WO2008066412A1 - Well jet device logging and testing horizontal wells - Google Patents

Abstract

The invention relates to pumping engineering and can be used for the gas and oil production industry for developing drilled wells or during the reparation thereof. The inventive well jet device comprises a body (5) provided with a working medium flow switch arranged therein. Said flow switch is embodied in a form of a spring-loaded steady bush (14) provided with bypass holes (15, 16) and a support seat for mounting a sealing unit (18) which is formed by a stepped piston (22) and a body (19) or changeable operational inserts, and a return valve (13) is arranged in the channel (10) for draining a pumped out medium. The inventive position of the working medium flow switch increases the operational reliability and performance of the device during the treatment of a production formation, prevents the active working medium from spontaneous overflowing when a jet pump stops to operate and to maintain depression applied on the formation when the jet pump does not operate.

Description

 BORROWING JET PLANT FOR HORIZONTAL WELLS TESTING AND TESTING

Field of application The invention relates to the field of pumping technology, mainly to downhole pumping units for testing and development of wells.

BACKGROUND OF THE INVENTION A downhole jet installation is known comprising a packer mounted on a pipe string from the bottom to the top with a central channel and a jet pump in the housing of which an active nozzle and a mixing chamber with a diffuser are installed, and a working medium supply channel and a pumped-out supply channel are made. from the well of the medium, while in the housing of the jet pump a passage channel is made with the possibility of installing replaceable functional inserts and a sealing assembly (RU 2176336 Cl) in it.

This downhole jet installation allows the formation to be processed in the well below the level of the jet pump installation, including creating a pressure differential above and below the sealing unit. However, the capabilities of a downhole jet installation are not used to the full extent, which is associated with a large investment of time for replacing the inserts, which is often longer than the estimated reaction time of the acid solution with the minerals of the reservoir.

The closest to the invention in terms of technical essence and the achieved result is a downhole jet installation comprising a packer mounted on a pipe string with a central channel formed therein and a jet pump in the housing of which an active nozzle and a mixing chamber with a diffuser are installed, as well as a channel for supplying a working medium, a channel for supplying a medium pumped out of a well, and a fluid flow switch is installed in the housing of the jet pump, the output of the jet pump is connected to the annular space of the pipe string, the nozzle of the jet pump through the medium supply channel is connected to the internal cavity of the pipe string above the switch and the medium channel for pumping the medium pumped out of the well is connected to the internal cavity of the pipe string below the packer (RU 2222717 C l). This downhole jet installation allows you to switch the flow of the working environment and affect the reservoir by creating depression and repression. However, the used flow switch creates significant hydraulic resistance and occupies the bore of the pipe string, which does not allow equipment and various purposes to be lowered into the well, for example, measuring instruments, flexible pipes for feeding chemicals or hydraulic fracturing fluids, as well as devices for influencing layer, which narrows the capabilities of this installation. Disclosure of invention

The task to which the present invention is directed is to improve the quality of work to increase well production by improving the technology of treating a productive formation with liquid agents, preventing spontaneous overflow of an active working medium when the jet pump stops working and maintaining depression on the formation when the jet pump is not working. The technical result achieved by the implementation of the invention is to increase the reliability and productivity of the downhole jet unit during processing of the reservoir and testing the well. This problem is solved, and the technical result is achieved due to the fact that the downhole jet installation includes a packer mounted on the pipe string from bottom to top with a central channel made therein and a jet pump in the housing of which a nozzle and a mixing chamber with a diffuser are installed, while the diffuser has an outlet connected to the annular space of the pipe string, the nozzle of the jet pump is connected to the internal cavity of the pipe string through a channel for supplying a working medium in the body of the jet pump, and In the case of a single pump, the channel for supplying the medium pumped out from the well is connected to the inner cavity of the pipe string through the upper and lower windows made in the jet pump housing, and a check valve is installed in the channel for supplying the pumped medium, located in the latter from the input side through the lower window, in the The pump is mounted coaxially with the pipe string and has a working fluid flow switch made in the form of an axially movable support sleeve spring-loaded relative to the housing, while in the support sleeve s upper and lower bypass holes and a seat for the installation of a descent through the column pipe sealing assembly or replaceable functional insert, in particular inserts for the registration curves recovery reservoir pressure in the initial upper position of the supporting sleeve of the working and the pumped medium supply channels covered last, and in the lower position of the support sleeve, its upper end is located below the inlet to the channel for supplying a working medium, while the bypass holes of the supporting sleeve are in communication with the entrance to the channel for supplying the medium pumped out from the well, the sealing unit is made in the form of a hollow stepped cylindrical body, in the upper part of the cavity of which a sealing element is placed, and below, in the cavity is located, with emphasis in an annular ledge in the cavity of the housing of the sealing unit, a stepped piston, spring-loaded relative to the sealing about the element, while in the wall of the housing of the sealing unit opposite the upper bypass holes of the supporting sleeve there are holes that are blocked by a stepped piston when it is in the lower position, and in the upper position of the stepped piston and simultaneously in the lower position of the supporting sleeve through the holes in the housing of the sealing unit, the upper bypass holes in the support sleeve and the upper window in the jet pump housing, the channel for supplying the medium pumped out of the well above the check valve with an internal cavity the pipe string below the jet pump housing and simultaneously the lower bypass openings of the support sleeve are in communication with the lower window of the supply channel of the fluid pumped out of the well, while the stepped piston and sealing element have axial axial channels for passing through them a flexible pipe through which the logging cable is passed, At the lower end of the flexible pipe, a complex logging tool is fixed, which is connected to the logging cable through the cable head, and in the wall of the flexible pipe above the complex logging tool m openings, by means of which the internal cavity of the pipe string is connected with the annular sub-packer space of the well.

An analysis of the operation of the well jet installation showed that the reliability and efficiency of the installation can be improved by optimizing the design of the installation and thereby achieve more complete cleaning of the borehole formation zone in the wells, shorten the time for these operations and expand the functionality of the installation when testing and developing wells.

It was found that the hydrodynamic effect on the borehole zone of the well allows the most efficient use of the downhole jet unit during the development and repair of oil and gas wells during work to intensify the influx of oil from the reservoir. At the same time, the installation allows cleaning the productive formation from clogging particles and reaction products of the treatment of the formation with chemical reagents, conducting control measurements both before and during the treatment, which in turn allows us to evaluate the technical condition and productivity of the well, as well as the properties of the pumped out from a borehole medium. Based on the results of studying the inflow, it is possible to evaluate the quality of processing the borehole zone of the reservoir. The installation with a switch of the working fluid flow in the form of a support sleeve spring-loaded relative to the housing allows processing of the productive formation by pumping chemicals and / or hydraulic fracturing into the formation through a pipe string. In this case, the support sleeve blocks the supply channels of the working and pumped media, which prevents them from clogging. The implementation of the support sleeve with a seat allows you to install various technological equipment in the sleeve and conduct hydrodynamic processing of the reservoir.

The downhole installation makes it possible to create a number of different depressions using a jet pump in the sub-packer zone of the well with a given pressure drop, and using a logging tool to record pressure, temperature and other physical parameters along the wellbore and the medium pumped out of the well, and also record the recovery curve reservoir pressure in the under-packer space of the well without using a specially designed functional insert. At the same time, it is possible to control the magnitude of depression by controlling the rate of pumping of the active working medium. During the formation test, it is possible to adjust the pumping mode by changing the pressure of the active working medium supplied to the active nozzle of the jet pump. At the same time, the implementation of the inlet channel for the medium pumped out from the well with a check valve and two (upper and lower) windows eliminates the possibility of spontaneous overflow of the working medium into the sub-packer zone when the jet pump is not working.

Implementation of coaxial axial channels in the stepped piston and sealing element for passage through them with the possibility of axial movement of the flexible pipe through which the logging cable is passed and fastening at the lower end of the flexible pipe of a complex logging tool that is connected to the logging cable by means of a cable head, as well as wall of a flexible pipe over a complex logging tool holes allows you to conduct better work on the study of the well, as well as to process the well and prepare it for operation without reinstalling the well jet installation. As a result, intensification of work on research and development of wells is achieved, which allows for high-quality research and testing of wells after drilling and during overhaul, as well as preparation of a well for operation with comprehensive research and testing in various modes, and thereby increasing the reliability of the installation.

Brief Description of the Drawings

Figure 1 presents a longitudinal section of a downhole jet unit during the treatment of the formation with chemical reagents or hydraulic fracturing fluid. Figure 2 presents a longitudinal section of a downhole jet unit with a sealing unit and a logging tool located on a flexible pipe in the formation zone.

On Fig.3 shows a longitudinal section of a downhole jet unit during its preparation for the lifting of the logging tool and the sealing unit to the surface.

The best embodiment of the invention

The proposed downhole jet installation comprises a packer 2 mounted on a pipe string 1 with a shank 29 from bottom to top, with a central channel 3 made therein, and a jet pump 4, in the housing 5 of which a nozzle 6 and a mixing chamber are installed

7 with a diffuser 8. The output of the diffuser 8 is connected to the annulus of the pipe string 1. The nozzle 6 of the jet pump 4 is connected to the inner cavity of the pipe string 1 through made in the housing 5 of the jet pump 4 channel 9 for supplying a working medium. The channel 10 for supplying the fluid pumped out of the well in the housing 5 of the jet pump 4 is connected to the inner cavity of the pipe string 1 through the upper 11 and lower 12 windows made in the housing 5 of the jet pump 4. In the channel 10 for supplying the pumped-out medium, a check valve 13 is installed, which is located in the latter from the entrance to it through the lower window 12. In the housing 5 of the jet pump 4, a fluid flow switch is installed coaxially to the pipe string 1, made in the form of a support sleeve 14 axially movable , spring-loaded relative to the housing 5. In the supporting sleeve 14, the upper 15 and lower 16 bypass holes and a seat 17 are made for installing the sealing assembly 18, which is deflated through the pipe string 1, or interchangeable functional ABOK (not shown), in particular inserts for the registration curves recovery reservoir pressure. In the initial upper position of the supporting sleeve 14, the channels 9 and 10, respectively, of the supply of the working and pumped medium are blocked by the latter, and in the lower position of the supporting sleeve 14, its upper end is located below the inlet to the channel 9 of the working medium. In this case, the lower bypass holes 16 of the support sleeve 14 are in communication with the entrance to the channel 10 for supplying the medium pumped out of the well. The sealing assembly 18 is made in the form of a hollow stepped cylindrical body 19, in the upper part of the cavity of which a sealing element 20 is placed, and a lower piston 22 spring-loaded relative to the sealing element is located, with emphasis in an annular ledge 21 in the cavity of the housing 19 of the sealing assembly 18 20. In the wall of the housing 19 of the sealing unit 18 opposite the upper the bypass holes 15 of the support sleeve 14 made holes 23, which are blocked by a stepped piston 22 when it is in the lower position. In the upper position of the stepped piston 22 and simultaneously in the lower position of the support sleeve 14 through the holes 23 in the housing 19 of the sealing assembly 18, the upper bypass holes 15 in the support sleeve 14 and the upper window 11 in the housing 5 of the jet pump 4 channel 10 for supplying the medium pumped out of the well is communicated above the check valve 13 with the internal cavity of the pipe string 1 below the housing 5 of the jet pump 4 and at the same time the lower bypass holes 16 of the support sleeve 14 are in communication with the lower window 12 of the channel 10 for supplying the medium pumped out of the well. In the stepped piston 22 and the sealing element 20, axially axial channels are made for passing a flexible pipe 24 through which a wireline 25 is passed through. A complex wireline tool 26 is attached to the lower end of the flexible tube 24, which is connected to the wireline 25 through a cable head 27. In the wall of the flexible pipe 24 above the complex logging tool 26, holes 28 are made, by means of which the internal cavity of the pipe string 1 is in communication with the annular under-well space of the well.

Downhole jet installation operates as follows. On the pipe string 1 with a liner 29, the packer 2 and the jet pump 4 are lowered into the well, and the channels 9 and 10 are closed by the support sleeve 14. The packer 2 is unpacked and crimped by applying a working medium under pressure to the annular space relative to the housing 5 of the jet pump 4. wells. Then, an acid solution and / or fracturing fluid are pumped through the pipe string 1 into the reservoir wells and run down the pipe string 1 into the well on a flexible pipe 24, which is passed through the axial channels of the sealing element 20 and the step piston 22 of the sealing assembly 18, a complex logging tool 26 connected through a cable head 27 to the logging cable 25. The complex logging device 26 is lowered in a horizontal well until the device reaches the bottom of the well, and the sealing unit 18 is installed on the seat 17 in the supporting sleeve 14. During the descent, a complex logging device 26 is recorded geo Physically parameters, particularly pressure and temperature, in the area below the packer, including a formation zone. After that, the working medium is fed through the pipe string 1 under pressure, under the influence of which the support sleeve 14 is displaced to the sealing assembly 18 to the lower position, freeing the entrance to the working medium supply channel 9, to the nozzle 6 and communicating the upper and lower bypass openings 15 and 16 s the upper and lower windows 11 and 12 of the channel 10 for supplying the medium pumped out from the well. By supplying the working medium under pressure through the channel 9 for supplying the working medium to the nozzle 6 of the jet pump 4, the well is drained and reaction products and / or hydraulic fracturing fluid are removed from the reservoir with periodic measurement using a logging device 26 well flow rates at different depressions on the reservoir and continuous registration of bottomhole pressure, as well as the composition of the liquid medium pumped from the wellbore.

The supply of the working medium to the nozzle 6 of the jet pump 4 is abruptly stopped and the pressure recovery curve in the under-packer space of the well is recorded. Then using a flexible pipe 24 lift the logging tool 26 and press the step piston 22 from the bottom with its upper end, move it up and, thus, through the holes 23 in the wall of the housing 19 of the sealing assembly 18, the upper bypass holes 15 in the support sleeve 14 and the upper window 11 of the feed channel 10 the sub-packer space of the pumped-out medium with the inner cavity of the pipe string 1 above the jet pump 4 and the annulus above the packer 2, and, due to this, the pressure is equalized above and below the jet pump 4. Then, it is removed from the well, the logging tool 26 together with the sealing assembly 18. If necessary, additional studies can be installed instead of the sealing assembly 18 on the seat 17 in the support sleeve 14, any of interchangeable functional inserts, in particular, an insert for recording the reservoir pressure recovery curves, which allows you to expand the amount of information received about the state of the well without lifting the pipe string 1 to the surface.

INDUSTRIAL APPLICABILITY The present invention can be used in the oil and gas industry for well development after drilling or for their underground repair in order to intensify hydrocarbon production or increase the injectivity of injection wells.

Claims

 Claim

A downhole jet installation comprising a bottom-up packer mounted on a pipe string with a central channel made therein and a jet pump in which a nozzle and a mixing chamber with a diffuser are installed, the diffuser output being connected to the annular space of the pipe string, the jet pump nozzle being connected to the internal cavity of the pipe string through the channel for supplying the working medium made in the body of the jet pump, and the channel for supplying the medium pumped out of the well made in the body of the jet pump is connected to the internal the lower cavity of the pipe string through the upper and lower windows made in the jet pump housing, and a check valve is installed in the channel for supplying the pumped medium; the check valve located in the latter from the inlet side through the lower window has a fluid flow switch coaxial with the pipe string, made in the form of an axially movable support sleeve, spring-loaded relative to the housing, while the upper and lower bypass holes and a seat for mounting on the support sleeve are made it is lowered through the pipe string of the sealing unit or interchangeable functional inserts, in particular, inserts for recording the reservoir pressure recovery curves, in the initial upper position of the support sleeve, the supply channels of the working and pumped medium are blocked by the latter, and in the lower position of the support sleeve its upper end is located below the input holes in the channel for supplying a working medium, while the bypass holes of the supporting sleeve are in communication with the entrance to the channel the supply of the medium pumped out from the well, the sealing assembly is made in the form of a hollow stepped cylindrical body, in the upper part of the cavity of which a sealing element is placed, and a lower piston spring-loaded relative to the sealing element is located, with an emphasis in an annular ledge in the cavity of the housing of the sealing assembly, while in the wall of the housing of the sealing unit opposite the upper bypass holes of the support sleeve, holes are made that are blocked by a stepped piston when located it in the lower position, and in the upper position of the step piston and simultaneously in the lower position of the support sleeve through the holes in the housing of the sealing assembly, the upper bypass holes in the support sleeve and the upper window in the jet pump housing, the supply channel of the medium pumped out of the well is communicated above the non-return valve from the internal the cavity of the pipe string below the body of the jet pump and simultaneously the lower bypass holes of the support sleeve are in communication with the lower window of the supply channel of the medium pumped out of the well, while in the stupa The piston and the sealing element are provided with coaxial axial channels for passing a flexible pipe through which a logging cable passes through, a complex logging tool is fixed at the lower end of the flexible pipe, which is connected to the logging cable through the cable head, and above the complex logging tool in the wall of the flexible pipe holes are made through which the internal cavity of the pipe string is in communication with the annular under-packer space of the well.