Effect of Wettability on Vaporization of Hydrocarbon Solvents in Capillary Media

Al-Kindi, Ilyas; Babadagli, Tayfun

doi:10.2118/201258-pa

Cited by 2 publications

(1 citation statement)

References 32 publications

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“…12,16,19 Obviously, the pore size is a vital factor affecting the EOR performance with the DC electric field. Due to the fact that micro/nanopores have a very large surface−volume ratio and the rapidly increasing contact area between fluids and rock affects fluid flow (significant boundary layer effects) on its surface, 17,20 wettability as a macroscopic reflection of solid−liquid interactions is particularly important for exploiting a tight oil reservoir. In practice, the positive correlation between reservoir hydrophilicity and capillarity can be used as a driving force to displace the nonwetting phase (oil) in the pores, 3,7 and the wetting phase adhering to the rock wall and forming a similar stationary boundary layer has a strong influence on the flow.…”

Section: Introductionmentioning

confidence: 99%

Laboratory Evaluation of Electrically Enhanced Oil Recovery in Tight Reservoirs

Jia,

Ning,

Lyu

et al. 2023

Energy Fuels

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By coupling the electrokinetic phenomenon, the direct current (DC) electric field has recently been considered as a novel process to enhance oil recovery over waterflooding. We conducted a series of coreflood experiments to evaluate the performance of electrically enhanced oil recovery in tight reservoirs and identify the key underlying mechanisms. Results show that the oil recovery induced by the DC electric field is higher than that of waterflooding. The oil recovery increases first and then decreases with the enhancement of the DC electric field. Using 0.05 mol/L NaCl solution with 10 V voltage, the highest oil recovery of 55.6% was increased by 28.4% compared with the average oil recovery (43.3%) of waterflooding. Not only does electroosmosis reduce the required pressure from 19.20 to 15.89 MPa with its variation proportional to the DC voltage and ion concentration but also such an electrochemical reaction changes the core mineral compositions (i.e., increasing the clay content but decreasing the orthoclase and calcite content), evidenced by a decrease in both contact angle up to 27.34% and absolute zeta potential up to 22.21%. By reduction of the flow resistance of water and increase of the oil−water ratio, electroosmosis shortens the time for the water at the displacement front to reach the outlet and reduces the volumetric sweep efficiency. Meanwhile, electroosmosis causes a smooth velocity profile similar to the piston-like displacement and increases displacement efficiency. Once a reduction in volumetric sweep efficiency could not be offset by an increase in displacement efficiency, oil recovery would be first improved with an increase in both voltage and ion concentration and then decreased, among which the effect of ion concentration is not as significant as that of the voltage.

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Section: Introductionmentioning

confidence: 99%

Laboratory Evaluation of Electrically Enhanced Oil Recovery in Tight Reservoirs

Jia,

Ning,

Lyu

et al. 2023

Energy Fuels

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Evaluation of Electroassisted Carbonated Water Injection (ECWI) in a Tight Reservoir: Outstanding Performance of Enhancing Oil Recovery and CO2 Storage Capacity

Jia,

Ning,

Lyu

et al. 2024

Day 3 Wed, April 24, 2024

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Summary Traditionally, carbonated water injection (CWI) finds its low injectivity in a tight reservoir with a low efficiency and slow effectiveness. By combining a direct current (DC) electric field with the CWI, i.e., the electroassisted CWI (ECWI), we conducted a series of experiments to evaluate the ECWI performance in a tight reservoir and identify the key underlying recovery mechanisms. Experimental results show that early adopting the ECWI in a tight sandstone reservoir results in the highest oil recovery up to 61.9%, compared to those of 51.2% for the CWI and 41.3% for the conventional waterflooding. During an ECWI process, a voltage of 10 V achieves the highest oil recovery, but that of 15 V has the best water injectivity and CO2 storage capacity. It is found that the underlying recovery mechanisms result from both electroosmosis and enhancement of carbonized water-rock reactions induced by a DC electric field. For a tight reservoir, the ECWI has the advantages of significantly increasing water injectivity, oil production rate, and CO2 storage capacity. By introducing two new indicators to respectively evaluate the water injection performance and energy consumption, the ECWI is found to perform moderately well at a low voltage in an energy-saving and financially viable manner.

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Effect of Wettability on Vaporization of Hydrocarbon Solvents in Capillary Media

Cited by 2 publications

References 32 publications

Laboratory Evaluation of Electrically Enhanced Oil Recovery in Tight Reservoirs

Laboratory Evaluation of Electrically Enhanced Oil Recovery in Tight Reservoirs

Evaluation of Electroassisted Carbonated Water Injection (ECWI) in a Tight Reservoir: Outstanding Performance of Enhancing Oil Recovery and CO2 Storage Capacity

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