Author: Alfredo Arriola Torres
Publisher:
ISBN:
Category : Capillarity
Languages : fr
Pages : 656
Book Description
An Experimental Study of the Effects of Viscous and Capillary Forces on the Trapping and Mobilization of Oil Drops in Capillary Constrictions
Author: Alfredo Arriola Torres
Publisher:
ISBN:
Category : Capillarity
Languages : fr
Pages : 656
Book Description
Publisher:
ISBN:
Category : Capillarity
Languages : fr
Pages : 656
Book Description
An Experimental Study of the Effects of Viscous and Capillary Forces on the Trapping and Mobilization of Oil Drops in Capillary Constrictions
Author: Alfredo Arriola Torres
Publisher:
ISBN:
Category : Capillarity
Languages : en
Pages : 538
Book Description
Publisher:
ISBN:
Category : Capillarity
Languages : en
Pages : 538
Book Description
Society of Petroleum Engineers Journal
Author: Society of Petroleum Engineers of AIME.
Publisher:
ISBN:
Category : Petroleum engineering
Languages : en
Pages : 1004
Book Description
Publisher:
ISBN:
Category : Petroleum engineering
Languages : en
Pages : 1004
Book Description
Transactions of the Society of Petroleum Engineers
Author:
Publisher:
ISBN:
Category : Petroleum engineering
Languages : en
Pages : 2162
Book Description
Publisher:
ISBN:
Category : Petroleum engineering
Languages : en
Pages : 2162
Book Description
Experimental Research on Multiphase Liquid Mobilization and Motion in Capillary and Micro Models Subjected to External Low Frequency Vibratory Excitations
Author: Yihe Zhang
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
Book Description
The research of this dissertation experimentally investigates the impacts of external vibratory excitation on the mobilization and motion of multiphase liquid in capillary and microcell models, aiming for understanding the mechanism of oil-water mobilization and flow in pore structures subjected to external excitations. Experiments with capillary models are first conducted; in which both straight capillary and curved capillary models are employed as an analogue of the pore structures. The mobilization and motion of an oil slug trapped in the capillary models with capillary forces are studied in the research. The models considered are subjected to both external pressures created by water injection and vibratory excitations. The focuses of the experimental investigations are on the variation of the pressure drop across the capillary model, the oil slug travel distance in the model in a fixed time duration, and the flow phenomena during the period of mobilization and flow of the oil slug. It is found in the investigations, in comparing the situations of with and without external excitations, proper vibratory excitations may positively affect the mobilization and flow of the oil slug in the capillary models, in terms of reducing the external pressure needed for mobilizing the oil slug, stabilizing the flow of the oil slug and increasing the oil slug travel distance in a fixed duration. The joint effects of the external pressure and vibratory excitation on the mobilization and flow of the oil slug are measured and quantified in the research. The optimal conditions in terms of external pressure and vibration frequency and amplitude for promoting the oil slug mobilization and stable flow are also searched and determined via the experiments of the research. Two-dimensional micro model are more close to the pore structures of the reservoir in oil field. To study the motion of oil-water liquid in a two-dimensional manner, an etched glass micro model is designed and employed in the research to study the liquid mobilization and flow in a network pore structure. The intention of this study is to understand the mechanism of the external water pressure and vibratory excitation on oil recovery from liquid saturated porous media of a reservoir. Experiments without vibratory excitation are first conducted on the model and various phenomena are observed in the experiments, including the development of water film and water patches surrounding the oil droplets and oil patches, and the variations of the contact angles of the oil droplets. The experimental investigations with application of vibration excitation fall in two categories: oil displacement by applying vibration excitation after waterflooding and oil displacement by applying vibration excitation with waterflooding. The oil-displacing rate, oil-water distribution, and pressure drop are measured during the oil displacement. The fractional flow is calculated and analyzed. From the experimental results, it can be concluded that applying vibration excitation has positive effects on the oil displacement in terms of increasing the total oil-displacing rate in the micro model flow. The effect is much more noticeable when the oil-water ratio is high. Also, the efficiency of the oil recovery is found sensitive to the acceleration amplitude of the vibration excitation. By comparing the final oil-displacing rate, it is found that applying vibration excitation after waterflooding is more effective in comparing with that applying vibration excitation together with waterflooding.
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
Book Description
The research of this dissertation experimentally investigates the impacts of external vibratory excitation on the mobilization and motion of multiphase liquid in capillary and microcell models, aiming for understanding the mechanism of oil-water mobilization and flow in pore structures subjected to external excitations. Experiments with capillary models are first conducted; in which both straight capillary and curved capillary models are employed as an analogue of the pore structures. The mobilization and motion of an oil slug trapped in the capillary models with capillary forces are studied in the research. The models considered are subjected to both external pressures created by water injection and vibratory excitations. The focuses of the experimental investigations are on the variation of the pressure drop across the capillary model, the oil slug travel distance in the model in a fixed time duration, and the flow phenomena during the period of mobilization and flow of the oil slug. It is found in the investigations, in comparing the situations of with and without external excitations, proper vibratory excitations may positively affect the mobilization and flow of the oil slug in the capillary models, in terms of reducing the external pressure needed for mobilizing the oil slug, stabilizing the flow of the oil slug and increasing the oil slug travel distance in a fixed duration. The joint effects of the external pressure and vibratory excitation on the mobilization and flow of the oil slug are measured and quantified in the research. The optimal conditions in terms of external pressure and vibration frequency and amplitude for promoting the oil slug mobilization and stable flow are also searched and determined via the experiments of the research. Two-dimensional micro model are more close to the pore structures of the reservoir in oil field. To study the motion of oil-water liquid in a two-dimensional manner, an etched glass micro model is designed and employed in the research to study the liquid mobilization and flow in a network pore structure. The intention of this study is to understand the mechanism of the external water pressure and vibratory excitation on oil recovery from liquid saturated porous media of a reservoir. Experiments without vibratory excitation are first conducted on the model and various phenomena are observed in the experiments, including the development of water film and water patches surrounding the oil droplets and oil patches, and the variations of the contact angles of the oil droplets. The experimental investigations with application of vibration excitation fall in two categories: oil displacement by applying vibration excitation after waterflooding and oil displacement by applying vibration excitation with waterflooding. The oil-displacing rate, oil-water distribution, and pressure drop are measured during the oil displacement. The fractional flow is calculated and analyzed. From the experimental results, it can be concluded that applying vibration excitation has positive effects on the oil displacement in terms of increasing the total oil-displacing rate in the micro model flow. The effect is much more noticeable when the oil-water ratio is high. Also, the efficiency of the oil recovery is found sensitive to the acceleration amplitude of the vibration excitation. By comparing the final oil-displacing rate, it is found that applying vibration excitation after waterflooding is more effective in comparing with that applying vibration excitation together with waterflooding.
Proceedings of the Fourth Tertiary Oil Recovery Conference, Wichita, Kansas, March 4-6, 1981
Author:
Publisher:
ISBN:
Category : Oil fields
Languages : en
Pages : 140
Book Description
Descriptors: enhanced recovery of oil, oil recovery, tertiary recovery of oil.
Publisher:
ISBN:
Category : Oil fields
Languages : en
Pages : 140
Book Description
Descriptors: enhanced recovery of oil, oil recovery, tertiary recovery of oil.
American Doctoral Dissertations
Author:
Publisher:
ISBN:
Category : Dissertation abstracts
Languages : en
Pages : 604
Book Description
Publisher:
ISBN:
Category : Dissertation abstracts
Languages : en
Pages : 604
Book Description
An Attempt to Test the Theories of Capillary Action by Comparing the Theoretical and Measured Forms of Drops of Fluid
Author: Francis Bashforth
Publisher:
ISBN:
Category : Capillarity
Languages : en
Pages : 160
Book Description
Publisher:
ISBN:
Category : Capillarity
Languages : en
Pages : 160
Book Description
Mobilization and Flow of Multiple Oil Slugs in Water Saturated Capillary Models
Author: Alexandre Guitierry Melo de Oliveira
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
Book Description
This research aims to investigate the mobilization and flow of Multi-Oil Slugs (MOS) inside capillary models saturated with water, attempting to understand the mechanism on how single oil slug (SOS) and MOS inside the capillary models are mobilized and stabilized inflow under static external pressure. The mobilization and stabilization pressures required for MOS in the models are quantified under various experimental conditions with different numbers of oil slugs. The oil slugs are all found experiencing the following patterns of state in the mobilization and flow stabilization: rest slowly increased pressure dramatically increased pressure motion impending unstable flow stabilized flow. The influences of the number of oil slugs on the pressure increasing rate and maximum pressure for mobilizing the oil slugs together with the flow stabilization rate of the oil slugs and stabilization pressure are studied thoroughly. An analysis comparing the pressure drop and the oil slugs travelling displacements are also carried out for the cases of one, two, and three oil slugs. An investigation of the effects of the water film and effects of contact angles of the oil slugs are taken into consideration in relating to the mobilization and flow stabilization of SOS and MOS. The research results indicate with experimental evidence that the maximum pressure required to mobilize the oil slugs and stabilize the oil slugs flow in a capillary model increases with the increase of the number of oil slugs. The time required to mobilize the oil slugs and stabilize their flow also increases with the increase in the number of oil slugs. The research provides a guide for comprehending mobilization and flow mechanism of MOS subjected to static pressure and capillary force. Outcomes found in the research combined with further analysis of MOS could potentially be beneficial to water flooding research in petroleum engineering and oil production with water flooding techniques in industrial practices.
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
Book Description
This research aims to investigate the mobilization and flow of Multi-Oil Slugs (MOS) inside capillary models saturated with water, attempting to understand the mechanism on how single oil slug (SOS) and MOS inside the capillary models are mobilized and stabilized inflow under static external pressure. The mobilization and stabilization pressures required for MOS in the models are quantified under various experimental conditions with different numbers of oil slugs. The oil slugs are all found experiencing the following patterns of state in the mobilization and flow stabilization: rest slowly increased pressure dramatically increased pressure motion impending unstable flow stabilized flow. The influences of the number of oil slugs on the pressure increasing rate and maximum pressure for mobilizing the oil slugs together with the flow stabilization rate of the oil slugs and stabilization pressure are studied thoroughly. An analysis comparing the pressure drop and the oil slugs travelling displacements are also carried out for the cases of one, two, and three oil slugs. An investigation of the effects of the water film and effects of contact angles of the oil slugs are taken into consideration in relating to the mobilization and flow stabilization of SOS and MOS. The research results indicate with experimental evidence that the maximum pressure required to mobilize the oil slugs and stabilize the oil slugs flow in a capillary model increases with the increase of the number of oil slugs. The time required to mobilize the oil slugs and stabilize their flow also increases with the increase in the number of oil slugs. The research provides a guide for comprehending mobilization and flow mechanism of MOS subjected to static pressure and capillary force. Outcomes found in the research combined with further analysis of MOS could potentially be beneficial to water flooding research in petroleum engineering and oil production with water flooding techniques in industrial practices.
An Attempt to Test the Theories of Capillary Action
Author: Francis Bashforth
Publisher:
ISBN:
Category : Capillarity
Languages : en
Pages : 158
Book Description
Publisher:
ISBN:
Category : Capillarity
Languages : en
Pages : 158
Book Description