RU2329409C1 - Well-deep jet unit for hydraulic formation fracturing and well analysis - Google Patents

Abstract

FIELD: engines and pumps; mining art.

SUBSTANCE: unit incorporates a jet pump (JP) mounted on the string and a packer. JP housing has a stepwise through channel (STC) with a mounting seat arranged between the steps and pumped-out well medium feed channels. The STC is arranged aligned with the string and communicates with it, while the aforesaid feed channels are provided with check valves and the valve shut-off element up-travel limiters. The STC can incorporate a sealing assembly in the form of a casing with a sealing element and a logging cable channel. A cylinder guide bush-separator (BS) is arranged above the STC and aligned with it in the JP housing, the aforesaid BS being fastened by its top end as a cantilever at the JP housing upper part. The BS walls are provided with lengthwise slot-like holes. The BS lower free end is arranged at a certain distance from the STC upper end face. The BS inner diameter, the STC upper end face diameter, the BS slot-like holes widths and the distances between adjacent slot-like holes are intercorrelated.

EFFECT: higher reliability and efficiency of the unit in testing the well and optimisation of testing procedures.

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Description

The invention relates to the field of pumping technology, mainly to downhole jet installations for hydraulic fracturing, testing and research of wells.

A well-known jet installation containing a pipe string with an jet pump and a packer with the ability to pump liquid working medium through the jet pump (see RU 2059891 C1, F04F 5/02, 05/10/1996).

This downhole jet installation allows pumping out various produced media, such as oil, from the well while processing the produced environment and the near-wellbore zone of the formation, however, in this installation, the possibilities for conducting well research are limited, which in some cases narrows the scope of use of this installation.

The closest to the invention in technical essence and the achieved result is a downhole jet installation containing a pipe string, a packer and an jet pump, in the housing of which an active nozzle with a mixing chamber is installed and a passage through is made with a seat for installing a sealing unit with an axial channel, the outlet of the jet pump is connected to the pipe string above the sealing unit, the input of the channel for supplying a pumped medium of the jet pump is connected to the pipe string below the sealing unit, and d the channel for supplying the working medium to the active nozzle is connected to the space surrounding the tubing string, and several channels for supplying a pumped medium are made in the jet pump housing (see patent RU 2106540, class F04F 5/02, 03/10/1998).

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 installation does not allow to fully utilize its capabilities, which is associated with the impossibility of maintaining depression on the reservoir with an idle jet pump, which does not allow to fully investigate the well. In addition, when carrying out hydraulic fracturing, it is necessary to install a blocking insert in the jet pump body, which is a rather time-consuming operation.

The problem to which the present invention is directed is to prevent spontaneous overflow of an active working medium when the jet pump ceases to function and to maintain depression on the formation with the jet pump not working and to organize hydraulic fracturing without using additional equipment for the jet pump.

The technical result, the achievement of which the present invention is directed, is to increase the reliability and productivity of a well jet device during a well test and to optimize the sequence of actions when conducting a well research and test.

The problem is solved, and the technical result is achieved due to the fact that the downhole jet installation comprises a jet pump and a packer mounted on the pipe string, moreover, an active nozzle and a mixing chamber with a diffuser are coaxially mounted in the jet pump housing, and a step-through passage tapering from top to bottom is made with a seat between the steps, a channel for supplying a medium pumped out of the well, reported below a seat with a stepped passage channel, and a channel for supplying an active working medium, with communicated on the exit side with the active nozzle and on the side of the entrance to the annulus of the pipe string, the stepped passage channel being made coaxially with the pipe string and connected to it, the supply channel of the pumped out medium from the well and the supply channel of the active working medium are each the check valve and the limiter for moving upward the shut-off element of the check valve, for example the ball, relative to the seat of the check valve, in the stepped passage channel, it is possible to install a sealing unit, to which is made in the form of a hollow stepped cylindrical body, in the cavity of which a sealing element is placed, and in the sealing element there is an axial channel for passing a wireline through it, on which a wireline tool is suspended below the jet pump body through a cable head, coaxially to the last passage channel a cylindrical guide sleeve-separator is installed in the housing of the jet pump, cantileverly fixed with its upper end by means of a threaded connection in the top of the part of the jet pump housing, longitudinal slit-shaped openings are made in the wall of the guide sleeve-separator, while the lower free end of the guide sleeve-separator is located from the upper end of the stepped passage channel at a distance of 0.1 to 0.2 of the diameter of the upper end of the stepped passage channel, the inner diameter of the guide sleeve of the separator is from 1.1 to 1.2 the diameter of the upper end of the stepped passage channel, and the width of the slit-like holes in the guide sleeve of the separator Ore no greater than the distance between adjacent slotted.

Analysis of various designs showed that the reliability can be improved by increasing the functionality of the installation in the study and testing of wells.

It was revealed that the above set of structural elements of the well installation allows you to organize a sequence of actions in which the equipment that is installed on the pipe string when carrying out well logging to study, test and develop 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 downhole installation makes it possible to create a number of different depressions using a jet pump in the sub-packer zone of the well with a given pressure drop, and using a logging tool to record pressure, temperature and other physical parameters of the well and the medium pumped out of the well, and also record the reservoir pressure recovery curve in the under-packer space of the well without using a specially designed functional insert. At the same time, it is possible to control the magnitude of depression by controlling the rate of pumping of the active working medium. During the formation test, it is possible to adjust the pumping mode by changing the pressure of the active working medium supplied to the active nozzle of the jet pump. At the same time, the possibility of spontaneous overflow of the working medium into the under-packer zone is excluded both with the working and non-working jet pump.

In addition, it is possible to carry out hydraulic fracturing without first installing any functional inserts in the jet pump, and at the same time it is possible to eliminate the misalignment and jamming of the sealing assembly in the jet pump housing when lowering the sealing assembly and installing it on the seat in the stepped passage channel.

For this, in the jet pump housing coaxially to the pipe string above the stepped passage channel, a guide sleeve-separator is cantilevered. As a result, when large fractions of hydraulic fracturing fluid get into the nozzle and the mixing chamber with the diffuser when the fracturing fluid is injected into the formation, the possibility of damage to the mixing chamber with the diffuser and the jet pump nozzle is prevented. The location of the lower free end of the guide sleeve of the separator from the upper end of the stepped passage channel is directed at the same distance from 0.1 to 0.2 of the diameter of the upper end of the stepped passage channel, as well as the execution of the inner diameter of the guide sleeve of the separator component from 1, 1 to 1.2, the diameter of the upper end of the stepped passage channel and the width of the slit-like openings in the guide sleeve-separator is not greater than the distance between adjacent slit-like openings. Taking into account that hydraulic fracturing fluid contains propant - a refractory granular material in the form of balls with a diameter of 0.4 to 2.0 mm, it was found that with the above size ratios for various sizes of jet pumps it is possible, on the one hand, to prevent the ingress of proppant into the flow part of the nozzle and the mixing chamber with the diffuser, and on the other hand, do not create significant hydraulic resistance at the outlet of the diffuser, which would disrupt the operation of the jet pump and would require significant energy costs to overcome this hydraulic resistance.

As a result, intensification of work on research, testing and development of wells is achieved, which allows for high-quality research and testing of wells after drilling and during overhaul, as well as preparation of the well for operation with comprehensive research and testing in various modes, and thereby increasing the reliability of work installation.

Figure 1 presents a longitudinal section of a downhole jet unit during the injection into the formation of chemicals or hydraulic fracturing fluid.

Figure 2 presents a longitudinal section of a downhole jet unit with a sealing assembly installed in a stepped passage channel during well research and testing.

The downhole jet installation comprises a jet pump 2 and a packer 3 mounted on a pipe string 1. An active nozzle 5 and a mixing chamber 6 with a diffuser 7 are coaxially mounted in the housing 4 of the jet pump 2, and a step-by-step passage channel 8 tapering from top to bottom with a seat 9 between in steps, the channel 10 for supplying a medium pumped out of the well, reported below the seat 9 with a step-through passage channel 8, and the channel 11 for supplying an active working medium, communicated from the exit side with the active nozzle 5 and from the input side it with the annulus 12 of the pipe string 1. The stepped passageway 8 is formed coaxially with the column pipe 1 and communicates with it. The channel 10 for supplying a medium pumped out from the well and the channel 11 for supplying an active working medium are each made with a check valve 13 and 14, respectively, and an upward stop 15 and 16 of a shut-off element 17 and 18, respectively, of a check valve 13 and 14, for example, a ball, relative to the seat 19 and 20 its check valve 13 and 14. In the stepped passage channel 8, it is possible to install a sealing assembly 21, which is made in the form of a hollow stepped cylindrical body, in the cavity of which a sealing element 22 is placed, with this, in the sealing element 22, an axial channel 23 is made for passing the logging cable 24 through it, on which a logging device 25 is suspended below the housing 4 of the jet pump 2 by means of a cable head 28. A cylindrical guide is mounted coaxially to the last passage channel 8 in the housing 4 of the jet pump 2. a separator sleeve 26, cantilevered to its upper end by means of a threaded connection in the upper part of the housing 4 of the jet pump 2. In the wall of the guide sleeve of the separator 26, longitudinal slots are made holes 27, while the lower free end of the guide sleeve of the separator 26 is located from the upper end of the stepped passage channel 8 at a distance S equal to from 0.1 to 0.2 of the diameter D of the upper end of the stepped passage channel 8. The inner diameter d of the guide sleeve the separator 26 is from 1.1 to 1.2 times the diameter D of the upper end of the stepped passage channel 8, and the width h of the slit-like openings 27 in the guide sleeve-separator 26 is not greater than the distance H between adjacent slit-like openings 27.

The operation of a well jet installation for hydraulic fracturing and well research consists in assembling a pipe string 1 by installing a jet pump 2 and a packer 3 on a pipe string. The assembly is lowered into the well and the packer 3 is unpacked, and then pumped through the pipe string 1 and a stepped passage channel 8 of the jet pump 2 fracturing fluid or acid solution. Then the sealing assembly 21 is lowered into the well on the logging cable 24 with the logging device 25 fixed on the cable 24 by the cable head 28. The sealing unit 21 is installed on the seat 9 in the stepped passage channel 8 of the jet pump 2, and the logging device 25 is located in the zone of the reservoir (not shown in the drawing). During the descent, the background values of the rock physical fields along the wellbore, in particular thermal fields, are recorded with a logging tool 25. Then, by means of a jet pump 2, by supplying a pipe string 1 through the annular space 12 to the active nozzle 5 of the active working medium, a depression is created on the reservoir and thus the reservoir is drained by removing frac fluid with unsecured proppant or chemical reaction products of the formation by chemical agents, for example acid solution. Then, 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 the bottomhole pressure and well flow rate are recorded. Then, the logging tool 25 is lowered to the bottom and the profile of the inflow and the physical parameters of the medium pumped out of the well are recorded while the jet pump 2 is operating, moreover, this registration is carried out several times with various depressions on the formation during the descent and raising of the logging tool 25, the latter being moved along the well at different speeds. Then, the supply of the active working medium to the active nozzle 5 is abruptly stopped and, using a logging tool 25, the formation pressure recovery curve is recorded in the under-packer well space.

At the end of the work, the logging tool 25 is removed from the well together with the sealing unit 21 and the pipe string 1 is lifted together with the jet pump 2.

The present invention can be used in the oil and gas industry for well development after drilling or for logging in all types of wells.

Claims (1)

A downhole jet installation comprising a jet pump and a packer mounted on a pipe string; moreover, an active nozzle and a mixing chamber with a diffuser are coaxially mounted in the jet pump body, and also a step-by-step passage channel tapering from top to bottom with a seat between the steps, an inlet channel for pumping medium out of the well , communicated below the seat with a stepped passage channel, and the channel for supplying an active working medium, communicated from the exit side with the active nozzle and from the entrance to it from pipe space of the pipe string, wherein the stepped passage channel is made coaxially with the pipe string and connected with it, the channel for supplying the medium pumped out of the well and the channel for supplying the active working medium are each made with a check valve and an upstream stop valve for the check valve, for example, a ball relative to the seat check valve, in the stepped passage channel, it is possible to install a sealing unit, which is made in the form of a hollow stepped cylindrical body, in the cavity A sealing element is placed, wherein an axial channel is made in the sealing element for passing a wireline through it, on which a wireline tool is suspended by means of a cable head below the jet pump housing, a cylindrical guide sleeve-separator is installed coaxially with the last in the jet pump housing, cantilevered to the upper end by means of a threaded connection in the upper part of the jet pump housing, in the wall of the guide sleeve of the separator longitudinal slit-like openings are flaxed, while the lower free end of the guide sleeve of the separator is located from the upper end of the stepped passage channel at a distance equal to 0.1 to 0.2 of the diameter of the upper end of the stepped passage channel, the inner diameter of the guide sleeve of the separator is from 1, 1 to 1.2 the diameter of the upper end of the stepped passage channel, and the width of the slit-like holes in the guide sleeve-separator is not greater than the distance between adjacent slit-like holes.

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