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Secondary oil recovery in the Central unit of the Bisti oil field, San Juan County, New MexicoSelinger, Keith Albin, 1939- January 1964 (has links)
No description available.
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Fully coupled fluid flow and geomechanics in the study of hydraulic fracturing and post-fracture productionAghighi, Mohammad Ali, Petroleum Engineering, Faculty of Engineering, UNSW January 2007 (has links)
This work addresses the poroelastic effect on the processes involved in hydraulic fracturing and post-fracture production using a finite element based fully coupled poroelastic model which includes a triple system of wellbore-fracture-reservoir. A novel numerical procedure for modeling hydraulic fracture propagation in a poroelastic medium is introduced. The model directly takes into account the interaction of wellbore, hydraulic fracture and reservoir in a fully coupled manner. This allows realistic simulation of near fracture phenomena such as back stress and leak-off. In addition, fluid leak-off is numerically modeled based on the concept of fluid flow in porous media using a new technique for evaluating local pressure gradient. Besides, the model is capable of accommodating the zone of reduced pressure (including intermediate and fluid lag zones) at the fracture front so as to capture the behavior of fracture tip region more realistically. A fully coupled poroelastic model for gas reservoirs has been also developed using an innovative numerical technique. From the results of this study it has been found that fracture propagation pressure is higher in poroelastic media compared to that of elastic media. Also high formation permeability (in the direction normal to the hydraulic fracture) and large difference between minimum horizontal stress (in case of it being the smallest principal stress) and reservoir pressure reduce the rate of fracture growth. Besides, high pumping rate is more beneficial in elongating a hydraulic fracture whereas high viscous fracturing fluid is advantageous in widening a hydraulic fracture. It has been also shown that rock deformation, permeability anisotropy and modulus of elasticity can have a significant effect on fluid flow in a hydraulically fractured reservoir. Furthermore, it has been shown that long stress reversal time window and large size of stress reversal region can be caused by high initial pressure differential (i.e. the difference between flowing bottomhole pressure and reservoir pressure), low initial differential stress (i.e. the difference between maximum and minimum horizontal stresses) and low formation permeability in tight gas reservoirs. By taking advantage of production induced change in stress state of a reservoir, this study has also shown that a refracture treatment, if carried out in an optimal time window, can lead to higher economic gain. Besides, analysis of stress reversal region has depicted that a small region with high stress concentration in the vicinity of the wellbore could impede refracture from initiating at the desired place. Moreover, re-pressurization of the wellbore can result in further propagation of the initial fracture before initiation or during propagation of the secondary fracture.
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Fully coupled fluid flow and geomechanics in the study of hydraulic fracturing and post-fracture productionAghighi, Mohammad Ali, Petroleum Engineering, Faculty of Engineering, UNSW January 2007 (has links)
This work addresses the poroelastic effect on the processes involved in hydraulic fracturing and post-fracture production using a finite element based fully coupled poroelastic model which includes a triple system of wellbore-fracture-reservoir. A novel numerical procedure for modeling hydraulic fracture propagation in a poroelastic medium is introduced. The model directly takes into account the interaction of wellbore, hydraulic fracture and reservoir in a fully coupled manner. This allows realistic simulation of near fracture phenomena such as back stress and leak-off. In addition, fluid leak-off is numerically modeled based on the concept of fluid flow in porous media using a new technique for evaluating local pressure gradient. Besides, the model is capable of accommodating the zone of reduced pressure (including intermediate and fluid lag zones) at the fracture front so as to capture the behavior of fracture tip region more realistically. A fully coupled poroelastic model for gas reservoirs has been also developed using an innovative numerical technique. From the results of this study it has been found that fracture propagation pressure is higher in poroelastic media compared to that of elastic media. Also high formation permeability (in the direction normal to the hydraulic fracture) and large difference between minimum horizontal stress (in case of it being the smallest principal stress) and reservoir pressure reduce the rate of fracture growth. Besides, high pumping rate is more beneficial in elongating a hydraulic fracture whereas high viscous fracturing fluid is advantageous in widening a hydraulic fracture. It has been also shown that rock deformation, permeability anisotropy and modulus of elasticity can have a significant effect on fluid flow in a hydraulically fractured reservoir. Furthermore, it has been shown that long stress reversal time window and large size of stress reversal region can be caused by high initial pressure differential (i.e. the difference between flowing bottomhole pressure and reservoir pressure), low initial differential stress (i.e. the difference between maximum and minimum horizontal stresses) and low formation permeability in tight gas reservoirs. By taking advantage of production induced change in stress state of a reservoir, this study has also shown that a refracture treatment, if carried out in an optimal time window, can lead to higher economic gain. Besides, analysis of stress reversal region has depicted that a small region with high stress concentration in the vicinity of the wellbore could impede refracture from initiating at the desired place. Moreover, re-pressurization of the wellbore can result in further propagation of the initial fracture before initiation or during propagation of the secondary fracture.
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Metodologia para seleção de conceitos para plantas de processamento submarino / Methodology for slection of concepts for subsea processing plantsPereira, Leandro Augusto Grandin, 1981- 27 August 2018 (has links)
Orientador: Celso Kazuyuki Morooka / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica e Instituto de Geociências / Made available in DSpace on 2018-08-27T23:45:28Z (GMT). No. of bitstreams: 1
Pereira_LeandroAugustoGrandin_M.pdf: 2825767 bytes, checksum: 5cbfd5a04926d5bf83c780db67ca3a60 (MD5)
Previous issue date: 2015 / Resumo: O desenvolvimento de campos marítimos de petróleo e gás natural tem se deslocado para águas cada vez mais profundas, ambientes cada vez mais hostis e áreas cada vez mais remotas. A utilização de soluções convencionais para desenvolver tais campos, especialmente o uso exclusivo de processamento primário em superfície e equipamentos elevação artificial instalados dentro de poços pode não justificar os investimentos. O processamento submarino tem aumentado a atratividade ou até viabilizando a produção de campos marítimos. Visto o aumento em sua utilização, os autores propuseram uma metodologia para selecionar conceitos de plantas submarinas para campos de petróleo e gás natural, utilizando informações disponíveis na literatura e suporte de especialistas em tecnologia submarina e modelagem de produção integrada. Uma menor contrapressão no poço produtor é uma potencial consequência do uso de processamento submarino, podendo tornar o perfil de produção mais atrativo. Como consequência, uma abordagem integrada considerando os estudos necessários para avaliar o escoamento dos fluidos de suas fontes iniciais até os destinos finais é necessária para se propor uma metodologia de seleção. Como alternativa à falta de estudos integrados comparando diferentes soluções de desenvolvimento em campos marítimos, informações de quatro desenvolvimentos comerciais que empregaram processamento submarino foram utilizadas para buscar a validação da metodologia. Os resultados destes estudos de caso sugerem que a metodologia é válida, entretanto não é claro que tais desenvolvimentos de produção utilizariam todas as fases propostas / Abstract: The development of offshore oil and natural gas fields has been moving to deeper waters, harsher environments and more remote areas. The use of conventional solutions to develop such fields, especially sole use of surface processing or downhole artificial lift methods, may not justify the investments. Subsea processing has been increasing the attractiveness or even enabling offshore field developments. Given the increase in its use, the authors proposed a methodology to select concepts of subsea processing plants for oil and natural gas fields, using information available in the literature as well as support from specialists in subsea technology and integrated production modelling. Higher drawdown in producer wells is a potential consequence of the use of subsea processing, therefore it may positively impact the production profile. As a consequence, an integrated approach comprising all the studies necessary to assess the flow between the initial sources and the final destinations is necessary to propose a selection methodology. As an alternative to overcome the lack of integrated studies comparing different development solutions in offshore fields, information from four commercial developments that employed subsea processing was used to seek methodology validation. The results of these four case studies suggest that the methodology is valid, although it is not clear if such production developments would utilize all phases proposed / Mestrado / Explotação / Mestra em Ciências e Engenharia de Petróleo
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Mechanistic modeling, design, and optimization of alkaline/surfactant/polymer floodingMohammadi, Hourshad, 1977- 05 October 2012 (has links)
Alkaline/surfactant/polymer (ASP) flooding is of increasing interest and importance because of high oil prices and the need to increase oil production. The benefits of combining alkali with surfactant are well established. The alkali has very important benefits such as lowering interfacial tension and reducing adsorption of anionic surfactants that decrease costs and make ASP a very attractive enhanced oil recovery method provided the consumption is not too large and the alkali can be propagated at the same rate as a synthetic surfactant and polymer. However, the process is complex so it is important that new candidates for ASP be selected taking into account the numerous chemical reactions that occur in the reservoir. The reaction of acid and alkali to generate soap and its subsequent effect on phase behavior is the most crucial for crude oils containing naphthenic acids. Using numerical models, the process can be designed and optimized to ensure the proper propagation of alkali and effective soap and surfactant concentrations to promote low interfacial tension and a favorable salinity gradient. The first step in this investigation was to determine what geochemical reactions have the most impact on ASP flooding under different reservoir conditions and to quantify the consumption of alkali by different mechanisms. We describe the ASP module of UTCHEM simulator with particular attention to phase behavior and the effect of soap on optimum salinity and solubilization ratio. Several phase behavior measurements for a variety of surfactant formulations and crude oils were successfully modeled. The phase behavior results for sodium carbonate, blends of surfactants with an acidic crude oil followed the conventional Winsor phase transition with significant three-phase regions even at low surfactant concentrations. The solubilization data at different oil concentrations were successfully modeled using Hand's rule. Optimum salinity and solubilization ratio were correlated with soap mole fractions using mixing rules. New ASP corefloods were successfully modeled taking into account the aqueous reactions, alkali/rock interactions, and the phase behavior of soap and surfactant. These corefloods were performed in different sandstone cores with several chemical formulations, crude oils with a wide range of acid numbers, brine with a wide range of salinities, and a wide range of temperatures. 2D and 3D sector model ASP simulations were performed based on field data and design parameters obtained from coreflood history matches. The phenomena modeled included aqueous phase chemical reactions of the alkaline agent and consequent consumption of alkali, the in-situ generation of surfactant by reaction with the acid in the crude, surfactant/soap phase behavior, reduction of surfactant adsorption at high pH, cation exchange with clay, and the effect of co-solvent on phase behavior. Sensitivity simulations on chemical design parameters such as mass of surfactant and uncertain reservoir parameters such as kv/kh ratio were performed to provide insight as the importance of each of these variables in chemical oil recovery. Simulations with different permeability realizations provided the range for chemical oil recoveries. This study showed that it is very important to model both surface active components and their effect on phase behavior when doing mechanistic ASP simulations. The reactions between the alkali and the minerals in the formation depend very much on which alkali is used, the minerals in the formation, and the temperature. This research helped us increase our understanding on the process of ASP flooding. In general, these mechanistic simulations gave insights into the propagation of alkali, soap, and surfactant in the core and aid in future coreflood and field scale ASP designs. / text
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