Abstract: The present invention is related with a biotechnological process that increases the recovery and mobilization of oils present in carbonated and/or siliciclastic porous media by the action of tensoactive biomolecules from Serratia marcescens SmSA. The invention also increases the oil recovery in reservoirs. Serratia marcescens SmSA biomolecules display tensoactive and emulsifying properties that produce changes in the surface and interfacial tensions, enhanced the recovery and mobilization of oils. The Serratia marcescens SmSA tensoactive biomolecules of the present invention are stable at temperatures from 4 to 121° C., pH from 2 to 12, pressures from atmospheric to 1,706 psi, and NaCl content from 0 to 200 g/L (from 0 to 200,000 ppm). The Serratia marcescens SmSA tensoactive biomolecules reduce the surface tension up to 26 mN/m, the interfacial tension up to 1.8 mN/m with hexadecane, with emulsifying activity up to 71% with the same solvent and a critical micellar concentration (CMC) of 300 mg/L.

Abstract: The present invention is related with a biotechnological process that increases the recovery and mobilization of oils present in carbonated and/or siliciclastic porous media by the action of tensoactive biomolecules from Serratia marcescens SmSA. The invention also increases the oil recovery in reservoirs. Serratia marcescens SmSA biomolecules display tensoactive and emulsifying properties that produce changes in the surface and interfacial tensions, enhanced the recovery and mobilization of oils. The Serratia marcescens SmSA tensoactive biomolecules of the present invention are stable at temperatures from 4 to 121° C., pH from 2 to 12, pressures from atmospheric to 1,706 psi, and NaCl content from 0 to 200 g/L (from 0 to 200,000 ppm). The Serratia marcescens SmSA tensoactive biomolecules reduce the surface tension up to 26 mN/m, the interfacial tension up to 1.8 mN/m with hexadecane, with emulsifying activity up to 71% with the same solvent and a critical micellar concentration (CMC) of 300 mg/L.

Abstract: A process for increasing recovery of heavy oil with an API gravity equal to or greater than 10, contained in carbonate and/or sandstone porous media using extremophile (thermophilic, halotolerant and barotolerant) anaerobic indigenous microorganisms. The process involves nutrient injection to stimulate activity of extremophile anaerobic indigenous microorganisms at the well bottom, promoting the production of metabolites which improve oil mobility and increase oil recovery. Stimulation of extremophile anaerobic indigenous microorganisms and their metabolite production is conducted under anaerobic conditions at temperatures of 45 to 90° C., NaCl concentrations of 5,000 to 40,000 mg/L and pressures of 0.795 to 169 Kg/cm2 (11.3 to 2,400 psi). Heavy oils are recovered with API gravity equal to or greater than 10 degrees. The process enables up to 21% oil recovery in addition to the waterflooding process in porous media.

Abstract: A biotechnological process for enhancing oil recovery of 14 to 25° API oil contained in carbonate or sandstone rock systems with low permeability utilizes indigenous extremophile microorganisms (first culture) from the oil well, a second culture containing selected microorganisms and its metabolites (gases, acids, solvents and surfactants), to improve oil mobility. Under anaerobic conditions, such microorganisms are able to grow in temperatures from 60 to 95° C., at pressures from 7 to 154.6 kg/cm2 and NaCl content from 5,000 to 45,000 ppm. Injection of indigenous microorganisms and a second culture for metabolites production into the well improves oil recovery after closing the system for periods from 5 to 10 days. The biotechnical process includes biostimulation (indigenous microorganisms) and bioaugmetation (second culture) to increase oil recovery.

Abstract: A process for increasing recovery of heavy oil with an API gravity equal to or greater than 10, contained in carbonate and/or sandstone porous media using extremophile (thermophilic, halotolerant and barotolerant) anaerobic indigenous microorganisms. The process involves nutrient injection to stimulate activity of extremophile anaerobic indigenous microorganisms at the well bottom, promoting the production of metabolites which improve oil mobility and increase oil recovery. Stimulation of extremophile anaerobic indigenous microorganisms and their metabolite production is conducted under anaerobic conditions at temperatures of 45 to 90° C., NaCl concentrations of 5,000 to 40,000 mg/L and pressures of 0.795 to 169 Kg/cm2 (11.3 to 2,400 psi). Heavy oils are recovered with API gravity equal to or greater than 10 degrees. The process enables up to 21% oil recovery in addition to the waterflooding process in porous media.

Abstract: The present invention refers to a biotechnological process that enhances oil recovery of a 14 to 25 API Gravity oil contained in carbonate-containing and/or clayey sandstone porous rock systems with low permeability (7 to 100 mD), thus focused to petroleum wells associated to zones with low recovery factor. The process utilizes the indigenous extremophile microorganisms activity from the oil reservoir and an IMP culture, as well as its metabolites (gases, acids, solvents and surfactants), which improve oil mobility and are able to develop at 60 to 95° C. temperatures, 7 to 154.6 Kg/cm2 (100 to 2,200 psi) pressures and NaCl content from 5,000 to 45,000 ppm, in anaerobic conditions.