RU2256102C1 - Ejector multifunctional formation tester for testing and completion of horizontal wells - Google Patents

Abstract

FIELD: oil producing jet units.

SUBSTANCE: proposed formation tester contains jet pump, unit for connecting and disconnecting tubing string, valve unit with seat for valve insert with check valve, packer and liner with intake funnel, all mounted on tubing string from top to bottom. Jet pump housing accommodates coaxially installed active nozzle and mixing chamber, and channels are made to deliver active medium, pumped out of well and stepped through channel with seat between steps. Possibility is provided for in-turn mounting of sealing unit and interlock insert with through channel which are arranged on flexible smooth pipe higher than tip for connecting self-contained logging complex and insert for recording pressure built-up curves I underpacker space of well under which self-contained instruments are installed for recording pressure, temperature and other physical parameters of well and forming fluids. Invention provides intensification of investigation, testing and preparation of wells, mainly, horizontal and high curvature wells, optimization of operation of jet pump used together with self-contained logging complex and other functional insets for investigation of producing formation.

EFFECT: improved reliability and increased capacity of operation.

3 cl, 3 dwg

Description

The invention relates to the field of pumping technology, mainly to downhole jet installations for oil production from wells.

A well-known jet installation containing a tubing string with a jet pump, a packer and a perforator with the ability to pump liquid working medium through the jet pump (see copyright certificate SU 1146416, E 21 B 43/116, 03/23/1985).

This downhole jet installation allows perforation of the well and, due to this, to intensify the pumping of various production media, for example oil, from the well, however, this installation does not allow the study of the near-borehole formation zone, which in some cases leads to a decrease in the efficiency of work to intensify the work of the well due to lack of information on how productive formations work. Thus, the efficiency of the well drainage work does not give the expected results.

Closest to the invention in terms of technical nature and the achieved result is an installation comprising a packer with a central channel and a jet pump with an active nozzle, a mixing chamber and a passage channel with a seat for installing a sealing unit with an axial channel mounted on a tubing string. the installation is equipped with a transmitter and a receiver-converter of physical fields located in a sub-packer area from the side of the entrance to the jet pump of the medium pumped out of the well and installed m on a logging cable that is passed through the axial channel of the sealing unit, and the outlet of the jet pump is connected to the space surrounding the pipe string, the input of the supply channel of the pumped medium of the jet pump is connected to the inner cavity of the pipe string below the sealing unit, and the input of the liquid supply channel to the active nozzle is connected to the inner cavity of the pipe string above the sealing unit, (see patent RU 2121610, F 04 F 5/02, 10.11.1998).

This installation allows you to carry out various technological operations in the well below the installation level of the jet pump, including by reducing the pressure drop above and below the sealing unit. However, this setup allows the study of productive rocks only in trunks close to vertical, which narrows the scope of use of this setup. In addition, the scope of work that could be carried out in a well without raising the installation to the surface is limited, which lengthens the time for testing and development of wells.

The task to which the present invention is directed is to intensify research, testing and preparation of wells, primarily horizontal and large curvature wells, to optimize the operation of a jet pump when used in conjunction with an autonomous well logging complex and other functional inserts for studying the reservoir and due to this, increasing the reliability and productivity of the ejector multifunctional reservoir tester.

This problem is solved due to the fact that the ejector multifunctional formation tester for testing and developing horizontal wells contains a jet pump mounted top down on the pipe string, a unit for disconnecting and connecting the pipe string, a valve assembly with a seat for installing a valve insert with a check valve, a packer and a shank with an inlet funnel, moreover, an active nozzle and a mixing chamber are coaxially mounted in the jet pump housing, and an active medium supply channel is made, the supply channel is pumped out the medium flowing from the well and a stepped passage channel with a seat between the steps, while in the stepped passage channel it is possible to install a sealing unit and a blocking insert with a through channel, which are placed on a flexible smooth pipe above the tip for connecting an autonomous logging complex, as well as an insert for registration of reservoir pressure recovery curves in the under-packer space of the well, under which autonomous instruments for recording pressure are installed , temperature and other physical parameters of the well and reservoir fluids, bypass channels are installed in the insert and a bypass valve is installed to equalize the pressure below and above the insert, the jet pump outlet is connected to the inner cavity of the pipe string above the sealing unit, the active nozzle of the jet pump through the active medium supply channel connected to the annulus of the pipe string, a channel for supplying a medium pumped out from the well is connected to the internal cavity of the pipe string below the sealing assembly, the diameter the channel of the sealing unit is larger than the outer diameter of the flexible pipe by at least 0.2 mm, the outer diameter of the flexible pipe is from 0.4 to 0.95 of the diameter of the passage channel of the blocking insert, and the flexible smooth pipe is made of a composite material reinforced with a conductive wire with the possibility of its use for electrical communication of an autonomous logging complex with a logging laboratory on the surface.

In the transport position, a flexible smooth pipe can be wound on a drum of a winch located on the chassis of a vehicle, such as a car, and a flexible smooth pipe on the side of its lower end can be made with holes in its wall.

Analysis of various designs of the ejector reservoir tester showed that its reliability can be improved both by increasing the functionality of the installation, and by optimizing the structural elements and the sequence of actions during testing and development of wells, primarily with an open and / or curved wellbore.

It was revealed that the above set of structural elements of the test tester allows you to organize a sequence of actions in which the equipment that is installed on the pipe string when conducting research, testing and development of productive rock formations is most effectively used. At the same time, conditions have been created both for obtaining complete and reliable information about the state of productive formations, and for conducting processing of productive formations during the study. The reservoir tester makes it possible to create a series of different depressions using a jet pump in the sub-packer zone of the well with a given pressure drop, and using an autonomous logging complex and an insert for recording reservoir pressure recovery curves with autonomous instruments installed underneath it, conduct research and testing of the well. At the same time, it is possible to control the magnitude of depression by controlling the rate of pumping of the liquid working medium. During the formation test, it is possible to adjust the pumping mode by changing the pressure of the liquid working medium supplied to the jet pump nozzle. The installation of the logging complex on a flexible smooth pipe, which is passed through the sealing unit with the possibility of axial movement, allows for better work on the well research using geophysical methods, and the installation of a blocking insert with a flexible smooth pipe passing through it allows processing to be performed without reinstalling the well wells, and first of all, productive strata of the well to increase their productivity, which ultimately allows to accelerate and simplify the process of testing and preparing the well for work.

To increase the reliability of the installation and reduce the influence of overflows on the test results and accelerate the testing, it is necessary to provide strictly defined size ratios. The most critical in this regard are the ratio of the size of the diameter of the axial channel of the sealing unit and the passage channel of the blocking insert with respect to the outer diameter of the flexible smooth pipe. It was found that it is most expedient that the diameter of the axial channel of the sealing unit be greater than the outer diameter of the flexible pipe by at least 0.2 mm, and the outer diameter of the flexible pipe is from 0.4 to 0.95 of the diameter of the passage channel of the blocking insert. In this case, it is advisable that the flexible smooth pipe was made of a composite material reinforced with a conductive wire with the possibility of its use for electrical connection of an autonomous logging complex with a logging laboratory on the surface.

In the transport position, a flexible smooth pipe can be wound on a drum of a winch located on the chassis of a vehicle, such as a car, which makes it possible to accelerate installation of the installation. And the implementation of a flexible smooth pipe from the side of its lower end with holes in its wall allows you to process the borehole zone of the reservoir with liquid agents without dismantling or reinstalling the equipment. As a result, intensification of work on research and development of wells is achieved.

Thus, this ejector multifunctional formation tester for testing and developing horizontal wells allows for qualitative research and testing of wells after drilling and during overhaul, as well as preparing the well for operation with comprehensive research and testing in various modes.

As a result, the achievement of the objective of the invention was achieved — the intensification of research and testing of wells with a horizontal, including open hole, as well as the optimization of the operation of the jet pump during its operation together with the logging system and functional inserts, and thereby increasing the reliability of the ejector formation tester .

Figure 1 shows a longitudinal section of a tester with a sealing unit. Figure 2 shows a longitudinal section of a reservoir tester with an insert for recording the reservoir pressure recovery curve. Figure 3 presents a longitudinal section of a tester with a blocking insert.

An ejector multifunctional formation tester for testing and developing horizontal wells comprises a jet pump 2 mounted from top to bottom on a pipe string 1, a node 3 for disconnecting and connecting the pipe string 1, a valve assembly 4 with a seat 5 for installing a valve insert with a check valve 6, a packer 7 and a shank 8 with an inlet funnel 9. An active nozzle 11 and a mixing chamber 12 are coaxially mounted in the housing 10 of the jet pump 2, and a channel for supplying the active medium 13, a channel 14 for supplying the medium pumped out of the well and the steps are made a nasal passage channel 15 with a seat between the steps, while in the step passage channel 15 it is possible to install a sealing assembly 16, which is movably placed on a flexible smooth pipe 17 above the tip for connecting an autonomous logging complex 18, functional inserts: blocking 19 with a through passage bypass channel 20, and insert 21 for recording the curves of reservoir pressure recovery in the under-packer space of the well together with autonomous instruments (for example, a manometer, thermo meter and flow meter) 22 and bypass valve 25. The output of the jet pump 2 is connected to the inner cavity of the pipe string 1 above the sealing assembly 16, the active nozzle 11 of the jet pump 2 is connected to the annulus of the well (pipe string 1) through the channel 13 for supplying the active medium and the channel 14 for supplying the medium pumped out from the well, it is connected to the inner cavity of the pipe string 1 below the sealing assembly 16.

The diameter (D) of the axial channel of the sealing assembly 16 is greater than the outer diameter (D ₁ ) of the flexible smooth pipe 17 by at least 0.2 mm, the outer diameter of the flexible pipe 17 is from 0.4 to 0.95 of the diameter (D ₂ ) of the passage channel 20 of the blocking insert 19, and the flexible smooth pipe 17 is made of a composite material reinforced with a conductive wire, which allows it to be used for electrical communication of an autonomous logging complex 18 with a logging laboratory on the surface.

The flexible pipe 17 from the side of its lower end can be made with holes 23 in its wall. In the transport position, a flexible smooth pipe can be wound on a drum of a winch located on the chassis of a vehicle, such as a car (not shown in the drawing).

The operation of the ejector multifunctional formation tester for testing and developing horizontal wells of a downhole jet installation consists in assembling a pipe string 1 in the following sequence: a jet pump 2, unit 3 are installed from top to bottom for disconnecting and connecting the pipe string 1, valve assembly 4 with a seat 5 for installing a valve insert with a check valve 6, a packer 7 and a shank 8 with an inlet funnel 9. When lowering, the packer 7 is installed above the roof of the reservoir 24. After this, the packer 7 is unpacked and run into the well on the flexible pipe 17 of the autonomous logging complex 18 with the sealing assembly 16 movably placed above it on the flexible pipe 17, which is installed on a seat in the passage channel 15 of the jet pump 2, and the autonomous logging complex 18 is located in the zone of the reservoir 24. During the descent, the autonomous logging complex 18 records the background values of the physical fields of rocks, for example a thermal field, along the wellbore. Next, the jet pump 2 by feeding a liquid working medium into the active nozzle 5 creates a depression on the reservoir 18, draining it in this way, and when the jet pump 2 is operating, the current values of the rock physical fields and the formation fluid entering the well are recorded, and during registration by means of the flexible pipe 17, the autonomous logging complex 18 is moved along the wellbore, including the reservoir 24. Then, the autonomous logging complex 18 is removed from the well together with the flexible pipe the battlefield 17 and the sealing assembly 16 and install an insert 21 in the passage channel 15 of the jet pump 2 for recording the reservoir pressure recovery curves in the under-packer space with an autonomous pressure gauge 22 and, by supplying a liquid working medium to the active nozzle 11 of the jet pump 2, the formation is drained with a phased creation less than three successively increasing values of depression on the reservoir 24, recording at each of them bottomhole pressure, well production, composition and physical parameters of the incoming 24 fluid from the reservoir. Next, a hydrodynamic cyclic effect on the reservoir 24 is carried out to clean its borehole zone from clogging particles by creating at least five cycles of depression + repression, moreover, depression is created by supplying an active medium to the nozzle 11 of the jet pump 2, and repression when the jet pump 2 is stopped and by opening after that, in box 21 for recording the recovery curves of the reservoir pressure of the bypass valve 25, and then re-pumping the medium extracted from the well with a phased creation of at least three incrementally increasing in magnitude of depression values to reservoir 24, recording bottomhole pressure, well production rate, composition and physical parameters of fluid entering the reservoir with each of them, and after reaching the last highest value of depression, the flow of liquid medium into the nozzle 11 of the jet pump 2 is abruptly stopped registration of the reservoir pressure recovery curve in the under-packer space of the well, and the hydrodynamic test cycle described above is repeated until the well’s productivity is e last cycle hydrodynamic tests did not reach the design values. Next, an insert 21 is removed for recording the reservoir pressure recovery curves in the under-packer space together with an autonomous pressure gauge 22 and a blocking insert 19 with a bypass channel 20 is thrown into the well, which is seated on a seat in the passage channel 15 of the jet pump 2 and, thus, the internal cavity is disconnected pipe string 1 and the space surrounding pipe string 1. Then 24 chemical reagents or hydraulic fracturing fluid with proppant are injected into the reservoir, blocking insert 19 is removed and dumped they insert into the pipe string 1 a valve insert with a non-return valve 6, which is seated on a seat in the valve assembly 4, and then insert 21 into the pipe string 1 for recording the reservoir pressure recovery curves in the under-packer space of the well with an autonomous pressure gauge 22 and by feeding under pressure liquid medium into the active nozzle 11 of the jet pump 2, 24 products of the reaction of chemicals or hydraulic fracturing with residues of proppant are pumped out from the reservoir, then it is carried out by feeding the liquid medium into the active nozzle of a jet pump 2, drainage of formation 24 with the phased creation of at least three successively increasing values of depression on formation 24, recording downhole pressure, well production, composition and physical parameters of the fluid entering the formation with each of them, and after reaching the last highest value of depression, sharply stop the flow of fluid into the nozzle 11 of the jet pump 2 and register the recovery curve of reservoir pressure in the under-packer space of the well, then insert 21 for register the formation pressure recovery curves in the under-packer space of the well together with an autonomous pressure gauge 22 and raise the jet pump 2 with a part of the pipe string 1 above the assembly 3 to disconnect and connect the pipe string 1, leaving a liner 9 with a packer 7 and a valve assembly with a check valve 6 , thus preventing the penetration of 24 working agent into the reservoir. Then the pump is lowered into the well on the pipe string 1 to extract liquid from it (not shown in the drawing) and the pipe string 1 is connected in node 3 to disconnect and connect the pipe string, after which the well is put into operation.

After the blocking insert 19 is planted through the latter, descent into the well into the zone of the productive formation 24 of the flexible pipe 17 can be carried out and, after the last, chemical reagents or hydraulic fracturing fluid with proppant are injected into the formation 24, as well as washing the bottom of the well from sand plugs.

The present invention may find application in the oil industry for testing and development of horizontal and curved wells, as well as in other industries where various media are produced from wells.

Claims (3)

1. An ejector multifunctional formation tester for testing and developing horizontal wells, comprising a jet pump mounted top down on the pipe string, a unit for disconnecting and connecting the pipe string, a valve assembly with a seat for installing a valve insert with a check valve, a packer and a shank with an inlet funnel, moreover, an active nozzle and a mixing chamber are coaxially mounted in the jet pump housing, and a channel for supplying an active medium, a channel for supplying a medium pumped out of the well, and a step the passage channel with a seat between the steps, while in the step passage channel, it is possible to install a sealing unit and a blocking insert with a through channel, which are placed on a flexible smooth pipe above the tip for connecting an autonomous logging complex, as well as an insert for recording pressure recovery curves in the under-packer space of the well, under which autonomous devices are installed for recording pressure, temperature and other physical vapor meters of the well and reservoir fluids, bypass channels are installed in the insert and a bypass valve is installed to equalize the pressure below and above the insert, the outlet of the jet pump is connected to the inner cavity of the pipe string above the sealing unit, the active nozzle of the jet pump is connected to the annulus of the column through the inlet of the active medium pipes, the channel for supplying the medium pumped out from the well is connected to the internal cavity of the pipe string below the sealing unit, the diameter of the axial channel of the sealing unit is pain the outer diameter of the flexible pipe is not less than 0.2 mm, the external diameter of the flexible pipe is from 0.4 to 0.95 the diameter of the passage channel of the blocking insert, and the flexible smooth pipe is made of a composite material reinforced with a conductive wire with the possibility of using it for electrical connection of an autonomous logging complex with a surface logging laboratory. 2. The tester according to claim 1, characterized in that in the transport position a flexible smooth pipe is wound on a winch drum located on the chassis of a vehicle, such as a car. 3. The tester according to claim 1, characterized in that the flexible smooth pipe from the side of its lower end is made with holes in its wall.

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