Steam-Foam Assessment Using Native Cores from the Ratqa Lower Fars RQLF Heavy Oil Reservoir in Kuwait to De-Risk Field-Scale Deployment

Steam-foam has been used extensively in field trials to improve steam conformance, both for cyclic steam injection and steam flood. It is a proven process and very useful lessons can be drawn from these field trials to plan new projects. However, foam has not yet been used to improve SAGD (Steam-Assisted Gravity Drainage) performances. The aim of this paper is to examine the reasons for this situation and discuss the practical aspects of Foam-Assisted SAGD (FA-SAGD). After a thorough description of the main mechanisms involved in these processes (steam-foam for cyclic steam injection and steam flood, as well as foam for SAGD), this paper proposes to review the differences between the various processes and their implications for the design and implementation of FA-SAGD. Finally, based on the lessons drawn from all the documented steam-foam trials, potential and drawbacks of FA-SAGD are presented together with suggested roadmaps to address these remaining and newly identified challenges to make this technology come true. By definition, the driving mechanism of SAGD relies on gravity and involves the use of a pair of horizontal wells drilled a few meters apart, one on top of the other. This is completely different from foam applications with both cyclic steam injection and steam flood, which are typically conducted with vertical wells; in addition, cyclic steam relies on single wells only whereas steam flood is essentially a lateral displacement process. Steam quality, injection velocity, proximity of the injection and production wells and the risks associated with the formation of emulsions in the surface facilities are some of the issues that are typically not problematic for foam with conventional steam processes, but which need to be considered before FA-SAGD can be implemented in the field. This work concludes that FA-SAGD is feasible but that ignoring any of these aspects would very likely cause the process to fail in the field. This study will provide useful physical considerations on the steam-foam process along with detailed guidelines for the implementation of the Foam-Assisted SAGD process in the field. It will be useful for engineers that are considering foam to improve the performances of SAGD by targeting a reduction of the steam consumption or the Steam Oil Ratio.

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Enhanced Oil Recovery in Naturally Fractured Reservoirs: State of the Art and Future Perspectives

Delamaide¹,

Batôt

Alshaqsi³

et al. 2022

Day 2 Tue, March 22, 2022

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In Naturally Fractured Reservoirs (NFRs), production rate quickly drops once the oil in the fractures is produced. Indeed, high connectivity of the fracture network soon requires the application of IOR/EOR methods to unlock production from the low permeability matrix blocks which bear the major part of the oil in most carbonate-NFRs. This paper is intended as a thorough review of the EOR field tests in such reservoirs and discussion of the physical mechanisms at stakes. To the best of our knowledge there has never been any review dedicated to EOR methods specifically applied to NFRs. After a description of the main mechanisms involved in these processes this paper proposes to revisit the EOR field tests performed in carbonate-NFRs based on the following technologies: Gas injection, thermal- and solvent-assisted production, and finally chemical EOR, the latter being seen as a way to improve the kinetic of oil recovery from the matrix: foam, surfactant-polymer, low-salinity and hybrid processes, including a discussion of the remaining challenges to successfully apply these more recent technologies in the field. Beyond the fact that NFRs are quite interesting because of their complexity, they account for a large part of the world's oil proven reserves, approximatively 20%. Even though this value should be taken with caution, as it depends on the NFRs definitions and their characterizations, there are clearly significant amounts of oil trapped inside these reservoirs. For that reason, they are of great interest, both in terms of understanding and economical consideration for oil companies willing to get the most out of their fractured fields. Even when based on sound static and dynamic characterizations, production optimization of NFRs remains challenging: classical flooding mainly produces the oil contained in the fractures during the early stages of the field development. The high connectivity of the different levels of the fracture network along with the low permeability of the oil-bearing matrix blocks, combined with the often oil-wet nature of carbonate formations, are the three main factors at plays preventing the production of the remaining oil from the matrix blocks. Design of dedicated EOR solutions are needed and learning from past experiences through the review and analyze of the past field trials is of great value to that purpose. This review and discussion will allow engineers to get an extended and up to date understanding of the features and drawbacks of the main EOR methods which could be applied to NFRs, and also provide some guidance in the selection or design of the best suited EOR solution to a specific naturally fracture carbonate field.

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Steam-Foam Assessment Using Native Cores from the Ratqa Lower Fars RQLF Heavy Oil Reservoir in Kuwait to De-Risk Field-Scale Deployment

Cited by 3 publications

References 7 publications

An experimental investigation of surfactant structure–property relationship for foam mobility control in thermal EOR processes

An experimental investigation of surfactant structure–property relationship for foam mobility control in thermal EOR processes

Practical Aspects of Foam-Assisted SAGD

Enhanced Oil Recovery in Naturally Fractured Reservoirs: State of the Art and Future Perspectives

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