Development of Heavy Oil Fractured Carbonate Bati Raman Field: Evaluation of Steam Injection Potential and Improving Ongoing CO2 Injection

Babadagli, Tayfun; Sahin, Secaeddin; Kalfa, Ülker; Çelebioğlu, Demet; Karabakal, U.; Topguder, Nazan Necibe Senol

doi:10.2118/115400-ms

Cited by 19 publications

(11 citation statements)

References 33 publications

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“…In fact, as seen in Fig. 6, all surfactant cases followed a similar trend of recovery, but NaOH revealed less preliminary recovery and then a razor-sharp increase, which could be an evidence of wettability change eventually yielding a higher capillary imbibitions recovery than any other surfactants (Babadagli et al 2008(Babadagli et al , 2009.…”

Section: Chemically Improved Wag Applicationmentioning

confidence: 68%

“…But concentration of additive was slightly increased taking into account the effect of chemical retention and the field pilot was started in 2010. Recognizing through the lab tests that the wettability alteration by NaOH is not an immediate process, the field response is projected to be relatively slow (Babadagli et al 2008(Babadagli et al , 2009). The pH, liquid level and production data were recorded frequently at the neighboring wells.…”

Section: Chemically Improved Wag Applicationmentioning

confidence: 99%

“…At this stage, steam injection is an inevitable alternative for field wide development of the Bati Raman field since thermal diffusion is nearly five times faster than mass diffusion and this makes thermal applications much more favorable in terms of matrix oil recovery from heavy-oil fractured carbonates (Babadagli et al 2008(Babadagli et al , 2009. Although, the heterogeneous structure that causes early breakthrough of injected steam and uneven distribution of the heat is the main challenge in steam injection in carbonates, it is still measured as the only viable course of action for heavy-oil recovery even in challenging circumstances.…”

Section: Plans Aheadmentioning

confidence: 99%

“…5-spot pilot performed in the field in 1969 showed that the displacement type injection in this kind of fractured reservoirs is not feasible. Therefore, it was recommended to use steam as a heating agent rather than a displacement fluid (Babadagli, et al 2008(Babadagli, et al , 2009. Injection of steam into formation from top to heat the reservoir (crestal injection) using vertical communication towards the bottom is an alternative to enhance gravity drainage as suggested earlier (Shahin et al2006;Snell and Close 1999).…”

Section: Plans Aheadmentioning

confidence: 99%

“…Through an analytical modeling exercise, with 4200 ft. depth 1,000 cold water equivalent (CWE) B/D steam injection was found to be an optimal value yielding a steam quality of 0.4 at the crest of the reservoir. Since the rate is the most critical factor on the heat loss and steam quality, half of the suggested optimal rate (500 CWE B/D) gave only 0.05% steam quality (Babadagli et al 2008(Babadagli et al , 2009. With the improving technology of the vacuum insulated double walled tubular products that reduces heat transfer loss, it is considered that the drawback of depth for steam quality in the Bati Raman field can be minimized (Lombard 2008).…”

Section: Plans Aheadmentioning

confidence: 99%

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A Quarter Century of Progress in the Application of CO2 Immiscible EOR Project in Bati Raman Heavy Oil Field in Turkey

Sahin¹,

Kalfa²,

Çelebioğlu³

et al. 2012

All Days

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The Bati Raman field is the largest oil field in Turkey containing approximately 1.85 billion barrels of initial oil in place at an average depth of 4300 ft. The oil is heavy (12 o API) with high viscosity and low solution gas. Primary recovery between 1961 and 1986 was less than 2% of OOIP.The commercial CO 2 -EOR project began in 1986 and is still active. With the implementation of the CO 2 flood, the recovery is expected to potentially reach up to 10% of OOIP.The reservoir rock is naturally fractured carbonate where the heterogeneities and the unfavorable mobility ratio of CO 2 and crude caused inefficient sweep. The solubility of CO 2 in the oil, which is highly sensitive to reservoir operating pressure, was a significant factor for the success of the CO 2 flood. Currently, the injected agent is increasingly bypassing the remaining oil and the production is curtailed by excessive high gas/oil ratio (GOR) severely jeopardizing recovery. These conditions prompted the use of applications of the conformance-improvement systems in the wells in western part of the field.Successful applications of fracture plugging polymer gel system intended for the conformance improvement were carried out in the years of 2002 and 2004. Also, to improve the recovery by a better sweep (or displacement), a chemically augmented water injection process was proposed in the areas having relatively lower reservoir pressure. Chemicals were tested for wettability alteration and IFT reduction to select the best performing ones. After an economic analysis, a field trial of the water alternating gas (WAG) injection process with caustic was put into progress in 2010.Optimized application cases were determined by tuning the total gas injection rates of the field, proration of the individual well rates according to the GOR, investigation of infill drilling, and alteration of the gas injection pattern, based on the results of the simulations carried out in different time frames of the project history.The Bati Raman immiscible CO 2 injection project has been acknowledged as one of the most unique and successful enhanced oil recovery (EOR) applications in the history of fractured heavy-oil carbonate reservoirs. This paper presents a comprehensive overview of this project after a quarter century of experience. IntroductionBased on its in-situ gravity of 12º API and viscosity of 600 cp, the Bati Raman oil is classified as extra heavy. Due to adverse oil properties (12º API viscosity of 600 cp, and low solution gas), low reservoir energy and heterogeneity caused by naturally fractured and vuggy structure, only 1.7 percent of the OOIP corresponding to 32 million STB, was produced prior to CO 2 application. All primary recovery was due to fluid and rock expansion. With a drastic drop of pressure in reservoir after a short period of time the effect of solution gas drive was dwindled. Hence supplemental recovery through EOR was called for. Water drive resulted in insignificant additional oil; consequently, the field was extensively studied for an efficient...

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Section: Chemically Improved Wag Applicationmentioning

confidence: 68%

Section: Chemically Improved Wag Applicationmentioning

confidence: 99%

Section: Plans Aheadmentioning

confidence: 99%

Section: Plans Aheadmentioning

confidence: 99%

Section: Plans Aheadmentioning

confidence: 99%

See 3 more Smart Citations

A Quarter Century of Progress in the Application of CO2 Immiscible EOR Project in Bati Raman Heavy Oil Field in Turkey

Sahin¹,

Kalfa²,

Çelebioğlu³

et al. 2012

All Days

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A review of development methods and EOR technologies for carbonate reservoirs

et al. 2020

Pet. Sci.

178

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Carbonate reservoirs worldwide are complex in structure, diverse in form, and highly heterogeneous. Based on these characteristics, the reservoir stimulation technologies and fluid flow characteristics of carbonate reservoirs are briefly described in this study. The development methods and EOR technologies of carbonate reservoirs are systematically summarized, the relevant mechanisms are analyzed, and the application status of oil fields is catalogued. The challenges in the development of carbonate reservoirs are discussed, and future research directions are explored. In the current development processes of carbonate reservoirs, water flooding and gas flooding remain the primary means but are often prone to channeling problems. Chemical flooding is an effective method of tertiary oil recovery, but the harsh formation conditions require high-performance chemical agents. The application of emerging technologies can enhance the oil recovery efficiency and environmental friendliness to a certain extent, which is welcome in hard-to-recover areas such as heavy oil reservoirs, but the economic cost is often high. In future research on EOR technologies, flow field control and flow channel plugging will be the potential directions of traditional development methods, and the application of nanoparticles will revolutionize the chemical EOR methods. On the basis of diversified reservoir stimulation, combined with a variety of modern data processing schemes, multichannel EOR technologies are being developed to realize the systematic, intelligent, and cost-effective development of carbonate reservoirs.

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