RU2795009C1 - Method for well exploration and stimulation of oil and gas inflows and a jet pump for its implementation - Google Patents

Abstract

FIELD: testing wells; intensifying oil and gas inflows.

SUBSTANCE: method for testing wells and intensifying oil and gas inflows and a jet pump for its implementation. Packer with a jet pump is lowered into the well on a tubing string. The packer is activated above the top of the reservoir. An acid solution is fed into the productive formation through the passage channel and the sealing sleeve. A depression insert is lowered into the tubing string. Under pressure, the working fluid is fed into the tubing string. The working fluid is supplied through the annulus and the reaction products of the acid solution are taken from the formation. Pressure is equalized above and below the depression insert. The depression insert is removed. A geophysical instrument and a sealing unit are lowered through the tubing string on a cable. Background recording is conducted. Working fluid is supplied under pressure through the annulus. The inflow profile is recorded. The flow of working fluid into the annulus is stopped. The sealing assembly and the geophysical instrument are removed. The packer is deactivated, and the jet pump is removed.

EFFECT: creating a method for geophysical exploration of wells, which cleans the well environment and uses a jet pump, with a reduced accident rate when working in difficult conditions in a partially cased or contaminated well.

10 cl, 7 dwg

Description

The invention relates to the production of oil and gas from boreholes, in particular to methods and means for geophysical survey of partially cased open-ended wells and wells with partially cased sidetracks using downhole equipment containing jet pumps.

Such wells are characterized by a large number of mechanical inclusions that can clog or damage downhole equipment. During geophysical control of partially cased wells, various methods are used to assess the current oil and gas saturation of productive formations and study their operational characteristics, including the identification of inflow and injectivity intervals of formations with the identification of zones of fluid manifestations and absorption of flushing fluid, the identification of intervals of occurrence of rocks with high rheological properties, subject to rapid and intense erosion or buckling, etc.

After drilling wells and opening horizons promising for oil and gas, tests are carried out using instruments lowered into the well on a cable or test cable. With the help of the study of partially cased wells, such important geological and physical parameters of the reservoir are determined as the permeability in the drainage zone, the productivity factor of the test interval, reservoir pressure, hydraulic conductivity coefficient, the state of the bottomhole zone, etc.

When conducting geophysical surveys, it is advisable to use jet pumps, which makes it possible to carry out combined technological operations in wells, while solving the problems of intensification of inflow and conducting field geophysical surveys, and the use of functional inserts, for example, sealing, depression, etc., allows you to create an alternation of different modes .

Downhole equipment used for geophysical surveys, as a rule, includes a jet pump and a packer lowered into the well on tubing.

The prior art well-known jet installation designed for testing and development of wells (RF patent for the invention No. 2320899, publ. 27.03.2008, bull. No. 9). The known installation contains a packer with a central channel mounted on a pipe string and a jet pump, in the body of which a nozzle and a mixing chamber with a diffuser are installed. The outlet of the diffuser is connected to the annulus of the pipe string. The nozzle of the jet pump is connected to the inner cavity of the pipe string through the working medium supply channel made in the jet pump housing. The channel for supplying the medium pumped out from the well, made in the jet pump housing, is connected to the inner cavity of the pipe string through the upper and lower windows made in the jet pump housing. In the channel for supplying the pumped medium, a check valve is installed, located in the latter from the side of its inlet through the lower window. In the body of the jet pump, coaxially with the pipe string, there is a switch for the flow of the working medium, made in the form of an axially movable support sleeve, spring-loaded relative to the body. The support sleeve has upper and lower bypass holes and a seat for installing a sealing assembly or replaceable functional inserts (not shown in the drawing), in particular, an insert for recording reservoir pressure recovery curves.

In the initial position, the support sleeve blocks the channels for supplying the working and pumped medium. In the lower position of the support sleeve, its upper end is located below the inlet to the channel for supplying the working medium, while the lower bypass holes of the support sleeve are in communication with the inlet to the channel for supplying the medium pumped out of 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. Below in the cavity there is a stepped piston with an emphasis on the annular ledge, spring-loaded relative to the sealing element, while in the wall of the body of the sealing assembly opposite the upper bypass holes of the support sleeve, holes are made that are blocked by the stepped piston when it is in the lower position.

In the upper position of the stepped piston and at the same time in the lower position of the support sleeve, the borehole fluid supply channel is connected through the holes in the sealing assembly housing, the upper bypass holes in the support sleeve and the upper window in the jet pump housing with the internal cavity of the pipe string below the jet pump housing. At the same time, the lower bypass holes of the support sleeve are in communication with the lower window of the channel for supplying the pumped out well fluid.

In the stepped piston and the sealing element, coaxial axial channels are made for passing a logging cable through them, on which a logging tool is suspended by means of a cable head. In the initial upper position of the support sleeve, the channels for supplying the working medium and the medium pumped out of the well are blocked by the latter, and in the lower position of the support sleeve, its upper end is located below the inlet to the working medium supply channel.

In a well-known jet pump, the inner surface of the sleeve has a seat in the form of an annular protrusion, on which the sealing assembly rests, while it descends along the tubing on the cable, which can lead to the fact that the location of the sealing assembly relative to the sleeve is not coaxial and mutual engagement of these parts is possible each other's annular protrusions.

In addition, under operating conditions in a partially cased well, mechanical particles suspended in the well fluid can settle on the inner surface of the sleeve. Contamination of the bushing stage can lead to jamming of the sealing assembly in the casing, breakage of the geophysical cable during its extraction, and an accident due to leaving parts of the cable inside the tubing.

Known downhole jet installation designed for testing and development of wells used in logging operations (RF patent for the invention No. 2334130, publ. 20.09.2008, bull. No. 26).

The downhole jet installation comprises a jet pump and a packer mounted on a pipe string, and an active nozzle and a mixing chamber with a diffuser are coaxially installed in the jet pump housing, and a stepped passage channel with a seat is made. In addition, the installation contains a channel for supplying the medium evacuated from the well, communicated below the seat by means of side holes in the jet pump housing with a stepped passage channel and an active working medium supply channel, communicated from the side of its exit with an active nozzle and from the side of its inlet with annular space of the pipe string. The channel for supplying the pumped out medium is connected through a check valve with a pipe string below the stepped passage channel, in which it is possible to install a sealing unit.

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 located, and below in the cavity there is a stepped piston, spring-loaded by means of a spring relative to the sealing element, resting against the annular ledge in the cavity of the sealing assembly body.

Holes are made in the wall of the housing of the sealing unit opposite the side holes of the jet pump housing. In the lower position of the stepped piston, the holes in the wall of the sealing unit body are blocked, and in the upper position of the stepped piston, through the side holes in the jet pump body and the holes in the wall of the sealing unit body, the channel for supplying the medium pumped out from the well is connected with the pipe string below the jet pump body.

In the stepped piston and the sealing element, coaxial axial channels are made for passing a logging cable through them, on which a logging tool is suspended by means of a cable head below the jet pump housing with the possibility of its movement along the well and its location in the productive formation zone. A check valve is installed in the active working medium supply channel, the packer is made with an axial through hole, and the diameter d of the stepped through passage below the seat is not less than the diameter D of the packer axial through hole.

When operating a downhole jet unit according to the patent of the Russian Federation No. 2334130 in a partially cased well, in which there are impurities and mechanical impurities with a particle size often exceeding the diameter of the jet pump nozzle, the injection of the working fluid through the annulus contributes to the ingress of debris into the nozzle, which blocks the movement of the working fluid and causes the device to stop working.

In addition, the passage channel of the jet pump housing is made stepped. Between the steps there is a seat in the form of an annular protrusion. On the inner surface of the body, near the stage and ledge, mechanical particles are also accumulated, which are in suspension in the well fluid. Contamination of the passage channel of the body leads to rapid wear of the jet pump, as well as to jamming of the sealing unit, breakage of the geophysical cable during its extraction and, as a result, to an emergency.

The disadvantage is also that due to the rigidity of the cable, the sealing assembly is not lowered along the tubing coaxially, while the installation of the sealing assembly in the seat on the inner surface of the body can lead to mutual engagement of the sealing assembly with the body, and difficulties with fitting the sealing assembly into the body .

The closest in technical essence is the method of development, testing of wells and intensification of oil and gas inflows, including lowering the hollow body of the device with a packer into the well on tubing pipes (RF patent for the invention No. 2160364, publ. 10.12.2000, bull. 34) . The method is implemented as follows.

To approach the productive formation, the jet pump is lowered and set in the device housing under the packer and the cable is sealed.

Next, the working fluid is supplied through the annular space between the production string and the tubing string to the jet pump, while the working fluid is supplied to the jet pump from the above-packer space to the under-packer space through the channel, which, if necessary, is increased. The direction of flow of working and reservoir fluids is changed before entering the jet pump.

Then, the formation fluid is pumped out by a jet pump, the mixed fluid is supplied to the surface, and field information is transmitted via a cable. In the perforation interval of the productive formation, the cable is moved in one trip of the device.

To implement the method, a device is used that contains a hollow body connected to the tubing string with axial and radial channels. The housing contains a plug-in jet pump, a non-return valve and a cable lug with recording devices. The device is configured to lower and seat the jet pump under the packer to form a channel for supplying the working fluid from the annulus to the space under the packer.

The jet pump is equipped with a lock to secure it and a puller to remove it when lifting it. In addition, the jet pump is equipped with a check valve with a spring mounted above it. In the lower part of the hollow body of the device, under the jet pump, there is a sealing unit with a lock and a puller.

A device for development, well testing and stimulation of oil and gas inflows, consisting of a valve sub, a hollow body packer, a liner, is lowered on the tubing string 1 into the production string to the estimated depth. The packer is installed above the productive formation for a closer location of the jet pump to the productive formation.

After separation of the annular space by the packer, the packer and the tubing string are checked for tightness. To do this, fluid is pumped into the tubing and a pressure of the required value is created, and the initial permeability of the formation is also determined.

Then, a jet pump is lowered on a logging cable, containing a check valve with a spring and a screen passing through the check valve opening, an internal guide vane, a jet pump puller, a cable sealing tip with a geophysical instrument.

By creating pressure in the tubing, the jet pump is seated in the seat and fixed in the annular groove with a lock. Similarly, the sealing assembly is installed on the other saddle, sealing the axial channel of the hollow body and the logging cable. With the help of ground pumping units, the working fluid is supplied to the cavity between the tubing string 1 and the production string. The working fluid enters through the valve system into the annular channel formed by the separation pipe, the valve sub housing, the packer rod, enters the cavity under the jet pump and the guide vane, where the profiled vanes swirl the flow of the working fluid and direct it to the jet pump nozzle.

The swirling flow of working fluid flows out of the nozzle at a higher speed and ejects formation fluid from the under-packer space, which enters the annular mixing chamber of the jet pump through the radial channels of the hollow body, where it mixes with the working fluid, while the formation fluid, when moving in the annulus, is twisted by profiled blades external guide vanes. The swirling flows of the working and reservoir fluids have a higher speed than direct flows and therefore the productivity of the jet pump is higher than usual, while the cable is covered with a screen, which reduces friction losses. The mixed flow of working and reservoir fluid enters the diffuser of the jet pump, opens the check valve, while the spring softens the hydraulic shock of the check valve, and the stop of the jet pump keeps it in the open position.

By pumping the working fluid through the jet pump, the liquid is pumped out from the under-packer space, the pressure in the productive formation zone is reduced, creating a depression in the under-packer space, which is controlled by changing the operating pressure by the pumping unit on the surface of the well.

The pressure in the pay zone is recorded by a logging station, the signals to which are received via a logging cable from the recording instruments. To record reservoir pressure recovery curves, the operation of the surface pumping unit is stopped and the fluid flow from the annulus is blocked by the valve system, while the jet pump stops working, and the check valve, under the action of the hydrostatic liquid column in the tubing string, closes the diffuser of the jet pump, thereby sealing the sub-packer zone .

The pressure in the under-packer zone is gradually restored due to the influx of fluid from the reservoir. This change is transmitted to the recording device, and the formation pressure recovery curves are recorded at the surface logging station. A logging cable with a geophysical instrument is raised and lowered over the entire interval of the under-packer space, carrying out the necessary complex of geophysical surveys of the well. At the end of the work, using a logging cable, the jet pump is taken to the surface along with the sealing unit and the geophysical instrument.

The disadvantage of known technologies is the absence of actions that increase the intensification of oil and gas inflows (acid treatment and extraction of reaction products), which reduces the efficiency of geophysical surveys.

In addition, downhole equipment containing jet pumps and used for geophysical research is characterized by low reliability, the complexity of the design of jet pumps and is not suitable for conducting studies of productive formations in contaminated wells.

The objective of the invention is to improve the efficiency and quality of geophysical exploration of wells and the creation of a jet pump that saves downhole equipment used for these purposes.

The technical result is the creation of a method for geophysical exploration of wells, which cleans the well environment and uses a reliable jet pump with high performance, by reducing accidents when working in difficult conditions in a partially cased or contaminated well.

The technical result is achieved by the fact that the method of testing wells and intensifying oil and gas inflows consists in lowering a packer and a jet pump with an axial flow channel into the well on a tubing string. A feature of the method is that the actions are carried out using a jet pump, in the body of which there is a channel for the removal of a liquid medium, in which a check valve is installed, a channel for supplying a working medium, in which a diffuser and a mixing chamber with a nozzle are installed, and a seat for a sealing sleeve, installed in the passage channel with the possibility of axial movement. The next step after running the packer and the jet pump is to activate the packer above the top of the productive formation and hermetically separate the above-packer and under-packer space. Further, through the passage channel and the sealing sleeve, an acid solution is fed into the productive formation and the technological time of the acid solution exposure is maintained. Then, a depression insert is lowered into the tubing, containing a housing with radial holes, which moves along the jet pump passage channel until it contacts the sealing sleeve. After that, a working fluid is fed into the tubing under pressure, under the influence of which the depression insert interacting with the sealing sleeve moves it to the seat. Next, the working fluid is supplied through the annulus, creating a reduced pressure in the productive formation zone, and the working fluid is filtered through a filter installed on the outer surface of the jet pump, and the reaction products of the acid solution are taken from the formation through the mixing chamber and the diffuser. Then the pressure is equalized in the space above and below the depression insert and it is removed from the well. After that, a geophysical instrument and a sealing assembly are lowered through the tubing on a cable, containing a housing in which a bypass channel is made, hydraulically connecting the cavities above and below the sealing assembly and blocked during the operation of the jet pump by a spring-loaded piston placed in the sealing assembly with the possibility of axial movement. Then, background recording is carried out by moving the geophysical instrument along the interval of the productive formation to be investigated. Further, a working fluid is supplied under pressure through the annulus, which, flowing through the nozzle, mixing chamber and diffuser, causes the inflow of formation fluid, and the inflow profile is recorded by moving the geophysical instrument along the interval of the studied formation. Upon completion of the measurements, the supply of working fluid to the annulus is stopped, pressure is equalized above and below the sealing unit by tensioning the cable, and the sealing unit and the geophysical instrument are removed. After that, the packer is deactivated and the jet pump is removed from the well.

The depression insert is removed using a catcher on the cable, while under the tension of the cable, the depression insert sleeve is displaced and opens the upper radial openings of the body, through which the pressure is equalized in the space above and below the depression insert.

The sealing sleeve is installed in the seat when the locking element is destroyed.

Hydraulic connection of the under-packer space with the check valve channel is provided through radial holes made in the body of the sealing unit.

The fulfillment of the task and the achievement of the technical result is also achieved by the fact that the jet pump for implementing the method comprises a hollow body, in the central passage channel of which a sealing sleeve is installed. In addition, an active nozzle, a mixing chamber with a diffuser are coaxially located in the jet pump housing, and a channel is made in which a check valve is located. A feature of the jet pump is that in the central passage channel, made with a flat surface, it is possible to alternately install a depression insert and a sealing assembly, while a filter is installed on the outer surface of the housing. The depression insert includes a housing and a bushing mounted with the possibility of axial displacement relative to it. The depression insert body has a lower radial hole forming a formation fluid removal channel, and upper radial holes forming a working fluid supply channel through the internal cavities of the pump into the under-packer space to equalize the pressure above and below the depression insert. The sealing assembly comprises a housing in which a bypass channel and a cavity with a piston placed in it with the possibility of axial movement and held by a spring are made. In addition, radial holes are made in the body of the sealing unit, forming a reservoir fluid selection channel at the lower position of the piston, in which the extraction is carried out through the check valve channel and the bypass channel, and when mixed with the working fluid entering through the annulus, through the mixing chamber, the diffuser and tubing cavity. The upper position of the piston opens the access of the working fluid to the space under the packer through the bypass channel to equalize the pressure in the space above and below the sealing unit;

The channel for supplying the working fluid through the annulus is formed by a nozzle, a mixing chamber and a diffuser and a channel connected to the central flow channel of the jet pump.

The sealing assembly is installed on the geophysical cable with the possibility of axial movement, and the geophysical instrument is fixed on the lower end of the geophysical cable.

The sealing sleeve is fixed in the jet pump housing by a destructible element. The check valve is equipped with a ball. The filter, mounted on the outer surface of the housing, is located in front of the nozzle inlet.

The initial installation of a drawdown insert provides stimulation of the reservoir inflow, including preliminary cleaning from reaction products, which increases the permeability of the bottomhole formation zone and creates improved conditions for subsequent qualitative and informative geophysical research.

The design of the jet pump, containing a casing with a stepless inner surface, reduces the risk of jamming when installing a depression insert and subsequent installation of a sealing assembly.

The presence of a filter on the jet pump housing further reduces the accident rate in a contaminated well due to the filtration of circulating fluids entering the internal cavities of the pump and tubing.

In FIG. 1 shows a section of a jet pump with a sealing sleeve fixed in the upper position; in fig. 2 is a section of a jet pump with a depression insert installed in its housing and an illustration of the movement of liquid during the selection of reaction products; in fig. 3 is a general view of the jet pump with a filter installed on its housing; in fig. 4 is a sectional view of a jet pump with a depression insert and an illustration of the movement of fluid during pressure equalization; in fig. 5 is a sectional view of a jet pump with a sealing assembly and an illustration of the movement of fluid during a well survey; in fig. 6 is a sectional view of the sealing unit and an illustration of the movement of the working fluid during pressure equalization; in fig. 7 is a section along A-A (Fig. 5), which shows a channel connecting the cavities above and below the sealing assembly.

The jet pump lowered into the well on the tubing 1 consists of a hollow body 2, the central passage channel 3 of which is made with a flat surface, a sealing sleeve 4, a depression insert 5 and a sealing assembly 6. A channel 7 is made in the casing wall, in which a nozzle 8 is placed , a mixing chamber 9 and a diffuser 10. In addition, a channel 11 is made in the wall of the housing 2, in which a check valve 12 with a ball 13 is placed, while the cavity of the check valve is connected to the mixing chamber 9 through a bypass channel 14. The sealing sleeve 4 is fixed on the housing 2 using a destructible element 15 (Fig. 1).

The depression insert 5, which is lowered through the tubing 1, is installed on the sealing sleeve 4, displacing it until it stops 16, made on the inner surface near the lower edge of the housing 2, and contains the housing 17, in which the upper radial holes 18 and the lower hole 19 are made in contact with the channel 11 check valve 12 (Fig. 4). Equalizing sleeve 20 is installed on the body 17 with the possibility of axial displacement, blocking the upper radial holes 18 (Fig. 2).

The sealing assembly 6, which is lowered through the tubing 1 on the geophysical cable 21, is installed on the sealing sleeve 4 after the extraction of the depression insert 5 and contains a body 22 fixed with the possibility of axial movement on the geophysical cable 21, in which a bypass channel 23 is made, hydraulically connected to the central passage channel 3 of the body 2. In addition, a cavity 24 is made in the housing 22, in which a piston 25 is placed with the possibility of axial movement, held by a spring 26. The cavity 24 is connected to the channel 11 of the check valve 12 through radial holes 27. A geophysical instrument 28 is fixed on the geophysical cable 21, located under the sealing unit 6 (Fig. 5). On the outer surface of the lower part of the housing 2 of the jet pump, a filter 29 is fixed, hydraulically connected to the nozzle 8 (Fig. 3).

The implementation of the method and the operation of the jet pump are implemented as follows. A method for well exploration and stimulation of oil inflows in a partially cased or contaminated well begins with running a packer onto the tubing 1, for example, a 5POM mechanical packer (not shown in the figures), and a jet pump, in the hollow housing 2 of which the sealing sleeve 4 is fixed with the help of a destructible element 15 blocking channel 7 and channel 11 of the check valve 12. The packer is installed above the roof of the productive formation and activated, hermetically separating the above-packer and under-packer space.

Next, the bottomhole zone of the productive formation is treated by supplying an acid solution 30 through the central passage channel 3 and the sealing sleeve 4 and maintaining the process time required for the acid solution to act on the formation (Fig. 1).

After acid treatment, a depression insert 5 is lowered into the tubing, containing a housing 17 with radial holes 18, which moves along the central passage channel 3 of the jet pump to contact with the sealing sleeve 4, while the radial holes 18 of the housing are blocked by the equalizing sleeve 20.

Further, working fluid 31 is fed into the tubing under pressure, under the influence of which the depression insert 5 interacts with the sealing sleeve 4 and moves it to the seat in the form of a stop 16, destroying the element 15. the insert communicates with the channel 11 of the check valve 10, providing hydraulic communication with the mixing chamber 9 and the diffuser 8 through the bypass channel 14 (Fig. 2 and Fig. 7).

After installing the sealing sleeve 4 and the depression insert 5, the working fluid 31 is supplied under pressure into the annulus, when it passes through the filter 29 installed on the outer surface of the jet pump housing and the nozzle 8, due to the ejection effect, a reduced pressure is created in the zone of the productive formation. pressure and filtration of the working fluid 31 is provided (Fig. 2 and Fig. 3) At the same time, formation fluid 33 (reaction products of the acid solution from the formation) is taken off by mixing the filtered working fluid 31 moving through the nozzle 8, and the formation fluid 33 moving through the sealing sleeve 4, the lower opening 19 of the body 17 of the depression insert 5, the channel 11 of the check valve 12 and the bypass channel 14. The well fluid 32 formed in the mixing chamber 9 is brought to the surface through the channel 7, the central passage channel 3 and the tubing 1 (Fig. 2) .

Then equalize the pressure above and below the depression insert. Due to the tension of the cable with the catcher, the depression insert is removed, while the bushing 20 moves upward, opening the radial holes 18 and, through them, the access of the well fluid 32 to the under-packer space (Fig. 4).

After pulling out the depression insert to the surface, the geophysical tool 28 and the sealing unit 6 are lowered through the tubing on the cable until it stops on the sealing sleeve 4 and a background recording is made by moving the geophysical tool along the studied interval of the productive formation. The bypass channel 23 of the sealing assembly, made in the housing 22 and hydraulically connecting the cavities above and below the sealing assembly, during the operation of the jet pump is blocked by a spring-loaded piston 25 placed in the cavity 24 with the possibility of axial movement.

Further, working fluid 31 is supplied under pressure through the annulus to the nozzle 8. Flowing through the mixing chamber 9 and diffuser 10, the working fluid ensures the inflow of formation fluid, which is recorded by a geophysical instrument moving along the same formation interval, for which the background record was previously recorded. The formation fluid inflow, due to the pressure drop, rushes upward through the cavity of the sealing sleeve 4, the radial holes 27, the channel 11, the cavity of the check valve 12 and the bypass channel 14, is mixed in the mixing chamber 8, forming the well fluid 32 (mixture), which is brought to the surface ( Fig. 5).

Upon completion of the measurements, the supply of working fluid through the annulus is stopped. The tension of the cable provides equalization of the pressure above and below the sealing assembly 6, while the piston 25 under the action of the spring 26 occupies the upper position in the cavity 24, connecting it with the bypass channel 23 and channel 7 providing hydraulic connection of the space above and below the sealing assembly and equalizing the pressure in it (Fig. 6).

Next, the sealing assembly with the geophysical instrument is removed on the cable, then the packer is deactivated and the jet pump is removed to the surface.

Claims (10)

1. A method for testing wells and intensifying oil and gas inflows, which consists in lowering a packer and a jet pump into the well on a tubing string (tubing string), characterized in that a formation fluid selection channel is made in the jet pump housing, in which a reverse a valve, a channel for supplying a working fluid, in which a diffuser is installed, a mixing chamber with a nozzle, a sealing sleeve installed in the central axial passage channel with the possibility of axial movement to a seat in the form of a stop made on the inner surface of the central axial passage channel, at the lower edge of the housing jet pump; then the packer is activated above the roof of the productive formation, hermetically separating the above-packer and under-packer space; then, through the passage channel and the sealing sleeve, an acid solution is fed into the productive formation and the technological time of exposure to the acid solution is maintained; after that, a depression insert is lowered into the tubing, containing a housing with radial holes with the possibility of movement along the passage channel of the jet pump to contact with the sealing sleeve; then, under pressure, a working fluid is fed into the tubing, under the influence of which the depression insert interacting with the sealing sleeve moves it to the seat; then the working fluid is supplied through the annulus, creating a reduced pressure in the productive formation zone, while filtering the working fluid through a filter installed on the outer surface of the jet pump before entering the nozzle and hydraulically connected to it, and carrying out the selection of acid solution reaction products from the formation through mixing chamber and diffuser; then provide pressure equalization in the space above and below the depression insert; then, the depression insert is removed, a geophysical instrument and a sealing assembly are lowered through the tubing on a cable, containing a housing in which a bypass channel is made, hydraulically connecting the cavities above and below the sealing assembly and blocked during the operation of the jet pump by a spring-loaded piston placed in the sealing assembly with the possibility of axial movement; and conduct background recording by moving the geophysical tool along the interval of the formation to be investigated; after that, a working fluid is supplied under pressure through the annulus, which, flowing through the nozzle, the mixing chamber and the diffuser, causes the inflow of formation fluid, and the inflow profile is recorded by moving the geophysical instrument along the formation interval to be investigated; upon completion of measurements, the supply of working fluid to the annulus is stopped; then, by tensioning the cable, the pressure is equalized above and below the sealing assembly, and the sealing assembly and the geophysical instrument are removed; then the packer is deactivated and the jet pump is removed from the well. 2. The method according to p. 1, characterized in that the depression insert is removed using a catcher on the cable, while under the tension of the cable, the depression insert sleeve is displaced and opens the upper radial openings of the body, through which the pressure is equalized in the space above and below the depression insert. 3. The method according to p. 1, characterized in that the sealing sleeve is installed when the locking element is destroyed on the seat in the form of a stop made on the inner surface of the central axial passage channel. 4. The method according to p. 1, characterized in that the hydraulic connection of the under-packer space with the check valve channel is provided through radial holes made in the body of the sealing unit. 5. A jet pump for implementing the method according to claim 1, containing a hollow body, in the central passage channel of which a sealing sleeve is installed, in addition, a nozzle, a mixing chamber with a diffuser are coaxially located in the jet pump body, and a channel is made in which a check valve is placed, characterized in that the central axial passage channel of the jet pump housing is configured to install a sealing sleeve into it, while the sealing sleeve is configured to axially move along the central axial passage channel to a seat in the form of a stop made on the inner surface of the central axial passage channel at the lower edge of the jet pump housing, while the central axial passage channel of the jet pump is also made with the possibility of alternately installing the depression insert and the sealing assembly on the sealing sleeve, while the inner surface of the central axial passage channel is made stepless in the area of movement along the specified channel of the depression insert and the sealing assembly in addition, a filter is installed on the outer surface of the jet pump housing, located in front of the nozzle inlet, and is hydraulically connected to it; the depression insert includes a housing and a bushing installed with the possibility of axial displacement relative to it, and in the depression insert body there is a lower radial hole forming a formation fluid withdrawal channel, and upper radial holes forming a channel for supplying the working fluid through the internal cavities of the pump to the under-packer space for pressure equalization above and below the depression insert; the sealing unit comprises a housing in which a bypass channel and a cavity with a piston placed in it with the possibility of axial movement and held by a spring are made; in addition, radial holes are made in the body of the sealing unit, forming a reservoir fluid selection channel at the lower position of the piston, in which the extraction is carried out through the check valve channel and bypass channel, and when mixed with the working fluid entering through the annulus through the mixing chamber, the diffuser and tubing cavity; at the top position of the piston, the working fluid penetrates into the space under the packer through the bypass channel and equalizes the pressure in the space above and below the sealing unit. 6. The jet pump according to claim 5, characterized in that the channel for supplying the working fluid through the annulus is formed by a nozzle, a mixing chamber, a diffuser and a channel connected to the central axial flow channel of the jet pump housing. 7. The jet pump according to claim 5, characterized in that the sealing unit is installed on the geophysical cable with the possibility of axial movement, and the geophysical instrument is fixed on the lower end of the geophysical cable. 8. Jet pump according to claim 5, characterized in that the sealing sleeve is fixed in the jet pump housing with a destructible element. 9. Jet pump according to claim 5, characterized in that the check valve is equipped with a ball. 10. The jet pump according to claim 5, characterized in that the hydraulic connection of the filter installed on the outer surface of the jet pump housing and the nozzle provides filtration of the circulating working fluid entering the internal cavities of the jet pump and tubing.

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