Favorable Attributes of Alkali-Surfactant-Polymer Flooding

Abstract

AbstractA laboratory study of the alkali-surfactant-polymer (ASP) process was conducted. It was found from phase behavior studies that for a given synthetic surfactant and crude oil containing naphthenic acids, optimal salinity depends only on the ratio of the moles of soap formed from the acids to the moles of synthetic surfactant present. Adsorption of anionic surfactants on carbonate surfaces is reduced substantially by sodium carbonate but not by sodium hydroxide. The magnitude of the reduction with sodium carbonate decreases with increasing salinity.Particular attention was given to a surfactant blend of a propoxylated sulfate having a slightly branched C16-17 hydrocarbon chain and an internal olefin sulfonate. In contrast to alkyl/aryl sulfonates previously considered for EOR, alkaline solutions of this blend containing neither alcohol nor oil were single-phase micellar solutions at all salinities up to and even exceeding optimal salinity with representative oils. Phase behavior with a West Texas crude oil at ambient temperature in the absence of alcohol was unusual in that colloidal material, perhaps another microemulsion having a higher soap content, was dispersed in the lower phase microemulsion. Low interfacial tensions existed with the excess oil phase only when this material was present in sufficient amount in the spinning drop device. Overall solubilization of oil and brine for this system was high, leading to low interfacial tensions over a wide salinity range and to excellent oil recovery in both dolomite and silica sand packs. These experiments were performed with surfactant concentrations as low as 0.2 wt%. It was necessary that sufficient polymer be present to provide adequate mobility control and that salinity be below the value at which phase separation occurred in the polymer/surfactant solution.A one-dimensional simulator was developed to model the process. By calculating transport of soap formed from the crude oil and injected surfactant separately, it showed that a gradient in local soap-to surfactant ratio develops during the process. This gradient increases robustness of the process in a manner similar to that of a salinity gradient in a conventional surfactant process. Predictions of the simulator were in excellent agreement with the sand pack results.