An Experimental and Numerical Investigation of Solvent Injection to Heavy Oil in Fractured Five-Spot Micromodels

摘要

In this work a series of solvent injection experiments was conducted on horizontal glass micromodels at several fixed flow rate conditions. The micromodels were initially saturated with heavy crude oil. The produced oil as a function of injected volume of solvents was measured using image analysis of the continuously provided pictures. In order to investigate the macroscopic behavior of the process in different media, several fractured, with constant width, and nonfractured five-spot micromodels were designed and used. The measured data have also been used for verifying and developing a simulation model that was later used for sensitivity analysis of some parameters that affect oil recovery. The results show that when the fracture spacing increased, the oil recovery decreased. In contrast, as the fracture orientation angle (the angle with the mean flow direction) or solvent viscosity increased, the oil recovery increased. A critical value for the ratio of connate water saturation to the oil volume has been found that, beyond that the solvent injection process, loses its efficiency. The final recovery of a water alternating solvent (WAS) injection process in fractured medium in the presence/absence of connate water saturation was considerably greater than that obtained either by continuous solvent injection or water injection alone. Good agreement was observed between experimental and simulation results when a dual permeability model was used in our simulation.