Modeling of Viscous Displacement in Dual-Porosity Naturally Fractured Reservoirs: Application to Surfactant Enhanced Oil Recovery

Kiani, Mojtaba; Alamdari, Baharak Barzegar; Kazemi, Hossein

doi:10.2118/169076-ms

Cited by 3 publications

(1 citation statement)

References 22 publications

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“…They might result in more oil recovery and a delay in breakthroughs [21,22]. The viscous drive mechanisms can assist the oil displacement from the matrix due to substantial pressure gradients of fracture flow, particularly for chemical injection [23]. Water-alternating gas (WAG) injection, as a mobility control process, can improve sweep efficiency and oil recovery.…”

Section: Introductionmentioning

confidence: 99%

Performance Quantification of Enhanced Oil Recovery Methods in Fractured Reservoirs

2021

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The enhanced oil recovery mechanisms in fractured reservoirs are complex and not fully understood. It is technically challenging to quantify the related driving forces and their interaction in the matrix and fractures medium. Gravity and capillary forces play a leading role in the recovery process of fractured reservoirs. This study aims to quantify the performance of EOR methods in fractured reservoirs using dimensionless numbers. A systematic approach consisting of the design of experiments, simulations, and proxy-based optimization was used in this work. The effect of driving forces on oil recovery for water injection and several EOR processes such as gas injection, foam injection, water-alternating gas (WAG) injection, and foam-assisted water-alternating gas (FAWAG) injection was analyzed using dimensionless numbers and a surface response model. The results show that equilibrium between gravitational and viscous forces in fracture and capillary and gravity forces in matrix blocks determines oil recovery performance during EOR in fractured reservoirs. When capillary forces are dominant in gas injection, fluid exchange between fracture and matrix is low; consequently, the oil recovery is low. In foam-assisted water-alternating gas injection, gravity and capillary forces are in equilibrium conditions as several mechanisms are involved. The capillary forces dominate the water cycle, while gravitational forces govern the gas cycle due to the foam enhancement properties, which results in the highest oil recovery factor. Based on the performed sensitivity analysis of matrix–fracture interaction on the performance of the EOR processes, the foam and FAWAG injection methods were found to be more sensitive to permeability contrast, density, and matrix block highs than WAG injection.

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Section: Introductionmentioning

confidence: 99%

Performance Quantification of Enhanced Oil Recovery Methods in Fractured Reservoirs

2021

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New Approach for Using Surfactants to Enhance Oil Recovery from Naturally Fractured Oil-Wet Carbonate Reservoirs

Parra

Pope

Mejia

et al. 2016

Day 1 Mon, September 26, 2016

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Recent research indicates that even small viscous transverse pressure gradients can increase the rate of surfactant imbibition into the matrix of a fractured reservoir. However, surfactants are commonly tested using static imbibition cells without any imposed pressure gradient. Therefore, the effect of viscous pressure gradients was investigated by conducting a series of surfactant corefloods using fractured Silurian Dolomite and Texas Cream Limestone cores. The viscosity of the surfactant solution was increased by adding polymer or by changing the salinity of the aqueous surfactant solution, which affects the in-situ microemulsion viscosity. The fractured cores had a permeability contrast between the fracture and the matrix ranging from 2500 to 90,000. Non-fractured corefloods were also performed and compared with the fractured corefloods. The more viscous surfactant solutions achieved greater oil recovery from the fractured carbonate cores. These results indicate that a viscous microemulsion can serve as a mobility control agent in naturally fractured reservoirs (NFRs) that is analogous to mobility control with foams and polymers, but with less complexity and cost.

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The Modeling of the Viscous Drive in Oil-wet Naturally Fractured Reservoirs

Romero¹,

Behr²

2018

Day 3 Wed, June 13, 2018

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Recent experiments have shown that gels can promulgate the viscous drive recovery mechanism in fractured oil-wet matrix cores. The large viscosity of gels can increase the pressure gradient in the fractured network, generating higher local pressures in the fractures that can overcome the capillary entrance pressure of the oil-wet matrix. When that occurs, the water leaking-off from the gel invades the matrix and displaces the oil to the fractures, promoting the viscous drive as the dominant recovery mechanism. The goal of this research is to comprehend whether the viscous drive recovery mechanism could enhance the oil recovery in oil-wet NFR under realistic conditions and furthermore to determine the range of applicability. The laboratory tests executed by Brattekås et al. (2013), where the gel was injected at high velocity in the fracture provoking matrix invasion, allowed generating a conceptual model of the process that was adapted in a numerical reservoir simulator to reproduce the experiments. As a step forward, the lab-scale simulations are scaled up to field conditions to analyze the phenomenon in real reservoirs. Multiple simulations were performed to evaluate the influence of different parameters such as the gel viscosity, the velocity of injection and the matrix block size on the recovery rate and the ultimate recovery factor. The simulation results demonstrated on the one hand that in smaller matrix blocks higher values of velocity-viscosity are needed to initiate the process, and additionally the capillary end-effect significantly affects oil production. On the other hand, in the larger matrix blocks the recovery time is considerably longer and could be unrealistic for practical applications. The dimensionless criterion controlling this process is derived as the viscous-capillary ratio relating the differential pressure along the fracture to the capillary pressure of the oil-wet matrix. To provoke the matrix invasion by the viscous drive, this dimensionless number should overcome a critical value which was estimated for this study. The novelty of this work has a significant contribution for the EOR implementation in oil-wet NFR. It is demonstrated that the viscous drive recovery mechanism can have a strong contribution on oil recovery.

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Modeling of Viscous Displacement in Dual-Porosity Naturally Fractured Reservoirs: Application to Surfactant Enhanced Oil Recovery

Cited by 3 publications

References 22 publications

Performance Quantification of Enhanced Oil Recovery Methods in Fractured Reservoirs

Performance Quantification of Enhanced Oil Recovery Methods in Fractured Reservoirs

New Approach for Using Surfactants to Enhance Oil Recovery from Naturally Fractured Oil-Wet Carbonate Reservoirs

The Modeling of the Viscous Drive in Oil-wet Naturally Fractured Reservoirs

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