Experimental Study of Blending CO 2 with Triethyl Citrate for Mitigating Gravity Override During Reservoir Flooding
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RESEARCH ARTICLE-PETROLEUM ENGINEERING
Experimental Study of Blending CO2 with Triethyl Citrate for Mitigating Gravity Override During Reservoir Flooding Khaled H. Al-Azani1 · Sidqi A. Abu-Khamsin1
· Abdullah S. Sultan1
Received: 29 May 2020 / Accepted: 18 August 2020 © King Fahd University of Petroleum & Minerals 2020
Abstract Challenges during CO2 flooding of oil reservoirs are mobility control and gravity override caused, respectively, by lower viscosity and density of CO2 compared with reservoir fluids. Blocking agents such as foam, cross-linked polymers and gels have been tested. However, such techniques are more effective in preventing fingering and blocking thief zones than reducing gravity override. Moreover, no foaming agent has been identified to withstand the high temperatures and salinities of some reservoirs. This experimental study investigates the use of triethyl citrate (TEC) as a densifying agent to blend with supercritical CO2 (scCO2 ) to minimize gravity override. High-permeability, Indiana limestone core samples saturated with either dead or live light crude oils at irreducible water saturations were flooded vertically upward at 24.132 MPa and 100 °C with about one pore volume of either pure scCO2 or a scCO2 –TEC blend of 0.15 mol fraction (0.525 mass fraction) TEC. At breakthrough, scCO2 flooding of dead oil recovered 14.82% of the initial oil in place, while the blend flood recovered 31.99%. At 1 PV, the scCO2 flood recovered 60.14%, while the blend flood recovered 72.67%. The live-oil-saturated core samples produced similar results but with generally lower oil recoveries. At 1 PV of fluid injected, all floods reduced the oil saturation to levels lower than the residual oil saturation achieved with water flooding. With TEC’s low solubility in both crude oil and water, blending scCO2 with TEC is, thus, a technically viable method to mitigate gravity override in CO2 –EOR process. Keywords CO2 –EOR · Gravity override · CO2 sequestration · Core flooding
Abbreviations API IOIP P PV R TDS
American Petroleum Institute Initial oil in place (cm3 ) Pressure (MPa) Pore volume (cm3 ) Solution gas–oil ratio (cm3 /cm3 ) Total dissolved solids, parts per million
ρ Density (g/cm3 )
Subscripts b sat o w
At the oil’s bubble point At a mixture’s saturation conditions Oil Water
Greek Letters γ Specific gravity μ Viscosity (cP)
B 1
Sidqi A. Abu-Khamsin [email protected] Department of Petroleum Engineering, King Fahd University of Petroleum and Minerals, KFUPM, Box 652, Dhahran 31261, Saudi Arabia
1 Introduction Carbon dioxide is an effective agent of oil displacement for enhanced oil recovery (EOR) purposes [1, 2]. By dissolving in the oil, CO2 swells the oil, reduces its viscosity and lowers its interfacial tension with water. Furthermore, compared with other gases, namely nitrogen and methane, CO2 can achieve miscibility with oil at much lower pressures that are usually close to reservoir conditions [3]. Under miscible
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Arabian Journal for Science and Engineering 0.12
0.8
H2S CO2 N2 CH4
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