RU2007149587A - METHOD OF PHYSICAL IMPACT AT THE DEVELOPMENT OF A HYDROCARBON DEPOSIT AND A WELL DEPARTMENT FOR ITS IMPLEMENTATION - Google Patents

Abstract

1. The method of physical impact in the development of a hydrocarbon reservoir, including the selection of reservoir fluid through production wells, the treatment of reservoirs by wave radiation and depression-repressive perturbations of reservoir pressure from at least one production and / or injection well, determination of the frequency of exposure and regulation of selection formation fluid from the wells, characterized in that prior to the depression-repression perturbation of the reservoir pressure from the wells, the plas is tested and with the recording and analysis of signals of its microseismic emission, as well as the hydrodynamic parameters of the formation and the composition of the formation fluid to determine the frequency ranges and modes of effective exposure, then a poly-frequency effect is performed with the identified parameters using the simultaneous operation of at least two sources, at the same time or alternately with polyfrequency exposure, a depression-repression disturbance is periodically carried out with the above testing and in reverse mode tie with the formation adjust modes of action, specifying frequency ranges and combining radiation sources and the impact of cyclically repeated until the termination of the selection changes the formation fluid. ! 2. The method according to claim 1, characterized in that they intensify the processes of crack formation, develop existing cracks and / or create new ones by sequentially flushing wells at the stages of circulation or outflow and pumping a working fluid, for example oil, oil-emulsion and / or at least one rim chi�

Claims (23)

1. The method of physical impact in the development of a hydrocarbon reservoir, including the selection of reservoir fluid through production wells, the treatment of reservoirs by wave radiation and depression-repressive disturbances of reservoir pressure from at least one production and / or injection well, determination of the frequency of exposure and regulation of selection formation fluid from the wells, characterized in that prior to the depression-repression perturbation of the reservoir pressure from the wells, the plas is tested and with the recording and analysis of signals of its microseismic emission, as well as the hydrodynamic parameters of the formation and the composition of the formation fluid to determine the frequency ranges and modes of effective exposure, then a poly-frequency effect is performed with the identified parameters using the simultaneous operation of at least two sources, at the same time or alternately with polyfrequency exposure, a depression-repression disturbance is periodically carried out with the above testing and in reverse mode tie with the formation adjust modes of action, specifying frequency ranges and combining radiation sources and the impact of cyclically repeated until the termination of the selection changes the formation fluid. 2. The method according to claim 1, characterized in that they intensify the processes of crack formation, develop existing cracks and / or create new ones by sequentially flushing wells at the stages of circulation or outflow and pumping a working fluid, for example oil, oil-emulsion and / or at least one rim of chemicals, which use solutions of surfactants, acids, alkalis and hydrocarbon solvents. 3. The method according to claim 1, characterized in that for the periodic creation of a depression-repression disturbance, processes are used for pumping the well fluid with jet pumps and / or control the density of the working fluid in the aeration and foaming processes and / or selective narrowing of the well space. 4. The method according to claim 1, characterized in that the formation is hydrodynamically isolated, the magnitude of the repression perturbation is increased, for example, by increasing the pressure and flow rate of injection of the working fluid into the formation, up to the formation of fracturing pressures, after which a fixing agent, for example, proppant, is pumped into the formation and / or insulating and blocking emulsions, solutions and / or emulsions of high viscosity reagents. 5. The method according to claim 1, characterized in that under the conditions of opening a multilayer reservoir, testing is preliminarily carried out at all productive intervals, then a poly-frequency effect of elastic vibrations on the bottom-hole zone is performed simultaneously or alternately with the creation of depression-repression disturbances and injection of functional working fluids, testing is repeated and the reservoir interval is selected based on its results, it is hydrodynamically isolated and hydraulic fracturing is performed. 6. The method according to claim 1, characterized in that as the radiation using waves of elastic vibrations, and / or electromagnetic, and / or thermal. 7. The method according to claim 1, characterized in that as sources for the polyfrequency effect, sources are used, in the frequency spectrum of which, along with the dominant frequency, there are harmonics with lower and / or higher frequencies that are identical and / or phase shifted. 8. The method according to claim 1, characterized in that borehole sources based on hydraulic vortex processes in the borehole fluid flows, on mechanohydraulic shock processes of interruption of the flow, on electromechanical processes, on the contact-gravity creation of dilatational wave perturbations are used for poly-frequency impact Wednesday. 9. The method according to claim 1, characterized in that according to the recall of the formation in feedback mode, simultaneously with the regulation of the selection of formation fluid, the injection of the displacing agent into the surrounding wells is controlled. 10. The method according to claim 1, characterized in that at the same time and / or alternately act as wave radiation from the wells and create a cyclic change in the directions and rates of fluid filtration in the reservoir and / or carry out a wave action on the reservoir from the surface. 11. A downhole installation for physical impact, including a tubing string, two interconnected pipe parts, one of which is equipped with a stress concentrator and is stationary, and the other pipe part is equipped with a piston and mounted with the possibility of reciprocating movement relative to the fixed pipe part, characterized in that the pipe parts are connected coaxially, while the stationary pipe part is located inside, consists of at least two hollow cylinders connected in series of known diameter, at least one of which is equipped with a relay valve that hydraulically connects the cylinder cavity with the borehole space, and the other is equipped with a flow regulator, while the coaxially connected pipe parts are equipped with hydraulic locks mounted on series-connected hollow cylinders of different diameters in communication with the borehole space and with the internal cavity of the tubular part, equipped with a piston and additionally with an actuator for controlling the relay valve. 12. The downhole installation according to claim 11, characterized in that an elastic wave emitter is installed on the piston of the pipe part. 13. The downhole installation according to item 12, characterized in that the emitter of elastic waves is made in the form of at least one spring-loaded pusher. 14. The downhole installation according to claim 11, characterized in that a part of the surface of the hollow cylinder is provided with a series of annular grooves or protrusions. 15. The downhole installation according to claim 11, characterized in that the flow controller is equipped with a pulsating device. 16. The downhole installation of Claim 15, wherein the flow regulator is provided with at least one pulsating nozzle connected in series with a centrifugal nozzle and with a cavity with elasticity and at least one constant flow nozzle. 17. The downhole installation according to clause 16, wherein the nozzles of the flow regulator are installed coaxially with a common axis of rotation, while the pulsating nozzle is shifted downstream relative to the nozzle of constant flow. 18. The downhole installation according to claim 11, characterized in that the stress concentrator is installed with emphasis on the bottom. 19. The downhole installation according to claim 11, characterized in that at least one packer and / or centralizer is installed on the stationary pipe part and / or tubing string and / or stress concentrator. 20. The downhole installation according to claim 11, characterized in that a jet pump with a check valve is installed above the packer. 21. The downhole installation according to claim 11, characterized in that the tubing string is connected to a downhole pump. 22. The downhole installation according to claim 11, characterized in that the tubular part provided with a piston and an actuator for controlling the relay valve is spring loaded relative to the stationary tubular part. 23. The downhole installation according to claim 11, characterized in that the water locks are mounted on serially connected hollow cylinders of different diameters with an adjustable clearance.