UA74984C2 - Method for operation of well jet unit at cleaning the well zone of the bed with ultrasound and appliance for its implementation - Google Patents

Abstract

The invention relates to pumping engineering, mainly to well pumping devices for extracting oil from wells. The inventive method consists in assembling from the bottom upward an input cone provided with a shank, a packer and a jet pump and in runningsaid assembly with the aid of a tubing string into a well. Afterwards, a receiver transformer of physical fields is also run into said well, background measurements of temperature and other physical fields are carried out, a formation is drained and the work of the individual interlayer of a productive strata is evaluated. An ultrasonic action is performed on the productive strata. The hydrodynamic action being performed on the productive strata during said operation, the entire formation is exposed to the combined action of ultrasonic oscillations and a hydrodynamic effect. Afterwards, the unit for ultrasonic effect is pulled out from the well to the surface. The hydrodynamic and geophysical investigations of the well being carried out using the jet pump and replaceable functional inserts, the assembly and the jet pump are pulled out from the well to the surface and the well is prepared in order to be put into operation. The invention makes it possible to optimise the dimensions of various elements of the device, thereby increasing the operating reliability and performance of the well jet device during the treatment of the productive strata.

Description

Description of the invention

The invention belongs to the field of pumping technology, mainly to well pumping units for oil extraction from wells.

There is a known method of operation of a jet well installation, which includes feeding an active liquid medium through a column of pump-compressor pipes into the nozzle of a jet apparatus, capturing a passive medium and mixing it with the supply of a mixture of media from the well to the surface (KI 2059891 C1).

From the same source, a well jet installation is known, which includes a jet pump installed in a well on a pump-compressor pipe string and a geophysical device placed below the jet pump in a pump-compressor pipe string.

The known method of operation and the well jet installation allow pumping out of the well various produced media, for example, oil with simultaneous treatment of the produced media and the near-well zone of the reservoir.

However, this method does not provide for the possibility of selective influence on the near-well zone of the formation.

In addition, this installation does not provide for the possibility of installing 2 different functional inserts, which in a number of cases narrows the scope of use of the operation and installation data.

The closest to the invention in terms of technical essence and the result that is achieved, in terms of the method, is the method of operation of a well jet installation during formation processing, which includes installation in the well on a column of pump-compressor pipes of a jet pump placed in a housing with a passage channel made in the last, supply of the working medium through the column of pipes to the nozzle of the jet pump and, due to this, the creation of regulated pressure in the sub-packing zone with the possibility of draining the reservoir and other regulatory works (KI 2176336 C1). with

The closest to the invention in terms of the technical essence and the result that is achieved in the part of the installation is Ge) known from the same source, a well jet installation, which contains a packer, a column of pipes and a jet pump, in the body of which an active nozzle with a mixing chamber is installed and a pass-through a channel with a seat for installing a sealing unit with an axial channel, while the installation is equipped with an emitter and a receiver-converter of physical fields, placed on the side of the entrance to the jet pump of the medium pumped from M well and installed on a cable passed through the axial channel of the sealing unit, (o the supply channel of the active medium is connected to the pipe column above the variable functional insert, the inlet of the pumped medium supply channel of the jet pump is connected to the pipe column below the variable functional insert, and the outlet of the jet pump is connected to the annular space of the pipe column. "I

The known method of operation and the downhole jet installation allow to carry out formation processing in the well below the level of the jet pump installation, including by processing the productive layer with the help of chemical reagents and creating a pressure difference above and below the functional insert.

However, the given method of operation and the downhole jet installation do not allow the full use of the capabilities of the downhole jet installation, which is associated with a limited set of operations for processing the "reservoir, mainly with the use of chemically active liquid media, and the absence of the possibility of targeted C 0 influence on non-working or poorly functioning layers of the productive layer, as well as with suboptimal size ratios of structural elements included in the well jet installation.

With" The task, the solution of which is directed to the solution of this invention, is to increase the reliability and productivity of the well jet installation during the treatment of the productive reservoir due to the detection of non-working and poorly functioning layers of the productive reservoir and targeted impact on the near-well zone with the restoration of its permeability and the removal of clogging from the well particles clogging the borehole zone, as well as optimization of the sizes of various elements of the installation structure. "" The specified problem in part of the method is solved due to the fact that the method of operation of the well jet installation during the cleaning of the near-well area of the reservoir with ultrasound is that an inlet funnel with a shank, a packer and a jet pump are mounted from the bottom up 20 of active medium, a supply channel for the medium pumped from the well and a stepped passage channel with a landing place between the steps, lower this assembly on a column of pipes into the well, while the incoming

The T" funnel is placed not lower than the roof of the productive layer, then the packer is unpacked and then lowered into the well through the passage channel of the jet pump housing on the logging cable or the receiver-transducer wire of physical fields together with the sealing unit, which is placed on the logging cable 25 or the wire above the tip to connect the receiver-converter of physical fields and install it on

GF) landing place in the passage channel of the jet pump housing with the possibility of reciprocating movement of the logging cable or wire through the sealing node, during the descent, background measurements of temperature and other physical fields are carried out along the wellbore from the funnel to the wellhead, then the receiver is placed the converter of physical fields above the roof of the productive 60 formation, by supplying under pressure a liquid medium to the active nozzle of the jet pump, drainage of the formation is carried out with the step-by-step creation of several depression values per formation, registering at each of them the cut-off pressures, composition and physical parameters of the fluid coming from the productive reservoir, as well as the flow rate of the well, then with the jet pump operating at a given depression value, the receiver-transducer of physical fields is moved to the reservoir along the axis of the well from the hole to the inlet funnel, while recording the inflow profile and formation fluid parameters, bottomhole pressure, and as well as changes in the physical fields in the near-well zone of the formation, while based on the results of the measurements, the work of individual layers of the productive formation and the composition of the fluid coming from them are evaluated, then the supply of liquid medium to the jet pump is stopped, the receiver-transducer of physical fields is pulled out of the well together with the Logger with a cable or wire and a sealing unit, then a device for ultrasonic impact on the formation, which includes an ultrasound emitter, together with a sealing unit movably installed above it on the logging cable, is lowered into the well along a column of pipes on a logging cable or wire, the latter is installed in the seat of the passage channel , and the ultrasound emitter is installed in front of the productive layer, then the ultrasonic effect is carried out on the productive layer, and first 7/0 affects its non-working layers, and then on the working layers, gradually moving from less permeable to more permeable layers and affecting each of them no less than two values of the frequency of ultrasonic oscillations, during the ultrasonic impact on the layers of the productive reservoir, a hydrodynamic effect is exerted on the productive reservoir by feeding a liquid medium into the active nozzle of a jet pump according to the scheme: creating a jump-like depression on the formation, maintaining this depression, jump-like 7/5 Restoration of hydrostatic of the pressure of the liquid medium on the wellbore and maintaining this pressure, and the time of maintaining the depression on the formation is set to be greater than the time of exposure to the formation of the hydrostatic pressure of the liquid medium, and the number of cycles of hydrodynamic influence on each layer of the formation in combination with the influence of ultrasonic oscillations is at least 5, and after after the impact on each layer of the formation by ultrasonic oscillations with hydrodynamic influence is completed, a control measurement of the flow rate of the well is carried out with the working jet pump, and after the influence on the entire formation is completed by ultrasonic oscillations in combination with the hydrodynamic influence of the install a device for ultrasonic impact on the formation on the surface, conduct hydrodynamic and geophysical studies of the well using a jet pump and variable functional inserts, after which the assembly with a jet pump is pulled to the surface and measures are taken to start the well into operation. with

The specified task in the part of the installation is solved due to the fact that the downhole jet installation contains a receiver-transducer of physical fields, a device for ultrasonic impact on the formation, variable i) functional inserts and an inlet funnel with a shank mounted on the pipe column from bottom to top, a packer with a it has a central channel and a jet pump, in the body of which an active nozzle and a mixing chamber are installed, as well as a channel for supplying the active medium, a channel for supplying the pumped medium from the well and a stepped passage channel with a landing place between the steps, while in the stepped passage channel alternately install a sealing unit, which is movably placed on a logging cable or wire above the tip for connecting a receiver-transducer of physical fields or a device for ultrasonic impact on the reservoir, and variable functional inserts: a depression insert and an insert for recording formation pressure recovery curves in the subpacking space a well with a sampler and an autonomous - with 5 device, while the device for ultrasonic impact on the layer includes an ultrasound emitter, which is made with the possibility of radiating at least 2 frequencies of ultrasonic oscillations, and a pressure sensor, the diameter of the Ф» of the stepped passage channel of the jet pump housing below seat is at least 1 mm larger than the diameter of the device for ultrasonic impact on the layer, and the diameter O of the central channel of the packer is not less than the diameter 0" of the stepped passage. channel of the jet pump housing below the landing "

places The analysis of the operation of the downhole jet installation showed that the reliability and productivity of the installation can be increased by optimizing the sequence of actions when cleaning the near-well zone of the formation in ;" wells, in particular, when carrying out work with the application of ultrasonic treatment of the formation, as well as the execution of various elements of the installation design with strictly defined dimensions.

It was found that the above-mentioned sequence of actions allows the most effective use of the -I well jet installation in combination with a device for ultrasonic treatment of the productive layer when carrying out work on the intensification of the inflow of oil from the productive layer by increasing the permeability of non-working and poorly functioning layers of the productive layer. By studying the reservoir both before and after ultrasonic treatment, it is possible to first assess the technical condition of the well, the properties of the fluid extracted from the well, the condition of the near-well zone of the productive reservoir, identify non-working and poorly functioning productive layers, and choose the mode of processing of the productive » layer by ultrasound. After conducting ultrasonic treatment in combination with hydrodynamic influence on the formation, it is possible to evaluate the quality of the treatment of the near-well zone of the productive formation and choose the mode of operation of the well. The variable hydrodynamic effect on the formation in combination with the effect on the formation by ultrasonic vibrations allows to increase the radius of treatment of the near-well zone of the formation. When the depression is created, the jet pump timely removes from the productive layer the clogging particles that (F) clog the productive layer, which are carried to the surface at high speed through the annular space of the pipe column. The use of a receiver-converter of physical fields and functional inserts, which include, in particular, a sampler and a number of autonomous devices that can be installed under the functional bo Inserts allows to conduct a study of the medium that comes from the well. current hydrostatic pressure. In addition, during the ultrasonic impact on the formation due to a change in the frequency of ultrasonic oscillations in combination with the adjustable, step-change pump mode described above by changing the 65 Pressure of the liquid working medium supplied to the nozzle currents n pump, it was possible to choose such an operating mode in which not only the permeability of non-productive layers is restored, but also the permeability increases, and therefore the inflow of the extracted medium (fluid) from the productive layers of the reservoir. It was found that the jump transition from the depression on the formation to the recovery of hydrostatic pressure with cyclic repetition of this operation and the excess of the time of maintaining the depression on the formation in comparison with the time of hydrostatic pressure on the formation of the column of liquid medium in the well are essential for effective influence on the formation. It was also found that the number of specified cycles of hydrodynamic influence on each of the layers should be at least 5 in order to achieve high-quality cleaning of the near-well zone of the formation. In the course of carrying out work on cleaning the near-well area of the formation, it is possible to move the receiver-transducer of physical fields and the device for ultrasonic impact on the formation along the well, 7/0, and the study of the formation and its processing can be carried out both when the jet pump is working and when it is stopped, which makes it possible to effectively carry out measures to intensify the flow rate of the well using ultrasonic treatment of the productive layer, at the same time conducting comprehensive research and testing of the well in various modes. As a result, it was possible to reduce the lower permeability limit of the formation by 1.5-2 times, to destroy the clogging zone in the non-working layers of the productive formation and, as a result, to speed up the work on increasing the productivity of the well by 1.2-1.6 times 7/5, and the inflow profile is significantly leveled due to the full coverage of the layer by the impact along its thickness during the treatment of the layer with ultrasound.

It should be noted that the sequence of actions described in the invention allows you to constantly monitor the progress of work on the intensification of the inflow of the medium extracted from the productive layer. In particular, the received inflow profiles and reservoir pressure recovery curves allow obtaining an objective picture of the state of the near-well zone of the productive reservoir depending on carried out works to increase its permeability.

In addition, to prevent jamming of the pipes of devices that are lowered down the column, in particular, the device for ultrasonic impact on the formation, and to ensure the operation of the well jet installation without disrupting its operation, the implementation of the diameter О o of the stepped passage channel of the jet pump housing below the landing place is aimed at not less than 1.0 mm larger than diameter 0; device for ultrasonic exposure, and the diameter Oz of the central channel of the packer is not less than the diameter of the stepped passage channel of the jet pump housing below the landing place. It was established that the implementation of the device for ultrasonic impact on the formation with i) an external diameter that differs by less than 1 mm from the diameter of the stepped passage channel below the landing place does not prevent its jamming, since during the operation of the installation it is possible to get into the gap between the device for ultrasonic impact and the wall of the stepped passage channel clogging "E of particles. At the same time, the specified gap should be such as to ensure the possibility of the medium pumped out of the well flowing through it during the movement of the device for ultrasonic impact on the oil layer through the stepped passage channel. b

Thus, the task of increasing the reliability and productivity of the downhole jet installation during the processing of the productive layer has been achieved due to the detection of - 5 non-working and poorly functioning layers of the productive layer and targeted impact on the near-well zone p with the restoration of its permeability and the removal of clogging particles from the well, clogging the borehole zone, as well as optimization of the sizes of various elements of the installation structure.

Fig. 1 shows a longitudinal section of a well jet installation for the implementation of the described method of operation with a sealing unit installed in it and a receiver-transducer of physical fields. "

In Fig. 2 - a longitudinal section of the installation with a sealing unit and a device for ultrasonic impact on the pt") with layer.

Fig. 3 is a longitudinal section of the installation with a functional insert for recording recovery curves;" reservoir pressure in the underpacking space with a sampler and autonomous device installed under it.

The downhole jet installation includes, mounted on a column of pipes 1 from the bottom up, an inlet funnel 2 with a shank З, a packer 4 with a central channel 5 made in it, and a jet pump 6, in the housing 7 of which an active nozzle 8 and a mixing chamber 9 are coaxially installed, as well as a channel for supplying the active medium 10, a channel 11 for supplying the medium pumped from the well, and a stepped passage channel ve 12 with a landing place 13 between the steps are made, while in the stepped passage channel 12 it is possible to install a sealing unit 14, which is movably placed on the logging cable or wire 5r 19 above the tip 16 for connecting the receiver-transducer of physical fields 17, the device 18 for the ultrasonic impact on the formation and variable functional inserts: the depression one with an autonomous device and the insert for recording formation pressure recovery curves in the underpacking space of the well 19 with the sampler 20 and autonomous device 21. Device 18 for ultrasound impact on the layer includes an ultrasound emitter, made with the ability to emit at least 2 ultrasonic frequencies in Oscillations, and a pressure sensor. The diameter OO" of the stepped passage channel 12 of the housing 7 of the jet pump 6 below the seat 13 is not less than 1 mm larger than the diameter 0.3 of the device 18 for ultrasonic impact on the formation.

F) The diameter Oz of the central channel 5 of the packer 4 is less than the diameter O» of the stepped passage channel 12 of the body 7 of the jet pump 6 below the seat 13. The outlet of the jet pump 6 is connected to the annular space of the well (pipe columns 1), the nozzle 8 of the jet pump 6 through the channel supply of the active medium 10 is connected to the inner cavity of the pipe string 1 above the sealing unit 14, and the supply channel of the medium pumped from the well 11 is connected to the inner cavity of the pipe string 1 below the sealing unit 14. Functional inserts are made in the upper part with a device 22 for their installation and removal from the well.

The method of operation of the downhole jet installation when cleaning the near-well zone of formation 65 with ultrasound consists in mounting from the bottom up the inlet funnel 2 with the shank З, the packer 4 with the central channel 5 and the jet pump 6, in the body 7 of which there is a channel for supplying the active medium

10, the supply channel of the medium pumped from the well 11 and the stepped passage channel 12 with a seat 13 between the steps. This assembly is lowered on a string of pipes 1 into the well, while the inlet funnel 2 is placed not lower than the roof of the productive layer 23. The packer 4 is unpacked and then lowered into the well through the passage channel 12 of the casing 4 of the jet pump 6 on the logging cable or wire 15 receiver-transducer of physical fields 17 together with the sealing unit 14, which is placed on the logging cable or wire 15 above the tip 16 for connecting the receiver-converter of physical fields 17. The sealing unit 14 is installed on the seat 13 in the passage channel 12 of the housing 7 of the jet pump 6 with the possibility of reverse - progressive movement of the logging cable or wire 15 through the 70 sealing unit 14. During the descent, background measurements of temperature and other physical fields along the wellbore from the inlet funnel to the wellhead are carried out. Next, the receiver-transducer of physical fields 17 is placed above the roof of the productive reservoir 23, and by feeding under pressure a liquid medium into the active nozzle 8 of the jet pump, drainage of the reservoir 23 is carried out with the stepwise creation of several depression values per reservoir, registering at each of them the cut-off pressures, composition and physical /5 parameters of the fluid coming from the productive layer 23, as well as the flow rate of the well. Then, with the working jet pump b at a given depression value, the receiver-transducer of physical fields 17 is moved to the layer 23 along the axis of the well from the wellbore to the entrance well 2 and the inflow profile, formation fluid parameters, bottomhole pressure, as well as changes in the physical fields in the near-well area are recorded layer 23, and based on the results of the measurements, the performance of individual layers of the productive layer 23 and the composition of the fluid coming from them are evaluated. After that, the supply of liquid medium to the jet pump 6 is stopped, the receiver-transducer of physical fields 17 is pulled out of the well together with the logging cable or wire 15 and the sealing unit 14. Next, the device for ultrasonic exposure is lowered into the well along the pipe column 1 on the logging cable or wire 15 on the layer 23, which includes an ultrasound emitter, together with a sealing unit 14 mounted movably above it on a logging cable or wire 15. The latter is installed in the seat 13 of the passage channel 12, and the ultrasound emitter is installed opposite the productive layer 23. Then the impact is carried out on productive layer 23 by ultrasonic vibrations, and first i) influence the non-working layers, and then the working layers, gradually moving from less permeable to more permeable layers and affecting each of them with at least two values of the frequencies of ultrasonic vibrations. During the ultrasonic impact on the layers of the productive layer 23, they affect the layer of the productive layer 23 by supplying a liquid medium to the active nozzle 8 of the jet pump 6 according to the scheme: creation of a jump-like depression on the layer 23, maintenance of this depression, jump-like recovery of the hydrostatic pressure of the liquid medium on well blowout and maintenance of this pressure, and the time b of maintaining the depression on the layer is set to be greater than the time of exposure to the layer 23 of the hydrostatic pressure of the liquid medium, and the number of cycles of hydrodynamic influence on each layer of the layer 23 in combination with ultrasonic influence is at least 5, and after the impact on each layer of the formation 23 is completed by ultrasonic oscillations with hydrodynamic influence, a control measurement of the flow rate of the well is carried out with the working jet pump 6. After the impact on the entire formation 23 is completed by ultrasonic oscillations in combination with hydrodynamic influence, the device for ultrasonic influence on the formation 18 is pulled out on p surface, conduct hydrodynamic and geophysical studies of the well using the jet pump 6 and variable functional inserts, after which the assembly with the jet pump 6 is pulled to the surface and measures are taken in c to start the well into operation.

This invention can be used in the oil and gas extraction and mining industry during development;" wells after drilling, during their underground repair or restoration in order to intensify the inflow of oil and gas wells.

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Claims (2)

The formula of the invention is 1. The method of operation of the downhole jet installation during the cleaning of the near-well zone of the 5p layer with ultrasound, which consists in mounting from the bottom up the inlet funnel with a shank, a packer and a jet (o) pump, in the body of which there is a channel for supplying active environment, the supply channel for the medium pumped from the well and a stepped passage channel with a landing place between the steps, lower this assembly on a column of pipes into the well, while the inlet funnel is placed not lower than the roof of the productive layer, then fix the packer and then lower it into the well through the passage the channel of the jet pump housing in the logging cable or wire, the receiver-converter of physical fields together with the sealing unit, which is placed on the logging cable or wire above the tip for connecting the receiver-converter (F) of physical fields and set it on the seat in the passage channel of the jet housing pumps with GI, ensuring the possibility of reversal progressive movement of the logging cable or wire through the sealing node, during the descent, background measurements of temperature and other physical fields are carried out along the wellbore from the funnel to the wellbore, then a receiver-transducer of physical fields is placed above the roof of the productive layer, by supplying liquid under pressure medium into the active nozzle of the jet pump, drainage of the formation is carried out with the stepwise creation of several depression values for the formation, recording at each of them the cutting pressures, the composition and physical parameters of the fluid coming from the productive formation, as well as the flow rate of the well, then with the jet pump working at the given the amount of depression on the layer 65, the receiver-transducer of physical fields is moved along the axis of the well from the hole to the inlet funnel, while recording the inflow profile and parameters of the formation fluid, the bottomhole pressure, as well as changes in the physical fields in the near-well zone of the formation, while the performance is evaluated based on the results of the measurements individual about layers of the productive layer and the composition of the fluid coming from them, then stop the supply of the liquid medium to the jet pump, pull out the receiver-transducer of physical fields from the well together with the logging cable or wire and the sealing unit, then lower it into the well along the column of pipes on the logging cable or to the wire, a device for ultrasonic impact on the layer, which has an ultrasound emitter, together with a sealing unit movably installed above it on the logging cable, the latter is installed in the seat of the passage channel, and the ultrasound emitter is installed opposite the productive layer, then ultrasonic influence is carried out on the productive layer, and first they influence its non-working layers, /o and then on working layers, gradually moving from less permeable to more permeable layers and affecting each of them with at least two values of the frequencies of ultrasonic oscillations, during ultrasonic influence on the layers of the productive reservoir to the productive formation by supplying liquid medium to the active nozzle of the jet pump to create a jump-like depression on the formation, maintain this depression, jump-like restoration of the hydrostatic pressure of the liquid medium on the 7/5 well hole and maintain this pressure, and the time for maintaining the depression on the formation is set to be greater than the time hydrostatic pressure of the liquid medium is applied to the layer, and the number of cycles of hydrodynamic influence on each layer of the layer in combination with the influence of ultrasonic vibrations is not less than 5, and after the impact on each layer of the layer with ultrasonic vibrations with hydrodynamic influence is completed, a control measurement of the flow rate of the well is carried out with a working jet pump, and after the end of impact on the entire formation with ultrasonic vibrations in combination with hydrodynamic impact, the device for ultrasonic impact on the formation is pulled to the surface, hydrodynamic and geophysical studies of the well are carried out using a jet pump and with mine functional inserts, after which the assembly with the jet pump is pulled to the surface and measures are taken to start the well into operation. 2. A downhole jet installation, which has a receiver-transducer of physical fields, a device for measuring ultrasonic impact on the formation, replaceable functional inserts and mounted on a pipe column from the bottom up to an inlet funnel with a shank, a packer with a central channel made in it, and a jet pump, in the body of which an active nozzle and a mixing chamber are installed, as well as a channel for the supply of the active medium, a channel for the supply of the medium pumped from the well and a stepped passage channel with a landing place between the steps, while in the stepped passage channel a sealing unit is alternately installed, "f zo which is movable placed on the logging cable or wire above the tip for connecting a receiver-transducer of physical fields or a device for ultrasonic impact on the formation, and interchangeable co-functional inserts, such as a depression and an insert for recording formation pressure recovery curves in the subpacking space of the well with a sampler and an autonomous device , while the device for ultrasonic impact on the formation has an ultrasound emitter, made with the ability to emit no less than 2 frequencies of ultrasonic oscillations, and a pressure sensor, the diameter O" of the stepped passage channel of the body of the jet pump below the landing place is not less than 1 mm larger than the diameter OO of the device for ultrasonic impact on the formation, and the diameter Oz of the central channel of the packer is not less than the diameter of the 02-stage passage channel of the jet pump housing below the landing place. 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