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W3200087348 endingPage "5646" @default.
W3200087348 startingPage "5639" @default.
W3200087348 abstract "Foams would play a substantial role in mobility control and are considered an efficient chemical agent to improve the oil recovery factor. Co-injection of foam and carbon dioxide (CO 2 ) would be one of the optimum injectivity scenarios in fractured tight core samples. This paper aimed to experimentally investigate the surfactant alternating gas injection and CO 2 -foam injection and how to determine the optimum parameters like foam quality, flow rate, and the number of cycles. It is observed that 0.65 is the optimum foam quality for the fractured tight core samples, and by the increase of foam quality, the pressure drop has been decreased. By increasing foam quality, pressure drop increases up to a specific value ( f g = 0 .65), and after this point, pressure drop has been decreased. Moreover, by the increase of injectivity cycles, pressure drop has increased subsequently. It is observed that five cycles are the optimum number of cycles, and after that, there is no pressure drop decrease in the system. Due to the surfactant property to control the mobility ratio, CO 2 breakthrough has occurred at 1.2 PV. Its oil recovery factor at breakthrough is about 48%, and the total oil recovery factor is about 65%. CO 2 -foam were injected into the system, and due to the presence of a foaming agent in CO 2 , a CO 2 breakthrough occurred at 1.8 PV. The total oil recovery factor is about 83% that indicated the efficiency of this scenario." @default.
W3200087348 created "2021-09-27" @default.
W3200087348 creator A5037774439 @default.
W3200087348 creator A5042581749 @default.
W3200087348 creator A5054963706 @default.
W3200087348 creator A5072154002 @default.
W3200087348 creator A5080064957 @default.
W3200087348 creator A5084446873 @default.
W3200087348 date "2021-11-01" @default.
W3200087348 modified "2023-10-16" @default.
W3200087348 title "Simultaneous injection of chemical agents and carbon dioxide to enhance the sweep efficiency from fractured tight core samples" @default.
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W3200087348 doi "https://doi.org/10.1016/j.egyr.2021.08.191" @default.
W3200087348 hasPublicationYear "2021" @default.
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