RU2205992C1 - Oil-well jet plant for hydraulic fracturing of formation - Google Patents

Abstract

FIELD: oil producing industry. SUBSTANCE: proposed plant includes the following devices mounted on tubing from bottom to top: inlet funnel shank, packer with central channel and jet pump in housing of which active nozzle and mixing chamber are coaxially installed and channel to supply active medium, channel for medium pumped out well and stepped passage channel with seat between steps are made. Provision is made for mounting sealing unit in stepped channel. Sealing unit is installed of movement on logging cable or wire higher than tip for connecting radiator and receiver- transducer of physical fields and functional inserts, namely, interlock insert with through passage channel, pressure differential insert with self- contained instrument and insert for recording curves of restoration of formation pressure in underpacker space well with sample and self-contained instrument furnished with pressure, temperature, production rate and formation fluid composition pickups. Outlet of jet pump is connected to inner space of tubing higher than sealing unit. Nozzle of jet pump is connected through active medium supply channel with well annulus, and channel to supply medium pumped out of well is connected to inner space of tubing below sealing unit. Functional inserts are provided with special devices in upper part for installation and extraction from well. Diameter D₁ of through passage channel of interlock insert is not less than 0.4 of diameter D₂ of stepped passage channel of jet pump housing lower than seat. Diameter D₃ of stepped passage channel higher than seat is greater than diameter D₂ of said channel lower than seat by not less than 0.5 mm. Diameter D₄ of radiator and receiver-transducer of physical fields is smaller by not less than 0.5 mm than diameter D₂ of stepped passage channel lower than seat, and diameter D₅ of central channel of packer. Maximum diameter of functional inserts is smaller than inner diameter D₆ of tubing under jet pump by not less than 1.0 mm and length of each functional insert not less than its maximum diameter. EFFECT: improved reliability. 4 dwg

Description

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

 A well-known jet installation including a jet pump installed in a well on a tubing string and a geophysical device located below the jet pump in a tubing string (see RU 2059891 C1, F 04 F 5/02, 05/10/1996).

 This downhole jet installation allows pumping out various produced media, for example, oil, from a well while treating the extracted medium and the borehole zone of the formation, however, this installation provides for the supply of the working medium to the nozzle of the jet apparatus through a pipe string, which in some cases narrows the scope of this installation.

 The closest to the invention in technical essence and the achieved result is a downhole jet installation containing a packer, a pipe string and a 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 installation is equipped with a transmitter and a receiver-converter of physical fields located on the input side of the jet pump of the medium pumped out of the well and mounted on the cable; m through the axial channel of the sealing unit, 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 the input of the working medium supply channel to the active nozzle is connected to the space surrounding the pumping column -compressor pipes and in the housing of the jet pump, several channels for supplying a pumped medium are made (see patent RU 2106540 C1, cl. F 04 F 5/02, 03/10/1998).

 This jet installation allows for 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 full use of its capabilities, which is associated with suboptimal size ratios of functional inserts, in particular, blocking inserts of a downhole jet installation.

 The problem to which the present invention is directed, is to optimize the sizes of various structural elements of the installation and thereby increase the reliability and performance of the downhole jet installation.

This problem is solved due to the fact that the downhole jet installation contains an inlet funnel with a liner mounted on the pipe string from bottom to top, a packer with a central channel made in it, and a jet pump, in the casing of which the active nozzle and mixing chamber are coaxially mounted, and the channel is made supply of the active medium, a channel for supplying a medium pumped out from the well and a step-through passage channel with a seat between the steps, while it is possible to install a seal in the step passage channel a viewing unit that is movably placed on a wireline or wire above the tip for connecting the emitter and receiver-transducer of physical fields and functional inserts: blocking with a through passage channel, depression with a stand-alone device and inserts for recording reservoir pressure recovery curves in the under-packer space of a well with a sampler and a stand-alone device equipped with, for example, sensors of pressure, temperature, flow rate and composition of the reservoir fluid, the output of the jet pump n to the inner cavity of the pipe string above the sealing unit, the jet pump nozzle is connected to the annulus of the well through the active medium supply channel and 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, while functional inserts are made in the upper part with device for their installation and extraction from the well, the diameter D _{1 of the} through passage of the blocking insert is not less than 0.4 of the diameter D _{2 of the} stepped passage of the building the mustache of the jet pump below the seat, the diameter D _{3 of the} stepped passage channel above the seat is greater than the diameter D _{2 of} this channel below the seat is not less than 0.5 mm, the diameter D _{4 of the} emitter and receiver-converter of physical fields is not less than 0, 5 mm less than the diameter D _{2 of the} stepped passage channel below the seat and diameter D _{5 of the} central channel of the packer, the largest diameter of the functional inserts is less than 1.0 mm less than the inner diameter D _{6 of} the pipe string above the jet pump, and the length of each one of the functional inserts is not less than their largest diameter.

Analysis of the operation of a downhole jet installation showed that the reliability and productivity of the installation can be improved by performing various structural elements of the installation, in particular functional inserts, with strictly defined dimensions. It was found that the implementation in the upper part of the functional insert of the device for its installation and extraction from the well allows you to control the installation process of the insert in the passage channel of the jet pump housing to the seat. In addition, it was found that in the case of each of the functional inserts with a length of at least their largest diameter, it is possible to increase the reliability and tightness of the installation of the functional insert in the passage channel of the jet pump housing. Reducing the likelihood of installation on a seat with a bias allows you to prevent possible flow of medium through the seat, as well as the disruption of the functional insert from the seat with subsequent disruption of the entire installation. In addition, the possible jamming of the inserts in the pipe string and in the jet pump housing during the installation or removal of the functional inserts is prevented. The implementation of these devices with the following size ratios is also aimed at preventing jamming of the pipes being lowered along the pipe string: the diameter D _{3 of the} step-through passage above the seat is greater than the diameter D _{2 of} this channel below the seat by at least 0.5 mm, the diameter D _{4 of the} emitter and receiver-transducer of physical fields is not less than 0.5 mm smaller than the diameter D ₂ the stepped passageway below the seat and the diameter D ₅ of the central channel of the packer, and the largest diameter of functional inserts Men e inner diameter D ₆ of the tubing being not less than 1.0 mm above the jet pump. Equally important is the diameter D _{1 of the} through passage of the blocking insert, which is at least 0.4 of the diameter D _{2 of the} stepped passage of the jet pump housing below the seat. The blocking insert solves the problem of supplying a liquid medium through a pipe string to the under-packer zone and at the same time prevents this medium from entering the annulus of the well and into the jet pump. In this regard, the blocking insert experiences significant pressure drops and at the same time should create as little hydraulic resistance as possible. In the course of research, an acceptable ratio was established between the hydraulic resistance and the mechanical characteristics of the blocking insert.

 Thus, the achievement of the objective of the invention has been achieved - optimizing the size of the structural elements of the installation and thereby improving the reliability and performance of the downhole jet installation.

 In FIG. 1 shows a longitudinal section of the described downhole jet installation with a sealing assembly, FIG. 2 is a longitudinal section of the installation with an insert for recording the reservoir pressure recovery curve, FIG. 3 is a longitudinal section of the installation with a blocking insert, and FIG. 4 is a longitudinal section of the installation with depression insert.

The downhole jet installation comprises an inlet funnel 2 with a liner 3 mounted on a pipe string 1 from bottom to top, a packer 4 with a central channel 5 formed therein, and a jet pump 6, in the housing 7 of which an active nozzle 8 and a mixing chamber 9 are coaxially mounted, and are also made an active medium supply channel 10, a channel 11 for supplying a medium pumped out from the well and a step-through passage channel 12 with a seat 13 between the steps, while in the step-through passage channel 12 it is possible to install a sealing assembly 14, which movably placed on a wireline or wire 15 above the tip 16 for connecting the emitter and receiver-transducer of physical fields 17 and functional inserts: blocking 18 with a through passage channel 19, depression 20 with a stand-alone device 21 and insert 22 for recording reservoir pressure recovery curves in the under-packer the space of the well with a sampler and an autonomous device 23, equipped with, for example, sensors of pressure, temperature, flow rate and composition of the reservoir fluid, the output of the jet pump 6 is connected to the internal the lower cavity of the pipe string 1 above the sealing unit, the nozzle 8 of the jet pump 6 is connected to the annulus of the well (pipe string 1) through the supply channel of the active medium 10 and the channel 11 for supplying the medium pumped out of the well is connected to the internal cavity of the pipe string 1 below the sealing unit 14 while functional inserts 18, 20 and 22 are made in the upper part with a device 24 for installing and removing them from the well, the diameter D _{1 of the} through passage channel 19 of the blocking insert 18 is at least 0.4 of the diameter D _{2 of the} step the passage channel 12 of the housing 7 of the jet pump 6 below the seat 13, the diameter D _{3 of the} stepped passage 12 above the seat 13 is larger than the diameter D _{2 of} this channel 12 below the seat 13 by at least 0.5 mm, the diameter D _{4 of the} emitter and the receiver-transducer of physical fields 17 is not less than 0.5 mm smaller than the diameter D _{2 of the} stepped passage channel 12 below the seat 13 and the diameter D _{5 of the} central channel 5 of the packer 4, the largest diameter of the functional inserts 18, 20 and 22 is smaller than the inner diameter D ₆ pipe strings 1 I am above the jet pump 6 by at least 1.0 mm, and the length of all functional inserts 18, 20 and 22 is not less than their largest diameter.

 In the well on the pipe string 1, a jet pump 6 is installed and a packer 4 and an inlet funnel 2 with a liner 3 located below the jet pump 6. Then, the packer 4 is unpacked, which allows to separate the well space. Next, the emitter and receiver of the physical field transducer 17 are connected to the tip 16 of the cable or wire 15 and the sealing assembly 14 is mounted on the cable or wire 15 to enable the reciprocating movement of the wireline or wire 15 and this assembly is lowered into the internal cavity of the pipe string 1. B during the descent, background measurements of temperature and other physical fields from the wellhead to the bottom of the well are carried out. After that, the liquid working medium is fed into the active nozzle 8 of the jet pump 6, which allows pumping 6 to start pumping from the sub-packer zone of the well of the formation medium. Thus, drainage of the producing formation 25 and cleaning of the formation 25 from the mud filtrate are performed. The parameters in the sub-packer zone of the well are controlled using the emitter and receiver-transducer of the physical fields 17, and at the same time, various depressions on the formation are gradually created, bottomhole pressures, the composition of the fluid coming from the reservoir and the flow rate of the well are recorded. Then, when the jet pump 6 is operating at a given depression value, the emitter and the receiver-transducer of physical fields 17 are moved to the reservoir 25 along the axis of the well in the zone of the reservoir 25 and the inflow profile, parameters of the formation fluid, bottomhole pressure, as well as changes in physical fields in the reservoir are recorded 25, with this, it is possible to carry out the indicated operation several times both with the above specified value of depression per layer 25, and with a different value of depression per layer 25. Then stop they feed the working medium into the jet pump 6 and the emitter and receiver-converter of physical fields 17 with the wireline or wire 15 and the sealing assembly 14 are removed from the well. Then, the pipe 22 is lowered along the pipe string 1 and insert 22 in the passage channel 12 to the seat 12. for recording the curves of reservoir pressure recovery in the under-packer space of the well together with a sampler and an autonomous device 23 equipped with sensors for pressure, temperature, flow rate, formation fluid composition, etc. A 6-wire jet pump the pumping-out of the formation medium is performed and the necessary depression is created on the formation 25 and after the estimated time of drainage of the productive formation, the supply of the working medium to the nozzle 8 of the jet pump 6 is abruptly stopped. The formation pressure recovery curve is recorded in the under-packer space of the well, after which insert 22 is removed and a blocking insert is installed 18 with a through passage channel 19, blocking the blocking insert 18 in the jet pump 6, channel 11 for supplying the medium pumped out from the well and exiting the jet pump 6. P After this, the solution is injected into the reservoir 25 for processing or fracturing. Then, the blocking insert 18 is removed, the depressing insert 20 is placed in place of the blocking insert 18, separating the pipe string 1 into the upper zone communicated with the outlet of the jet pump 6, and the lower zone communicated with the channel 11 for supplying the medium pumped out of the well. An active liquid medium is supplied to the nozzle 8 of the jet pump 6. The latter, flowing out from the nozzle 8 of the jet pump 6, entrains the formation fluid from the well together with the reaction products formed as a result of interaction with the solution that was previously pumped into the reservoir 25. After that, if necessary, it is possible to reinstall the insert 22 for registration in the passage channel 12 a pressure recovery curve or a sealing assembly 14 with placement of the emitter and receiver-transducer of physical fields 17 in the formation zone for processing the reservoir 25. After completion of the above work on the study of SLE zhiny and processing reservoir 25 can be installed in the well to pump oil from the well fluids.

 The present invention can be used in the oil and mining industries in testing and stimulating the influx of oil and gas wells at the stage of drilling or restoration.

Claims (1)

A downhole jet installation comprising an inlet funnel with a liner mounted on the pipe string from bottom to top, a packer with a central channel made therein, and a jet pump in the housing of which an active nozzle and mixing chamber are coaxially mounted, and an active medium supply channel and a channel for supplying pumped from the well of the medium 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 that is movably placed n on a logging cable or wire above the tip for connecting the emitter and receiver-transducer of physical fields and functional inserts: blocking with a through channel, depression with a stand-alone device and inserts for recording reservoir pressure recovery curves in the under-well space of the well with a sampler and a stand-alone device equipped with , for example, by sensors of pressure, temperature, flow rate and composition of the formation fluid, the output of the jet pump is connected to the inner cavity of the pipe string above the sealing unit, the jet pump nozzle is connected to the annulus of the well through the active medium supply channel, and the channel for supplying the medium pumped out of the well is connected to the inner cavity of the pipe string below the sealing unit, while the functional inserts are made in the upper part with a device for installing and removing them from a well, the diameter D ₁ of the through flow channel of the locking insert is not less than 0.4 stepwise diameter D ₂ of the through passage of the jet pump housing below the mounting m hundred, the diameter D ₃ staged passageway above the mounting space of the channel larger than the diameter D ₂ below the seat is not less than 0.5 mm, the diameter D ₄ and the emitter-receiver transducer of physical fields is not less than 0.5 mm smaller than the diameter D ₂ step passage channel below the seat and the diameter D _{5 of the} central channel of the packer, the largest diameter of the functional inserts is less than the inner diameter D _{6 of} the pipe string above the jet pump by at least 1.0 mm, and the length of each functional insert is not less than and x of the largest diameter.

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