventeen comprehensive papers on the latest developments in this exciting subject. Its diverse presentation brings together the various disciplines of applied mathematics, chemical engineering, physics and hydrology.
Book Synopsis Numerical Simulation in Oil Recovery by : Mary Fanett Wheeler
Download or read book Numerical Simulation in Oil Recovery written by Mary Fanett Wheeler and published by Springer. This book was released on 1988 with total page 304 pages. Available in PDF, EPUB and Kindle. Book excerpt: The papers of this book are based on a Symposium on Numerical Simulation in Oil Recovery held at the Institute for Mathematics and its Applications. The major research emphasis is on the modeling of fractures, heterogeneities, viscous fingering, and diffusion-dispersion effects in the flow in porous media. This volume contains seventeen comprehensive papers on the latest developments in this exciting subject. Its diverse presentation brings together the various disciplines of applied mathematics, chemical engineering, physics and hydrology.
Book Synopsis Numerical Simulation of Heavy Oil Recovery by the Steam-assisted Gravity Drainage Process by : Louis Chow
Download or read book Numerical Simulation of Heavy Oil Recovery by the Steam-assisted Gravity Drainage Process written by Louis Chow and published by . This book was released on 1993 with total page 326 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Numerical Simulation in Oil Recovery by : Mary E Wheeler
Download or read book Numerical Simulation in Oil Recovery written by Mary E Wheeler and published by . This book was released on 1987-12-08 with total page 300 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Numerical Simulation and History Matching of Steam-foam Process to Enhance Heavy Oil Recovery by : Erdi Aydin
Download or read book Numerical Simulation and History Matching of Steam-foam Process to Enhance Heavy Oil Recovery written by Erdi Aydin and published by . This book was released on 2018 with total page 384 pages. Available in PDF, EPUB and Kindle. Book excerpt: Thermal enhanced oil recovery techniques have been considered as the best approach to produce heavy oil; however, hybrid methods, which are combinations of different oil recovery methods, reveal more promise in enhancing oil production from heavy and viscose reservoirs. In this research, we investigate improving recovery from heavy oil reservoirs, considering steam foam method to control the mobility of steam and oil in such reservoirs, and delivering proper amount of heat to reservoir in order to reduce oil viscosity. In this thesis, a compositional K-value based reservoir simulator, CMG-STARS, was used to build simulation models for all case studies. Steam table is used to calculate the phase change during steam injection and to capture latent heat effect on energy balance and mass balance equations. CMG-STARS empirical foam model is used to capture mobility of steam in the presence of surfactant. Simulation models are tuned with experimental core data and field history data. Simulation results illustrated that a considerable increase in oil recovery is obtained when steam foam is used. It is also observed that foam parameters, which was used in modeling, affects oil recovery, reservoir average temperature, average pressure and gas saturation. Optimized foam parameters were determined considering oil recovery, average reservoir temperature, and average reservoir pressure. Finally, simulations revealed that field and simulation results were in good agreement with field data, and that steam foam oil recovery method has the potential to become a promising oil recovery method for heavy oil reservoirs.
Book Synopsis Numerical Simulation in Oil Recovery by : Mary F. Wheeler
Download or read book Numerical Simulation in Oil Recovery written by Mary F. Wheeler and published by . This book was released on 1988-01-01 with total page 283 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Experimental, Theoretical, and Numerical Studies of Solvent-Based Heavy Oil Recovery Processes by : Lixing Lin
Download or read book Experimental, Theoretical, and Numerical Studies of Solvent-Based Heavy Oil Recovery Processes written by Lixing Lin and published by . This book was released on 2015 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Innovations in Enhanced and Improved Oil Recovery - New Advances by : Mansoor Zoveidavianpoor
Download or read book Innovations in Enhanced and Improved Oil Recovery - New Advances written by Mansoor Zoveidavianpoor and published by BoD – Books on Demand. This book was released on 2024-04-24 with total page 196 pages. Available in PDF, EPUB and Kindle. Book excerpt: This book navigates the evolving landscape of Enhanced Oil Recovery (EOR) and Improved Oil Recovery (IOR), covering diverse topics such as lithological dynamics in CO2-EOR, the impact of asphaltene precipitation in WAG implementation, progress in CO2-EOR and storage technology, in situ foam generation for unconventional fractured reservoirs, electromagnetic radiation effects on heavy oil upgrading, advancements in hydraulic fracturing, in situ synthesis of nanoparticles, and operational insights in the Bakken Shale. This comprehensive volume serves as an indispensable resource for professionals and researchers in the ever-changing field of enhanced and improved oil recovery.
Book Synopsis Investigation of Interplay of Capillarity, Drainage Height, and Aqueous Phase Saturation on Mass Transfer Phenomena in Heavy Oil Recovery by Vapex Process by : Farid Ahmadloo
Download or read book Investigation of Interplay of Capillarity, Drainage Height, and Aqueous Phase Saturation on Mass Transfer Phenomena in Heavy Oil Recovery by Vapex Process written by Farid Ahmadloo and published by . This book was released on 2013 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Lab to Field Scale Modeling of Low Temperature Air Injection with Hydrocarbon Solvents for Heavy-oil Recovery in Naturally Fractured Reservoirs by : Jose R. Mayorquin-Ruiz
Download or read book Lab to Field Scale Modeling of Low Temperature Air Injection with Hydrocarbon Solvents for Heavy-oil Recovery in Naturally Fractured Reservoirs written by Jose R. Mayorquin-Ruiz and published by . This book was released on 2015 with total page 197 pages. Available in PDF, EPUB and Kindle. Book excerpt: Alternatives for enhanced oil recovery processes in heavy oil containing deep naturally fractured reservoirs (NFR) are limited due to excessive heat losses when steam is injected. Air injection at high temperature oxidation conditions (in-situ combustion) has been considered as an alternative to aqueous based thermal applications. However, its implementation has serious limitations including poor areal distribution of injected air and poor combustion efficiency due to the heterogeneous nature of these reservoirs as well as the safety risk of unconsumed injected oxygen (O2) reaching the production wells. Taking advantage of the low cost and availability of air, one option is to use air at low temperature conditions (low temperature oxidation, LTO) as a pressurizing agent in NFR. Oxygenated compounds are generated at these conditions resulting in oil viscosity increase, reducing fluid mobility. In order to minimize this detrimental effect, a combination of air injection with hydrocarbon solvents can be applied. The objectives of this thesis are to evaluate air injection at LTO conditions in NFR containing heavy oil as a way to improve oil recovery, to clarify the effect of hydrocarbon solvent addition into air on oil recovery and O2 consumption, and to propose optimal conditions (temperature, air/solvent ratio) and implementation strategies for an efficient use of this suggested method. Comprehensive laboratory and numerical simulation studies were conducted to achieve these objectives. Static diffusion experiments--simulating cyclic gas injection (huff-and-puff)--were carried out by soaking heavy oil saturated cores into a reactor filled with gas representing a matrix/fracture system. Oil recovery and O2 consumption were the main parameters assessed and an extensive set of variables including rock type, temperature, fracture volume, solvent type, matrix size, gas injection sequences, and soaking times were studied. From experimental studies, the following conclusions were made: 1.Gas sequence design affects oil recovery, 2.O2 consumption in air cycles is higher after the core is soaked into butane rather than propane, 3.It is beneficial to soak cores in air+C3 mixture rather than pure air or solvent; i.e., lower O2 concentration in produced gas, less solvent usage, higher and faster oil recovery compared to alternate injection of air and C3. Then, core scale numerical simulation models were created for modeling lab experiments for a sensitivity analysis on Air/C3 ratio and matrix size. The results show that the process is extremely sensitive to matrix size and optimization of air injection (assisted by hydrocarbon solvents) can be achieved based on the minimized hydrocarbon solvent for a given matrix size. Additionally, a sensitivity analysis was performed using an up-scaled numerical model to the field scale containing meter-scale matrix blocks. It was observed that oil production mechanisms acting in a matrix block surrounded by gas filling the fractures are predominantly gas-oil gravity drainage, effective diffusion, and voidage replacement of oil by gas. Finally, a numerical simulation sector model of a hypothetical NFR was created and several air-gas injection sequences were analyzed. It was concluded that injection of air (LTO conditions) and propane represents an alternative for heavy oil recovery from NFRs at the field scale, and an optimum production time/soaking time ratio can be obtained for given gas injection sequences (type of gas and injection/soaking durations), temperature, and block sizes.
Book Synopsis Comparative Evaluation of Three Immiscible Displacement Processes in Heavy Oil System (Numerical Simulation) by : Varinder Ghotra
Download or read book Comparative Evaluation of Three Immiscible Displacement Processes in Heavy Oil System (Numerical Simulation) written by Varinder Ghotra and published by . This book was released on 2011 with total page 156 pages. Available in PDF, EPUB and Kindle. Book excerpt: Research in heavy oil reservoirs has significantly increased over the past few years due to limiting production of conventional oil. A detailed experimental work was conducted using three heavy oil recovery techniques at University of Regina. The techniques used in these experiments were waterflooding, CO2 flooding and water alternating CO2 flooding. The objective of this 4th year project is to simulate the data collected from these experiments using computer modeling group (CMG) and compare the results with those obtained from the experiments.
Book Synopsis Numerical Simulation of Heavy Oil and Bitumen Recovery and Upgrading Techniques by : Muhammad Rabiu Ado
Download or read book Numerical Simulation of Heavy Oil and Bitumen Recovery and Upgrading Techniques written by Muhammad Rabiu Ado and published by . This book was released on 2017 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Modeling of Enhanced Heavy Oil Recovery Processes by : Zinqian Lu
Download or read book Modeling of Enhanced Heavy Oil Recovery Processes written by Zinqian Lu and published by . This book was released on 2021 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: Many heavy oil reservoirs are now developed by enhanced heavy oil recovery methods, such as solvent-based recovery techniques. The solvent-based recovery techniques have advantages in energy effectiveness, cost efficiency, and environmental benefits compared with other methods. In the application of solvent-based recovery techniques, many types of solvent are available, including methane (C1), propane (C3), carbon dioxide (CO2), and solvent mixture. Foamy oil flow is considered an essential mechanism and has been extensively studied. For each heavy oil-solution gas system, the flow behavior is unique, and a systematic study is necessary to understand the foamy oil mechanism better. Previously proposed simulation models did not history match the production data and pressure distribution simultaneously. This deficiency would increase the uncertainty of the simulation result and influence the subsequent evaluation or prediction of the enhanced heavy oil recovery process since the pressure incremental is not captured. This work provides an innovative methodology to characterize foamy oil flow and gas-oil two-phase flow in heavy oil-different solvent systems. For each heavy oil-solvent system, a reliable non-equilibrium simulation model is developed and validated with sand-pack model pressure depletion tests by capture the production data and pressure distribution. This work consists of a systematic simulation study using the same heavy oil sample with different types of solvent. Since the mobility ratio between the solvent and heavy oil in applying solvent-based recovery techniques is very high, the frontal instabilities are also widely observed at the two-phase interface. The instabilities grow and form the viscous fingering phenomenon. Due to the existence of viscous fingering, the breakthrough time is shortened significantly, which will impact the oil recovery and swept efficiency. Since the description and prediction of the two-phase frontal instabilities in the porous media is always a challenge, most current work is based on theoretical models and rarely validated with lab tests. In addition, previous modeling works of frontal instabilities were mainly conducted in the Hele-Shaw model or micromodel, not in the sand-pack model. Hence, previous conducted experimental works were not analyzed with the simulation study in the porous media. In this work, a simulation model is developed by adopting the Volume of Fluid (VOF) method coupled with the Level-Set (LS) method to capture and track the immiscible two-phase interface between oil and water. Then the simulation results of viscosity fingering are validated with lab tests in the porous media in terms of qualitative (frontal instability morphological characteristics) and quantitative (breakthrough time) aspects. The characterization of the frontal instabilities (viscosity fingering) is investigated under different displacing rates and viscosities. It is very challenging to describe and predict both the foamy oil flow and frontal instabilities at the same time during the enhanced heavy oil recovery process. Therefore, this research conducted simulation works and validated with lab tests for each process (foamy oil flow and viscosity fingering) separately. The conducted researches provide numerical simulation methods and reliable simulation models that could be applied to further studies on the history match and prediction of field application. Moreover, the conducted researches allow future research to consider both phenomena (foamy oil flow and viscosity fingering) that happened in the enhanced heavy oil processes by integrating the proposed simulation models in this work.
Book Synopsis Improved Numerical Simulation of Non-thermal Enhanced Heavy Oil Recovery by : Usman Habu Taura
Download or read book Improved Numerical Simulation of Non-thermal Enhanced Heavy Oil Recovery written by Usman Habu Taura and published by . This book was released on 2017 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt:
