RU2012145291A - CONSTRUCTION OF A WELL WITH PRESSURE MANAGEMENT, OPERATION SYSTEMS AND METHODS APPLICABLE FOR OPERATIONS WITH HYDROCARBONS, STORAGE AND MINING - Google Patents

Abstract

1. Device (23, 23C, 23F, 23I, 23S, 23T, 23V, 23Z, 128) for the formation of a system of pipe columns, applicable for selective access and movement of fluid mixture flows passing through many pipes in one or more wells passing from one main trunk or between wells, for at least one of the following: hydrocarbon production, dissolution production, and reservoir operation, comprising at least one distribution sub device (23) having a first plurality of pipes (2, 2A, 2B, 2C, 2D, 39) at the upper end, and the second one is at the lower end, the first plurality of pipes contains at least one intermediate concentric passage (24, 24A, 24B, 24X, 24Y, 24Z) located around the inner passage (25) to create access to the manifold and move the fluid mixtures to the at least one underground flow controller (61, 128) and from it to provide selective control of the movement of the fluid mixture in the passages, pipes, wells, or combinations thereof, the first radial passage (75) and at least the second radial passage (75), shared with the first rad at the same time, the radial passages are in communication with the inner passage, and at least one underground flow regulator is installed between the upper end and lower end to separate these radial passages, and is able to divert at least part of the flow of the fluid mixture to another a passage radially inward or outward from a designated passage through at least one of the radial passages of at least one distribution sub to form a plurality of barriers (14

Claims (28)

1. Device (23, 23C, 23F, 23I, 23S, 23T, 23V, 23Z, 128) for forming a pipe string system applicable for selectively accessing and moving fluid mixture flows passing through a plurality of pipes in one or more wells passing from one main trunk or between wells, for at least one of the following: hydrocarbon production, dissolution production and reservoir operation, comprising at least one distribution sub device (23) having a first plurality of pipes (2, 2A, 2B, 2C, 2D, 39) at the upper end, and the second one is the number of pipes at the lower end, the first set of pipes containing at least one intermediate concentric passage (24, 24A, 24B, 24X, 24Y, 24Z) located around the inner passage (25) to create access to the manifold and move the fluid mixtures to the at least one underground flow controller (61, 128) and from it to provide selective control of the movement of the fluid mixture in the passages, pipes, wells, or combinations thereof, the first radial passage (75) and at least the second radial passage (75), shared with the first rad at the same time, the radial passages are in communication with the inner passage, and at least one underground flow regulator is installed between the upper end and lower end to separate these radial passages, and is able to divert at least part of the flow of the fluid mixture to another a passage radially inward or outward from a designated passage through at least one of the radial passages of at least one distribution sub to form a plurality of barriers (14 8, 149, 150) pressure to control the movement of the fluid mixture between at least two of the following: the surrounding passage (55), the internal passage and at least one intermediate passage for accessing the manifold and performing operations in the manifold or performing operations with hydrocarbons. 2. The device according to claim 1, in which at least one intermediate passage is divided around the circumference to form the first and at least second circumferential axial passages (24A, 24B, 24X, 24Y, 24Z) associated with the first and at least second radial passages, at least one underground flow regulator is installed across the first and at least second axial passages located at the circumference to at least partially block the movement of the fluid mixture between the upper end and bottom ontsom and exhaust fluid mixture through a first and at least a second radial passages, wherein at least one underground flow regulator provides a transfer between the inner flow passage and at least one intermediate passage between the upper and lower ends. 3. The device according to claim 2, additionally containing gate valves connected to the ends of the inner passage (25) for selectively controlling the movement of the fluid mixture through the passage with the formation of a valve-controlled distribution sub. 4. The device according to claim 2, additionally containing at least one additional column (2B, 2C, 2D, 39) installed through at least one intermediate passage and separated from it, while at least , one of the radial passages allows the movement of the fluid mixture between the inner passage and at least one additional column. 5. The device according to claim 1, additionally containing a connecting chamber (43) in communication with the internal passage through the first and at least second radial passages through the first pipe (39) of the output channel and at least the second pipe (39) the outlet channel, respectively, with at least one additional radial passage for moving the fluid mixture between the first pipe of the outlet channel and at least one intermediate passage, and a channel selector (47) for selectively moving the flow controller through the inner niy passage. 6. The device according to claim 5, in which the passage of the first pipe of the output channel closest to the axial line is aligned with the axis of the connecting chamber, and the first plurality of pipes passes surrounding the first pipe of the output channel and at least one other pipe of the output channel, which passes through at least one intermediate passage (24) and is separated from it to provide communication with another intermediate passage or surrounding passage, while the channel selector or at least one underground flow regulator is used for selective control tion of the movement of the fluid mixture through radial passages. 7. The device according to claim 6, additionally containing at least one additional radial passage located between the passage of the first pipe of the output channel closest to the axial line and the intermediate passage, wherein at least one underground flow regulator is used for selective control moving the fluid mixture through at least one additional radial passage. 8. The device according to claim 1, in which the first and at least second radial passages are a first radial passage formed by a connected twin packer or channel selector axially aligned with the inner passage and at least a second radial passage separated with a double packer from the first radial passage, at least the second radial passage contains a pipe passing through at least one intermediate passage (24) and separated from it, while the double packer or channel selector is capable of move through the inner passage and is used to selectively control the movement of the fluid mixture through the radial passages. 9. The device according to claim 1, additionally containing a flow regulator (128) in the form of a piston with a throttle bore, moved through an internal passage, installed and removed using a pressure differential applied to the axially upper or axially lower end of the piston, with cables or pipes pass through at least one throttle bore using the ends of the piston to divert at least a portion of the flow of the fluid mixture into a passage other than the inner passage. 10. A method (CS1-CS8) for performing or using at least one distribution device (23, 23C, 23I, 23S, 23T, 23V, 23Z) to form a pipe string system for selectively accessing and moving fluid flows through a plurality pipes in one or more wells extending from one main trunk, or between them for at least one of the following: hydrocarbon production, dissolution production and operation of reservoirs, comprising the following steps: providing at least one system (70, 76) of pipe columns containing a plurality of pipes (2, 2A, 2B, 2C, 2D, 39) connected to a plurality of distribution sub pipes, having at least one intermediate passage (24, 24A, 24B, 24X, 24Y, 24Z) located around the inner passage (25) to access the collector and to allow the movement of fluid mixtures with at least one underground flow regulator (61, 128); the circulation of the fluid mixture flows through the first and at least second radial passage (75) of the pipes of the distribution sub, while the first and at least second radial passage are in communication with the inner passage; and blocking at least one of the passages with at least one underground flow regulator to divert at least a portion of the flow of the fluid mixture into another passage radially inward or outward from at least one of the passageways to form many pressure barriers (148, 149, 150) for selectively controlling the movement of the fluid mixture between at least two of the following: the surrounding passage (55), the internal passage, and at least one intermediate passage to access the manifold and you complete operations in the reservoir, or extraction or extraction with dissolution. 11. The method of claim 10, further comprising using gate valves connected to each end of the inner passage of the at least one distribution sub to selectively control the fluid mixture under pressure moving through the inner passages and at least one intermediate passage. 12. The method according to claim 10, additionally containing the use of at least one underground flow regulator moving through an internal passage and connected in a system of pipe columns to selectively control the movement of a fluid mixture by diverting at least a portion of the flow of the fluid mixture. 13. The method according to item 12, further comprising providing a flow regulator with a piston with a throttle bore, installed and removed using a pressure differential applied to its axially upper or axially lower surfaces, and installing cables or pipes passing through the flow regulator during removal, at least part of the flow of the fluid mixture into the passage, other than the inner passage. 14. The method of claim 10, further comprising selectively controlling the movement of fluid mixtures of gases, liquids, solids, or combinations thereof between one main wellbore and zones near one or more wells to create hydrostatic pressure of repression, equilibrium, or depression produced in a close zone in moving time of fluid mixtures. 15. The method of claim 10, further comprising providing one or more additional connecting pipes for functional interaction with a plurality of pressure barriers, wherein the additional connecting pipes are concentric or radial in the secondary pressure working pipe. 16. The method according to clause 15, further comprising connecting one or more additional connecting pipes to limit the pressure acting on many pressure barriers with pressure equalization or pressure relief in the pressure-absorbing tank. 17. The method (1S, 1T, 157, CO1-CO7) for creating selective access to the reservoir and moving fluid flows in one or more wells passing through many pipes from one main trunk or between them, for at least one of the following: hydrocarbon production or production by dissolution and operation of the reservoir, comprising the following steps: providing at least two of the following: two independent boreholes or a system of pipe columns with one or more wells extending from the main shaft with two or more pipe columns connected to one or more blocks of equipment of the wellhead, fountain fittings and underground controllers (61, 128) flow, forming many pressure barriers (148, 149, 150) to create selective access to the reservoir and move fluid mixtures of gases, liquids, solids, or combinations thereof, through the passageway cutting underground formations in at least one zone in the vicinity of one or more substantially hydrocarbon or substantially water reservoirs; however, the system of pipe columns contains at least one distribution sub (23, 23C, 23I, 23S, 23T, 23V, 23Z), applicable with flow controllers (61, 128) installed and removed from the internal passage for selective removal, at least a portion of the flow of fluid mixtures into another passage radially inward or outward from the allotted passage between two or more pipe columns through at least one of the radial passages of the distribution sub; and selective control of the movement of the fluid mixture between the equipment of the wellhead and at least one close area at the lower end of two or more pipes used to access the manifolds, with fountain fittings, flow controllers and many pressure barriers to create, when used, selective access to the collector and the movement of essentially hydrocarbon or essentially water flows of fluid mixtures to or from the collectors during operations with hydrocarbon reservoirs, mining operations from reservoirs creation or combinations thereof. 18. The method according to 17, in which the creation of selective access to the reservoirs and the movement of fluid mixtures between one or more essentially hydrocarbon or essentially aqueous reservoirs comprises separating the fluids of different relative densities with the possibility of creating selective access to the reservoirs and movements at two or more depths using flow controls. 19. The method according to 17, further comprising the step of selectively using flow controllers to supply water at two or more depths to at least one close zone in the salt deposit to form a substantially hydrocarbon or substantially aqueous salt solution and a storage tank (158, 159) with a buffer space inert to salt or stored fluid above a substantially water partition surface (117) or a fluid partition surface (117 A), suitable for controlling salt dissolution, hydrocarbon production, (1 ) production p stvoreniem or combinations thereof (1S). 20. The method according to p. 19, in which the selective movement of fluid mixtures between one or more blocks of equipment of the wellhead and fountain valves and at least one close zone comprises selective movement of the fluid mixture to at least one close zone using flow regulators at two or more depths between or below a substantially aqueous or interfacial interface for transporting stored fluids or brine to at least two reservoirs (158, 159) or la and storage of them. 21. The method of claim 20, further comprising selectively using flow controllers to supply water to the substantially water interface or fluid interface at two or more depths to displace the brine at the lower end of the first brine tank (158, 159) and storage through a device with a U-shaped pipe into at least a second brine tank and storage to form a brine by dissolving salt in a first brine tank and storage to minimize salt dissolution in at least a second tank (158, 15 9) brine and storage during operation. 22. The method according to claim 19, further comprising the step of selectively using flow controllers to supply fluids inert to salt or stored in salt of different relative densities at two or more depths to form a buffer with multiple fluid interface surfaces containing buffer spaces for storage operations under the shoe of the last casing string with cementing and above a substantially water interface or fluid interface. 23. The method according to claim 19, in which the selective regulation of the movement of the fluid mixture between the fountain and at least one close zone comprises the selective use of flow controllers at two or more depths to control the movement of a fluid inert to salt or fluids storage, stored and retrieved from the buffer, for influencing the corresponding working pressures, volumes and temperatures of the fluids stored and retrieved from the brine tank (158, 159) and storage. 24. The method of claim 19, further comprising selectively controlling the shape of the cavity walls using flow regulators at two or more depths to control the dissolution of the salt and brine tank (158, 159) and storage by adjusting the substantially water interface or surface fluid section for regulating the working storage volumes, the rates of production by dissolution, the rates of creep of salt or combinations thereof, to achieve the maximum effective diameter for the stability of the salt cavity. 25. The method according to paragraph 24, further comprising storing the salt inert fluid in the walls of the cavity between the underground depths, in which the walls of the cavity reach their maximum effective diameter for the stability of the salt cavity, and selectively creating two or more accesses and movements of salts inert to the salt; depths using flow regulators. 26. The method according to p. 19, further containing the location and separation of one or more reservoirs for creating support columns of salt according to the pressures of the fluids stored in the effective diameters of the brine and storage tanks (158, 159) and selectively creating access and moving these fluids to two or more depths using flow regulators. 27. The method according to claim 19, in which the selective control of the movement under pressure of the fluid mixture between the fountain valves and at least one close zone for hydrocarbon production, dissolution production or combinations thereof comprises using the ocean’s ability to draw water and absorb brine and use regulators flow at two or more depths. 28. The method according to p. 19, in which the selective regulation of the movement of the fluid mixture between the fountain valves and at least one close zone comprises using the possibilities of moving the fluid mixture with ships, pipelines or the ocean for the operation of brine storage tanks (158, 159) and storage and the use of flow regulators at two or more depths.