Mechanisms of Heavy Oil Recovery by Low Rate Waterflooding

Mai, A.; Kantzas, Apostolos

doi:10.2118/134247-pa

Cited by 30 publications

(22 citation statements)

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“…Despite the fact that some W/O emulsions were shown to have formed, and these are often indicative of an oil wet condition (Equation 1), the total water geometric mean T 2 values (T 2gm ) plotted in Figure 8 are still lower than the T 2gm of the original water-saturated core. This indicates that the rock was still water wet, and was verified through oil recovery via water imbibition 39 . Figure 9 shows the NMR spectra at the same four length locations after flooding one pore volume of DI AS solution through the core at a relatively high rate (0.51 m/day).…”

Section: Wettability Changes During As Floodingmentioning

confidence: 70%

“…In fact, the optimal oil recoveries were around 70% of OOIP, and most floods actually recovered less oil. Under very low rate waterflooding for many pore volumes 3,39 , it is also possible to achieve similar residual oil saturation by allowing water imbibition to slowly sweep oil from the core. Therefore, as also observed previously by Jennings et al 24 , the improved oil response is one of improved sweep and accelerated oil production.…”

Section: Oil Recovery Through DI As Injection At Various Ratesmentioning

confidence: 99%

“…The interpretation of wettability from NMR spectra has been developed previously in the analysis of imbibition during heavy oil waterflooding 39,43 . Figure 13 shows the range of T 2 values for water located in various different physical locations in the porous media.…”

Section: Wettability Changes During As Floodingmentioning

confidence: 99%

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Investigation into the Processes Responsible for Heavy Oil Recovery by Alkali-Surfactant Flooding

Bryan

Thuy

Kantzas

2008

SPE Symposium on Improved Oil Recovery

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This paper describes a suite of alkali-surfactant (AS) floods that were performed in systems containing viscous heavy oil (11,500 mPa⋅s). The study investigates how AS injection can be used to generate oil and water emulsions, which can in turn lead to improved sweep efficiencies and oil recovery. Data is obtained from core flooding, with in-situ saturation measurements made using low field NMR. This work is applicable to the many heavy oil reservoirs in countries like Canada and Venezuela that contain viscous oil that still has some limited mobility under reservoir conditions. In previous studies, improved oil recovery compared to waterflooding was observed. This work provides additional information that can be used to better understand how chemical injection can lead to oil recovery.The core floods in this study indicate that emulsification is most efficient when used to block pre-formed water channels and improve the sweep efficiency of the flood. Both O/W and W/O emulsions may form in the same system, even under controlled salinity conditions. The re-distribution of water from the flooded channels into emulsified droplets in the oil is at least partially responsible for the pressure increase seen in these systems. W/O emulsification is accompanied by wettability alteration, as evidenced by the NMR spectra obtained. After the chemical flood is completed, it may be possible to restore the original water wet condition of the rock, which can provide potential for future non-thermal improved oil recovery.

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Section: Wettability Changes During As Floodingmentioning

confidence: 70%

Section: Oil Recovery Through DI As Injection At Various Ratesmentioning

confidence: 99%

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Investigation into the Processes Responsible for Heavy Oil Recovery by Alkali-Surfactant Flooding

Bryan

Thuy

Kantzas

2008

SPE Symposium on Improved Oil Recovery

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“…( and alkali, 8-14 low-rate waterflooding, 15 variable-rate waterflooding, 16 immiscible CO 2 flooding, 17 miscible CO 2 flooding, 18 and water-alternating-CO 2 injection. 10, 19,20 Among the suggested methods, a miscible gas injection process and, in particular, VAPEX suffers from low initial production rates, premature breakthrough, and possible formation damage due to in situ deasphalting.…”

Section: Introductionmentioning

confidence: 99%

Analysis and Correlations of Viscous Fingering in Low-Tension Polymer Flooding in Heavy Oil Reservoirs

Jamaloei¹,

Kharrat²,

Torabi³

2010

Energy Fuels

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Low-tension polymer flooding (LTPF) can be an alternative for improving the recovery from some problematic heavy oil reservoirs, especially thin formations, where thermal methods face some challenges. A major technical challenge in LTPF is that a fingered displacement front may occur. Therefore, it is important to predict the nature of instability, to avoid viscous fingering, or, where it is inevitable, to be capable of including it as an additional factor in modeling displacement. Previous experiments of viscous fingering in immiscible displacements have been conducted in the presence of high permeabilities and linear displacement schemes. The question is whether previous findings are valid in displacement schemes similar to oil-field patterns (e.g., five-spot) in which one should deal with varying velocity profiles from injector(s) to producer(s). Hence, the effect of dispersion caused by varying velocity profiles has not been tested completely on viscous fingering. To help understand viscous fingering in LTPF in heavy oil reservoirs and to overcome the aforementioned limitations, we conducted experiments in relatively low-permeability, one-quarter, five-spot patterns. Foremost parameters, including oil recoveries at different times to breakthrough, pressure drops, cumulative saturation profiles, mean local saturations, finger lengths and widths, the dynamic level of bypassing, the dynamic population of fingers, the rate of growth of the population of fingers, and the number frequency of the fingers, were measured. We have correlated some of these parameters with the displacement time and front position. In summary, three distinct regions were identified for the viscous fingering patterns: onset of fingering, spreading phase, and end of sideways growth. The results also show that the finger width is comparable with the pore size and the fingerlike instabilities exist both in front of and behind the unstable front. Furthermore, the dynamic population of the macrofingers is well correlated with the square root of the time, and the profile of mean local oil saturation versus traveled distance is almost linear. Finally, the sharpest increase in the rate of growth of the finger population versus dimensionless pressure drop is accompanied with the sharpest pressure drop occurring at the onset of fingering and axial finger propagation during the early stages. A subsequent relatively uniform trend of the pressure drop versus time occurs during the spreading phase. Analysis of the experimentally observed fingering patterns of LTPF in this study is the most detailed interpretation performed to date, which provides new insight into the onset of fingering and finger development.

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“…Torabi et al [42] predicted heavy oil/water relative permeability by modified Corey-based correlations. Mai [43] reported that Johnson-Bossler-Naumann (JBN) method allowed for the calculation of apparent relative permeability curves that could be incorporated into reservoir simulators, and the effect of oil viscosity could be addressed through its effect on the apparent relative permeabilities calculated. Doorwar et al [44] considered that relative permeability functions needed to be modified to simulate unstable displacements with conventional simulators, and high viscosity ratio led to viscous fingering, which affected the observed relative permeability curves; they developed a lumped-finger model to modify multiphase flow equations and to yield pseudo relative permeability functions that accounted for viscous fingering.…”

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confidence: 99%

Non-Newtonian Flow Characteristics of Heavy Oil in the Bohai Bay Oilfield: Experimental and Simulation Studies

Xin

et al. 2017

Energies

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Abstract:In this paper, physical experiments and numerical simulations were applied to systematically investigate the non-Newtonian flow characteristics of heavy oil in porous media. Rheological experiments were carried out to determine the rheology of heavy oil. Threshold pressure gradient (TPG) measurement experiments performed by a new micro-flow method and flow experiments were conducted to study the effect of viscosity, permeability and mobility on the flow characteristics of heavy oil. An in-house developed novel simulator considering the non-Newtonian flow was designed based on the experimental investigations. The results from the physical experiments indicated that heavy oil was a Bingham fluid with non-Newtonian flow characteristics, and its viscosity-temperature relationship conformed to the Arrhenius equation. Its viscosity decreased with an increase in temperature and a decrease in asphaltene content. The TPG measurement experiments was impacted by the flow rate, and its critical flow rate was 0.003 mL/min. The TPG decreased as the viscosity decreased or the permeability increased and had a power-law relationship with mobility. In addition, the critical viscosity had a range of 42-54 mPa·s, above which the TPG existed for a given permeability. The validation of the designed simulator was positive and acceptable when compared to the simulation results run in ECLIPSE V2013.1 and Computer Modelling Group (CMG) V2012 software as well as when compared to the results obtained during physical experiments. The difference between 0.0005 and 0.0750 MPa/m in the TPG showed a decrease of 11.55% in the oil recovery based on the simulation results, which demonstrated the largely adverse impact the TPG had on heavy oil production.

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Mechanisms of Heavy Oil Recovery by Low Rate Waterflooding

Cited by 30 publications

References 0 publications

Investigation into the Processes Responsible for Heavy Oil Recovery by Alkali-Surfactant Flooding

Investigation into the Processes Responsible for Heavy Oil Recovery by Alkali-Surfactant Flooding

Analysis and Correlations of Viscous Fingering in Low-Tension Polymer Flooding in Heavy Oil Reservoirs

Non-Newtonian Flow Characteristics of Heavy Oil in the Bohai Bay Oilfield: Experimental and Simulation Studies

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