RU2222717C1 - Well jet plant for alternating hydrodynamic bottom hole zone treatment - Google Patents

Abstract

FIELD: oil producing industry. SUBSTANCE: invention relates to pumping facilities designed for production of oil. Proposed well jet plant contains packer with central channel and jet pump with active nozzle and mixing chamber with diffuser arranged in pump housing and channel for admission of working agent and for pumped out formation fluid, packer and pump are installed in tandem from bottom to top. Jet pump is provided with working agent flow direction selector made in form of changeable functional hollow shaped insert in form of sleeve with holes in side wall communicating through output with channel for pumped out formation fluid. Said insert is provided in upper part with valve spring-loaded relative to insert and made in form of cylindrical shell enclosing the insert and provided with holes in wall. With valve in upper position, holes of shell register with holes in side wall of sleeve and through said holes hollow insert is connected to inner space of tubing string from inlet side. Length is selector is not less than 1.2 of its outer maximum diameter. Output of jet pump is connected to string annulus. Nozzle of jet pump is connected through working agent admission channel to inner space of tubing string higher than insert, and channel for pumped out formation fluid is connected to inner space of tubing string lower than packer. Invention improves reliability and increase capacity of well jet plant at treatment of productive stratum. EFFECT: increased yield of production and intake capacity of injection wells owing to restoration of permeability of bottom hole zone. 2 cl, 1 dwg

Description

The invention relates to the field of pumping technology, mainly to downhole pumping units for testing and development of wells.

A well-known jet installation comprising a packer installed on a column of tubing and a jet pump with a central passage (see SU 1668646 A1, E 21 B 43/27, 08/07/1991).

This downhole jet installation allows pumping out various produced media, for example, oil, from a well while processing the extracted medium from the near-wellbore zone of a productive formation, however, the absence of the possibility of creating different modes of action on the near-wellbore zone of the formation 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 comprising a packer mounted on the pipe string from the bottom up with a central channel made therein and a jet pump in the housing of which an active nozzle and a mixing chamber with a diffuser are installed, as well as a channel the supply of the working agent, the channel for supplying fluid pumped out of the well, while in the housing of the jet pump, a passage channel is made with the possibility of installing a replaceable functional insert in it and sealing unit (see patent RU 2176336 C1, class F 04 F 5/02, 11.27.2001).

This downhole jet installation allows the formation to be processed in the well below the level of the jet pump installation, including creating a pressure differential above and below the sealing unit. However, the capabilities of a downhole jet installation are not used to the full, due to the insufficient range of the amplitude of the hydraulic effect and the long time for pressure recovery, especially at low permeability of the borehole zone of the reservoir.

The problem to which the present invention is directed, is to increase the reliability and productivity of a downhole jet installation during processing of a productive formation and, thus, increase production rates and injectivity of injection wells by restoring the permeability of the borehole formation zone.

This problem is solved due to the fact that the downhole jet installation for alternating hydrodynamic effects on the borehole zone of the formation contains mounted on the pipe string from the bottom up to the packer with a central channel made in it and a jet pump in the housing of which an active nozzle and a mixing chamber with a diffuser are installed, as well as a supply channel for the working agent, a channel for supplying the fluid pumped out of the well, and a switch for the flow direction of the working fluid is installed in the housing of the jet pump nta, which is a removable hollow profiled insert in the form of a sleeve with holes in its side wall, connected from the exit side to the supply channel for the fluid pumped out of the well, and in its upper part the insert is equipped with a spring-loaded valve made in the form of a cylindrical with holes in its wall of the shell covering the insert, and in the upper position of the valve, the holes of the shell are aligned with the holes in the side wall of the sleeve and through the last hollow insert from the input side it is connected to the annular space of the pipe string, the nozzle of the jet pump through the supply channel of the working agent is connected to the internal cavity of the pipe string above the insert, and the channel for supplying The fluid pumped from the well is connected to the inner cavity of the pipe string below the packer.

It is preferable that the area of the valve openings and the inserts, when combined, exceed the area of the outlet cross section of the active nozzle by at least 3 times.

Analysis of the operation of the well jet installation showed that the reliability and efficiency of the installation can be improved by optimizing the design of the installation and thereby achieve more complete cleaning of the borehole formation zone in the wells.

It was found that the hydrodynamic effect on the borehole zone of the well allows the most efficient use of the downhole jet unit in the development and repair of oil and gas wells during work to intensify the influx of oil from the reservoir. Moreover, the installation allows you to carry out control measurements both before and during the treatment, which in turn allows you to evaluate the technical condition of the well and the properties of the fluid that is produced from the well. Based on the results of studying the inflow, it is possible to assess the quality of processing the near-wellbore zone of the reservoir. The installation with a switch of the flow direction of the working agent allows alternating hydrodynamic effects on the formation with the formation of water hammer, which increases the radius and quality of the processing of the borehole zone of the formation. With the created depression, the jet pump promptly removes clogging particles from the producing formation, which are clogged by the annular space of the pipe string and are brought to the surface at high speed. The combination of an adjustable alternating operating mode of the installation (depression - repression), which is set using the switch of the working agent flow direction, provides an opportunity to choose a mode of operation in which not only the permeability of previously not working interlayers is restored, but also the permeability of previously working interlayers is increased, and therefore , increases the flow rate of the produced medium (fluid) from the productive layers of the reservoir. It was found that a step-by-step transition from depression to the formation to repression to the formation with a cyclic repetition of this operation and, most importantly, a sharp transition from repression to the productive formation with the formation of a hydraulic shock to depression is essential for effective impact on the formation. Due to such a sharp transition from repression to depression, the effect of the working agent on the reservoir is enhanced, which can significantly increase the permeability of the reservoir. It is this mode of operation of the installation that allows you to establish a combination of the operation of the jet pump with a switch. As a result, it was possible to increase the coefficient of the effective thickness of the reservoir by a factor of 1.5–2 due to the destruction of the zone of mudding in idle layers of the productive formation and, as a result, to speed up the work to increase well productivity by 1.2–1.6 times, moreover, the inflow profile is substantially leveled due to a more complete coverage of the reservoir by hydrodynamic influence over its thickness.

When the unit is operating, the precise installation of the switch in the jet pump housing is essential. This is achieved due to the fact that the length of the switch is not less than 1.2 times its maximum outer diameter. This allows you to install the switch in the jet pump housing without distortions, which ensures the smallest hydraulic losses of the flow of the working agent from the pipe string into the sub-packer zone of the well. As a result, it is possible to form a spasmodic character of pressure changes during the transition from depression to repression. It is preferable that the area of the holes in the switch valve and in the insert be at least 3 times larger than the area of the outlet section of the active nozzle. The control measurements data obtained during the operation of the installation make it possible to obtain an objective picture of the state of the borehole zone of the reservoir, depending on the work carried out to increase its permeability.

Thus, the achievement of the task has been achieved to increase the reliability of work and productivity during the processing of the borehole zone of the reservoir.

The drawing shows a longitudinal section of a downhole jet unit for implementing the described method of operation.

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 with a diffuser 9 are installed, and the channel 10 for supplying the working agent and the channel 11 for supplying the fluid pumped out of the well are made. In the housing 7 of the jet pump 6, a switch 12 for the direction of flow of the working agent is installed, made in the form of a replaceable functional hollow profiled insert 13 in the form of a sleeve with holes 14 in its side wall, communicated from the outlet side of it with the channel 11 for supplying fluid pumped from the well, and in its upper part, the insert 13 is equipped with a valve 15 spring-loaded relative to it, made in the form of a shell with holes 16 in its wall, covering the insert 13, and in the upper position of the valve 15 of the hole 16, the casing the yokes are aligned with the holes 14 of the side wall of the insert 13 and through the last hollow insert 13 from the input side it is connected to the inner cavity of the pipe string 1, the length L of the switch 12 is at least 1.2 of its external maximum diameter D, the output of the jet pump 6 is connected to the annular the space of the pipe string 1, the nozzle 8 of the jet pump 6 through the channel 10 for supplying the working agent is connected to the inner cavity of the pipe string 1 above insert 3 and the channel 11 for supplying fluid pumped out of the well is connected to the internal cavity of the pipe string 1 below the pack and 4.

Preferably, the area of the holes 16 of the valve 15 and the area of the holes 14 of the insert 13 during their combination exceeds the area of the output section of the active nozzle 8 by at least 3 times.

The method of operation of a well jet device with hydrodynamic effects on the borehole zone of the formation consists in lowering a funnel 2, a liner 3, a packer 4 and a jet pump 6 with a working agent flow direction switch 12 installed in it to a well of tubing 1; . The valve 15 of the switch 12 under the action of the spring is in its lower position and the holes 14 of the insert 13 do not coincide with the holes 16 of the valve 15. Install the packer 4 and the jet pump 6 above the roof of the reservoir 17 and unpack the packer 4. Then, using the pump unit, periodically feed the working agent into the nozzle 8 of the jet pump 6 (for example, water or oil), and the operation of the jet pump 6 is carried out in the following mode: sharply feed the working agent into the nozzle 8 of the jet pump 6 at a given pressure of the pump unit and that creates a depression in a few seconds on the reservoir 17. Supports action on this depression reservoir 17 during, for example, from 2 to 20 min by a constant flow of the working agent in nozzle 8 of the jet pump 6 at a predetermined pressure pump unit. Then, for example, using the logging cable, the valve 15 is raised to the upper position. In this way, the holes 16 of the valve 15 are combined with the holes 14 of the insert 13. As a result, repression on the reservoir 17 in the form of a water hammer by applying pressure to the reservoir 17 with the pressure of the working agent from the pipe string 1 is created abruptly, which is achieved due to the sharp, as indicated above, switching its supply from the pipe string 1 through openings 14, 16 and the channel 11 for supplying the pumped fluid into the under-packer space. In this case, the hydraulic shock is directed towards the reservoir 17, which leads to disruption of the particles of colmatant located in the pore channels of the reservoir 17, as well as to the formation of microcracks in the borehole zone of the reservoir. In this case, the pressure of the working agent on the reservoir 17 is greater than the reservoir pressure. Then, the supply of the entire working agent to the nozzle 8 of the jet pump 6 is sharply switched by returning the valve 15 to its initial lower position and blocking the holes 15 of the insert 13 with the valve 15, which allows you to repeat the above-described cycle of exposure to the borehole zone of the reservoir 17 with depression and then repression, and the amount cycles of “depression + repression” is determined by the degree of restoration of permeability of the borehole zone of the reservoir 17 by periodically monitoring the flow rate of the well before and during essays cyclical impact on the near-producing formation zone 17. If the last two test wells measuring performance is not increased, the work stopped.

The amount of repression, if necessary, can be adjusted by setting the necessary pressure of the working agent in the pipe string 1 before switching its supply to the under-packer space.

If there is a need for a complex effect on the borehole zone of the formation, it is possible to inject an acid solution into the reservoir through the jet pump 6, which, in combination with hydrodynamic influence, can enhance the effect on the reservoir 17. In addition to the switch 12 in the jet pump 6, another functional an insert, for example, an insert that blocks the flow of the acid solution into the nozzle 8 and the mixing chamber with the diffuser 9 of the jet pump 6.

The present invention can be used in the oil and gas industry for well development after drilling or for their underground repair in order to intensify hydrocarbon production or increase the injectivity of injection wells.

Claims (2)

1. A downhole jet unit for alternating hydrodynamic effects on the near-wellbore zone of the formation, comprising a packer mounted on the pipe string from the bottom to the top with a central channel and an inkjet pump in the casing of which there is an active nozzle and a mixing chamber with a diffuser, as well as an inlet channel working agent, a channel for supplying fluid pumped out from the well, while in the case of the jet pump, a switch for the direction of flow of the working agent is installed, which is a removable floor a profiled insert in the form of a sleeve with holes in its side wall, communicated from the exit side with a supply channel for the fluid pumped out of the well, and in its upper part the insert is equipped with a valve spring-loaded relative to it, made in the form of a cylindrical shell with holes in its wall, covering the insert, and in the upper position of the valve, the holes of the shell are aligned with the holes of the side wall of the sleeve and through the last hollow insert from the input side is connected to the inner cavity of the pipe string, d the switch is at least 1.2 of its outer maximum diameter, the outlet of the jet pump is connected to the annular space of the pipe string, the nozzle of the jet pump through the supply channel of the working agent is connected to the inner cavity of the pipe string above the insert, and the channel for supplying the fluid pumped out of the well is connected to the internal cavity pipe columns below the packer. 2. Installation according to claim 1, characterized in that the area of the valve openings and the inserts when they are combined exceeds the area of the output section of the active nozzle by at least 3 times.

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