RU171999U1 - Hydroimpulse jet generator for well treatment - Google Patents

Abstract

The utility model relates to the oil and gas industry and can be used to increase the production of gas, oil, water wells, as well as the injectivity of injection wells and the intensification of fluid inflow from a productive formation. A waterjet jet generator for treating wells consists of a stator with radial holes and a rotor with cylindrical holes made tangentially to the inner surface of the rotor and located on one side of the rotor along its entire length on one line perpendicular to the axial horizontal line of the generator, and with this on the same side of the rotor, a flat cut is made along the entire length, while an upper ring is welded along the perimeter to the stator, movable relative to the rotor, to which the intermediate a weft ring movable relative to the stator, and the last in the lower part is provided with a lower ring, rigidly connected with the stator and a pin, on which the cover is fixed to ensure sliding of the rotor along its upper surface. The utility model allows to increase the efficiency of development of the bottomhole zone of the well. An increase in the permeability of the bottomhole formation zone is achieved due to the impact of rotating hydraulic pulses on the treated object, which is achieved by the design of the device. 1 ill.

Description

The utility model relates to the oil and gas industry and can be used to increase the production of gas, oil, water wells, as well as the injectivity of injection wells and the intensification of fluid inflow from a productive formation.

A device for influencing a reservoir is known, including a tubing string and a reservoir on the surface. The tubing string is equipped with a set of cylinders with landing seats, equipped with a lubricator at the mouth and connected to the discharge line of the pump unit. The annulus of the well and the intake line of the pump unit are connected to the tank on the day surface, and an elastic elastic ball is placed inside the tubing string through the lubricator (patent RU2151283, IPC E21B 43/25, publ. 06/20/2000).

The disadvantages of the device are a slight increase in well productivity after exposure and the short-term effect observed.

It is also known a device for hydrodynamic effects on the bottomhole zone of a well, comprising a housing, injection and discharge chambers, which are separated from each other by a locking element in the form of a ball made of elastic material. A jet pump is installed in the upper part of the device, hydraulically connected to the injection chamber of the hydrodynamic device by an eccentric channel, with a saddle in the upper part of the channel, locked by a ball valve discharged from the wellhead, and an easily pressed plug with a sealant and a safety lamp is placed on the outlet of the jet pump (patent RU 29333, IPC E21B 43/00, published on 05/10/2003).

The disadvantage of this device is the inability to repeatedly change the processing modes of the bottomhole zone of the well without lifting the string of tubing.

Also known hydroimpulse installation for well development (patent RU2263207, IPC E21B 43/25, publ. 10/27/2005), which includes a pressure accumulator and a submersible pump. The pressure accumulator at the bottom is equipped with a movable seat with a return spring resting on a protective grill. The impact on the piston of the pump drive is carried out directly by the working fluid supplied by the pumping unit from the wellhead. The cavity formed by the piston of the pump drive is hydraulically connected to the annular space formed by the casing and tubing string through one or more radial openings of the pump drive sub. The downhole pump at the bottom is equipped with a valve that prevents the transmission of a pressure pulse to the under-packer zone. The efficiency of well development due to the pulsed impact on the reservoir increases.

Installation is very difficult in a constructive sense.

The objective of the utility model is to increase the efficiency of well development.

The technical result is an increase in permeability of the bottomhole formation zone due to the design features of the generator.

The problem is solved, and the technical result is achieved by a hydro-pulse jet generator for treating wells, consisting of a stator with radial holes and a rotor with cylindrical holes made tangentially to the inner surface of the rotor and located on one side of the rotor along its entire length on one line perpendicular to axial horizontal line of the generator, and on the same side of the rotor along the entire length a flat cut is made, while the upper ring is welded along the perimeter of the stator, moving relative to the rotor, to which an intermediate ring is movable from below, movable relative to the stator, and the last in the lower part is equipped with a lower ring, rigidly connected to the stator and a pin, on which the cover is fixed to ensure sliding of the rotor along its upper surface.

The technical result is achieved as follows.

Due to the arrangement of cylindrical holes made tangentially to the inner surface of the rotor, on one side of the rotor and the presence of a cut of the rotor on the same side, additional torsional oscillations of the generator with large amplitude are created, transmitted to the surrounding fluid and to the bottom hole zone of the well, which creates favorable conditions for increasing permeability of the treated object (reservoir).

The essence of the utility model is illustrated by the drawing, which shows the inventive jet jet pulse generator for processing wells.

The generator includes a stator 1, an upper ring 2, a rotor 3 (the right half of the rotor is shown in a sectional view), a lower ring 4, an intermediate ring 5, a stud 6, an abutment nut 7, lock nuts 8. The casing string is shown at 9. Radial holes A are made in stator 1, holes B are made in rotor 3 tangentially to the inner surface of the rotor, located on one side of the rotor along its entire length on one line perpendicular to the axial horizontal line of the generator, B is the top surface of the cover (position not marked) along which the rotor slides.

The generator operates as follows.

The fluid pumped by the pumping unit from the surface, circulating through tubing (not shown), enters the stator 1 and, flowing out of the radial holes A, enters the annular space between the stator 1 and the rotor 3. Next, the liquid enters the cylindrical holes of the rotor B The rotor 3 due to the reaction of a high-pressure flowing jet, sliding along the surface B, receives rotation with a certain number of revolutions and the amplitude of the amplified torsional vibrations due to the imbalance of the rotor 3, as a result of which Powerful rotating hydroimpulses are sent to the target object, contributing to an increase in the permeability of the reservoir.

Thus, the utility model allows to increase the efficiency of development of the bottomhole zone of the well. An increase in the permeability of the bottomhole formation zone is achieved due to the impact of rotating hydraulic pulses on the treated object, which is achieved by the design of the device.

Claims (1)

Hydroimpulse jet generator for processing wells, consisting of a stator with radial holes and a rotor with cylindrical holes made tangentially to the inner surface of the rotor and located on one side of the rotor along its entire length on one line perpendicular to the axial horizontal line of the generator, and with on the same side of the rotor, a flat cut is made along the entire length, while an upper ring is welded along the perimeter to the stator, movable relative to the rotor, to which the bottom is welded an intermediate ring movable relative to the stator, and the latter in the lower part is provided with a lower ring, rigidly connected to the stator and a pin, on which the cover is fixed to ensure sliding of the rotor along its upper surface.

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