Abstract
Although low salinity water injection (LSWI) has recovered residual oil after the conventional waterflood, highly viscous oil has remained in heavy oil reservoirs. Hot water injection is an economic and practical method to improve oil mobility for viscous oil reservoirs. It potentially controls temperature-dependent geochemical reactions underlying the LSWI mechanism and oil viscosity. Therefore, this study has modeled and evaluated a hybrid process of low salinity hot water injection (hot LSWI) to quantify synergistic effects in heavy oil reservoirs. In comparison to seawater injection (SWI) and LSWI, hot LSWI results in more cation ion-exchange (Ca2+ and Mg2+) and more wettability modification. Hot LSWI also reduces oil viscosity. In core-scaled systems, it increases oil recovery by 21% and 6% over SWI and LSWI. In a pilot-scaled reservoir, it produces additional oil by 6% and 3% over SWI and LSWI. Probabilistic forecasting with uncertainty assessment further evaluates the feasibility of hot LSWI to consider uncertainty in the pilot-scaled reservoir and observes enhanced heavy oil production. This study confirms the viability of hot LSWI due to synergistic effects including enhanced wettability modification and oil viscosity reduction effects.
Highlights
Conventional waterflood has been widely deployed to maintain pressure of reservoirs and pressurize depleted reservoirs
We investigated the coreflooding of secondary SW injection (SWI), low salinity water (LSW) injection (LSWI), and hot LSWI (115 °C), respectively, in terms of oil viscosity, geochemical reactions, and wettability modification
This study models hot LSWI process and evaluates synergistic effects of hot LSWI to enhance heavy oil production
Summary
Conventional waterflood has been widely deployed to maintain pressure of reservoirs and pressurize depleted reservoirs. The field tests and experiments already have confirmed that hot water injection reduces heavy oil viscosity and improves heavy oil production (Kovscek et al 2000; Alajmi et al 2009; Duval et al 2015) It potentially influences pore connectivity because of temperaturedependent mineral reactions (Kovscek et al 2000). Its results proved the enhanced heavy oil production and synergistic effects of the hybrid hot LSWI, the study lacked investigations of temperature-dependent geochemical reactions and carbonate rock during hot LSWI. This study simulates hybrid hot LSWI considering temperature-dependent geochemical reactions and evaluates the heavy oil recovery of hot LSWI from carbonate reservoirs. The heavy oil production and synergistic effects of hot LSWI are compared to those of SWI and LSWI in core- and pilot-scaled systems
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