Abstract
We present a systematic study of crude oil–brine–rock interactions in tight chalk cores at reservoir conditions. Flooding experiments are performed on outcrops (Stevns Klint) as well as on reservoir core plugs from Dan field, the Ekofisk and Tor formations. These studies are carried out in core plugs with reduced pore volumes, i.e., short core samples and aged with a dynamic ageing method. The method was evaluated by three different oil compositions. A series of synthetic multicomponent brines and designed fluid injection scenarios are investigated; injection flow rates are optimized to ensure that a capillary-dominant regime is maintained. Changes in brine compositions and fluid distribution in the core plugs are characterized using ion chromatography and X-ray computed tomography, respectively. First, we show that polar components in the oil phase play a major role in wettability alteration during ageing; this controls the oil production behavior. We also show that, compared to seawater, both formation water and ten-times-diluted seawater are better candidates for enhanced oil recovery in the Dan field. Finally, we show that the modified flow zone indicator, a measure of rock quality, is likely the main variable responsible for the higher oil recoveries observed in Tor core samples.
Highlights
Low-salinity water injection (LSWI) has shown improved oil recovery in both sandstone [1,2,3,4,5] and carbonate [6,7,8] reservoirs
To understand the effect of crude oil–brine–rock (COBR) individually, we investigate three different oil compositions: hexadecane, stearic acid–hexadecane, and reservoir crude oil
Hexadecane was used as a model oil for the first core flooding experiment; reservoir crude oil was used for the rest of the experiments, except the second one
Summary
Low-salinity water injection (LSWI) has shown improved oil recovery in both sandstone [1,2,3,4,5] and carbonate [6,7,8] reservoirs. The mechanisms behind the success of LSWI in carbonates have been studied extensively [9,10,11,12,13,14], decoupling the specific underlying mechanisms remains a challenge To tackle this challenge, a systematic study of the crude oil–brine–rock (COBR) interactions for each reservoir is critical. The disequilibrium of the COBR system induced by the injection of a low salinity or modified salinity brine can lead to an increase in oil recovery [10,15]. Wettability alteration from this ‘initial reservoir wetting state’ has been reported as the main mechanism behind enhanced oil recovery (EOR) by LSWI [15,16]. There is still a need to determine which mechanism is primary at particular reservoir conditions with a specific COBR system [18]
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