Oil drop stretch and rupture behavior at throat and pore junction during imbibition with active nanofluid: A microfluidic approach

Oil drop stretch and rupture behavior at throat and pore junction during imbibition with active nanofluid: A microfluidic approach

Imbibition is an effective method to recover oil from small pore and throat. Here we report the formation of oil drop at pore and throat junction during spontaneous imbibition with active nanofluid. A T-channel microfluidic model combined with high-speed camera was used to observe the stretch and ru...

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Bibliographic Details
Published in:Colloids and surfaces. A, Physicochemical and engineering aspects Vol. 653; p. 130012
Main Authors: Sun, Yongpeng, Xin, Yan, Wei, Li’nan, Ding, Fei, Gao, Zhanwu, Liu, Hanbin, Tang, Meirong, Du, Xianfei, Dai, Caili
Format: Journal Article
Language:English
Published: Elsevier B.V 20-11-2022
Subjects:
Active nanofluid
Enhanced oil recovery
Imbibition
Interfacial tension
Microfluidic
Oil drop stretch process
Active nanofluid
Imbibition
Oil drop stretch process
Enhanced oil recovery
Interfacial tension
Microfluidic
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Summary:Imbibition is an effective method to recover oil from small pore and throat. Here we report the formation of oil drop at pore and throat junction during spontaneous imbibition with active nanofluid. A T-channel microfluidic model combined with high-speed camera was used to observe the stretch and rupture process of oil discharged from throat to pore. When oil drop was discharged from throat gradually, its width/length was kept deceasing before rupturing. With more active content in the aqueous phase, the interfacial tension decreased from 33.8 to 8.7 mN/m, and the oil recovery increased by 12.4% by spontaneous imbibition. The oil drop rupture frequency increased by 3.0 times, but the length and width of the oil drop decreased by 32.2% and 28.0%, respectively. The reduced size of the oil drop would benefit the oil transportation in porous media. Higher flow rate in pores and throat would all intensify rupturing of the oil drop. Moreover, small throat could further reinforce the rupturing process. From combination of fluid flow rate, interfacial tension, and viscosity, higher capillary number reduced the maximum dimensionless width and length of the oil drop by 44.3% and 42.7%, respectively. The reduced size of oil drops ruptured at pore and throat junction contributes to the transportation of oil in porous media. Overall, this study provides a basic theory for active nanofluid to enhance imbibition oil recovery in tight reservoirs. [Display omitted] •A T-shaped microfluidic model was used to observe the stretch and rupture process of oil drop.•Oil drop rupture morphology and frequency were affected by various parameters.•Higher capillary number reduced the maximum dimensionless width and height of the oil drop.•The reduced size of ruptured oil drops contributes to their transportation in porous media.
ISSN:0927-7757
1873-4359
DOI:10.1016/j.colsurfa.2022.130012