EA028831B1 - Device for perforation of wells and mud-pulse treatment of the bottomhole formation zone - Google Patents

Abstract

The invention relates to the oil and gas production industry, to the field of drilling and operation of wells, namely to devices for secondary opening and mud-pulse treatment of productive formations. The device comprises a hydromechanical piercing perforator connected with the tubing string, a reusable implosion chamber 1, in the form of a cylindrical housing 2 with an expansion 3 in the upper part with plunger 4 connected with rope 5. A wedge-piston 6 is connected to the lower part of the implosion chamber 1, between which a shutoff valve 7 is made and the overflow channel 8 is provided. The wedge-piston 6 is built into the housing of the hydromechanical perforator, made in the form of a cylinder 9, in the upper part of which a piston cavity 10 is formed, communicating with the inner cavity of the implosion chamber 1 and the tubing string, through the overflow channel 8. In the lower part of cylinder 9, there is a support 11 on which punches 12 are installed, interacting with the working planes of the wedge-piston 6 via the "dovetail" type connection. In the wedge-piston 6, the supply channels 13 are provided communicating the piston cavity 10 with the jetting channels 14 of punches 12. When operating in wells requiring greater hydraulic impact power to break through the casing string 15, an overflow valve 16 can be installed in the supply channel 13, which opens exit of the fluid into the jetting channel 14, only after the cylinder 9 is completely moved upward. The technical result is fixation of the perforator with exclusion of undesirable axial displacements during its operation in the well.

Description

The invention relates to the oil and gas industry, to the field of drilling and operation of wells, namely, devices for the secondary opening and hydroimpulse treatment of productive formations. The device contains a hydromechanical piercing punch connected to the tubing, reusable implosion chamber 1, in the form of a cylindrical body 2 with expansion 3 in the upper part with a plunger 4 connected to the rope 5. A wedge-piston 6 is connected to the lower part of the implosion chamber 1, between which shut-off valve 7 is placed and a flow-through channel 8 is made. The wedge-piston 6 is built into the housing of a hydromechanical perforator, made in the form of a cylinder 9, in the upper part of which a piston cavity 10 is formed, communicating with the inner it has a cavity of the implosion chamber 1 and the tubing, through the flow-through channel 8. In the lower part of the cylinder 9 there is a support 11, on which are installed the punches 12, which interact with the working planes of the wedge-piston 6 through the dovetail connection. In the wedge-piston 6, the inlet channels 13 are made, communicating the piston cavity 10 with the jetting channels 14 of the piercers 12. When working in wells requiring greater energy of a hydraulic shock to break the casing 15, an overflow valve 16 can be installed in the inlet channel 13, which opens the working outlet fluid in the jet channel 14, only after full movement of the cylinder 9 up. The technical result is the fixation of the punch with the exception of unwanted axial movements during its operation in the well.

028831 Β1

028831

The invention relates to the oil and gas industry, to the field of drilling and operation of wells, namely, devices for the secondary opening and hydroimpulse treatment of productive formations.

Widely known are installed on the geophysical cable device cumulative perforation and processing of the bottomhole formation zone by the method of implosion (KI 2211313, 08/27/2003, KI 3131512, 06/10/1999, Ki 2072421, 27.01.1997). The disadvantage of all these devices is that the opening and subsequent processing of the bottomhole formation zone (PPP) of a separate interval in the well is carried out only once, because after each processing cycle requires the replacement of the elements of the device. The devices are technically limited in use in combination with other perforators, with the exception of cumulative (explosive), a significant drawback of which is the high risk of their use in oil and gas wells.

A device for creating perforation channels in a well, mounted on a tubing string, includes a housing, a wedge with a groove, a hydraulic cylinder and at least one working member with a jetting channel placed in the groove of the support and a wedge with the possibility of radial reciprocating displacement, while the wedge is installed above the piston of the hydraulic cylinder, on which the support of the working body is fixed, and the sub-piston cavity is communicated by means of tubes with the jetting channel of the working body and the nickle tube working fluid supply (patent for the invention of the Russian Federation No. 2521427, publ. 06/27/2014).

The closest technical solution chosen by the applicant as a prototype is a device for hydro-mechanical perforation of wells and hydro-impulse treatment of productive formations, which uses the impulse of hydraulic shock generated by the implosion chamber. The device contains a hydromechanical piercing punch installed in the well and interacting with the tubing string column, in the casing of which at least one piercer is installed, which is capable of moving in the radial direction under the pressure of the working fluid, the piercer is provided with a jetting channel with a shut-off valve, in the upper part of the perforator casing there is a hydraulic actuator, made in the form of an imilosion chamber (cylinder), inside which it has the ability to move the plunger, the device has a flow channel, the upper part of the implosion chamber is made with an extension (ЕА № 2013301096 А1, publ. 04/30/2015).

The disadvantages of the prototype is that when the device is fixed in the well from its axial movement while working down, a separate anchor is used, for which reliable installation requires preparatory work to clean the inner surface of the casing from asphalt, resin and paraffin deposits, which provides for an additional lifting operation of special equipment (scraper, brushes, etc.). For concentrating the impulse of a hydraulic impact on the bottomhole formation zone (PPP), a separate unit is used - a packer or packers, which complicates the design of the device and causes instability of its operation.

The technical problem of the invention is to improve the reliability of operation of the device while simplifying its design.

Achievable technical result - fixing the punch with the exception of unwanted axial movements during its operation in the well.

The technical problem is achieved by the fact that the device for perforation of wells and hydroimpulse treatment of the bottomhole formation zone contains a hydromechanical piercing perforator installed in the well and interacting with the tubing string and in which case at least one piercer is installed that can be moved in the radial direction under the pressure of the working fluid, the punch is equipped with a jetting channel, in the upper part of the body of the perforator is installed hydraulic one with a shut-off valve, the hydraulic actuator is represented by an implosion chamber made of a cylindrical shape with an expansion in the upper part, inside which the plunger is placed with the possibility of its movement, a flow-through channel is made in the perforator, characterized in that the perforator body is a cylinder, in the lower part of which there is a support , a wedge-piston is installed in the cylinder, equipped with at least one supply channel, a wedge-piston is rigidly connected to the implosion chamber, and a shut-off valve is built in between them, at least one The piercer is mounted on a support and has the ability to move along the working plane of the wedge-piston until the wedge-piston supply channel is aligned with at least one piercing channel of the piercer.

The flow channel of the wedge-piston can be additionally equipped with an overflow valve, which provides additional force for the puncture of the walls of the casing, made of hardened steel.

A comparison of the proposed technical solution with the prototype shows that it has the following features:

the punch body is a cylinder, in the lower part of which there is a support; a wedge-piston is installed in the cylinder, equipped with at least one supply channel; the wedge piston is rigidly connected with the implosion chamber;

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between the implosion chamber and the wedge-piston a shut-off valve is integrated; the piercer is mounted on a support;

the punch has the ability to move along the working plane of the wedge-piston to align the supply channel of the wedge-piston with at least one jetting channel of the punch;

the cylinder has the possibility of axial movement relative to the wedge-piston.

Therefore, we can assume that the claimed technical solution meets the criterion of "novelty."

The inventive device can be performed on standard equipment using known technological processes, so it meets the criterion of "industrial applicability".

The reliability of the device in operation is enhanced by using the wedging effect, which is provided by placing the punchers on the working planes of the perforated wedge-piston, during axial movement of which the perforators move apart radially from the axis of the perforator, form openings in the casing, and also fix the device from its axial downward movement of the well during hydro-pulse treatment of the PPP. The simplicity of the claimed design of the device eliminates the need to use packers to concentrate the pressure on the PPP, due to the same wedging effect, in which the piercers with hydrochannels are displayed behind the casing, while the body of the piercers blocks the dispersion of the hydraulic shock pulse into the well, concentrating it only on the PPP. When conducting patent information studies, the claimed set of features was not identified, therefore, the technical solution meets the criterion of "inventive step".

FIG. 1 schematically shows a general view of the device in a partially axial section in the transport position.

FIG. 2 schematically shows a general view of the device in a partially axial section in the working position.

FIG. 3 schematically shows a general view of the device in a partially axial section with a wedge piston with one working plane, two jetting channels in the piercer and the overflow valve.

The inventive device includes a hydromechanical piercing punch connected to the tubing string, reusable implosion chamber 1, in the form of a cylindrical body 2 with expansion 3 in the upper part with a plunger 4 connected to the rope 5. A wedge piston 6 is attached to the lower part of the implosion chamber 1, between which a shut-off valve 7 is placed and a flow-through channel 8 is made. The wedge-piston 6 is built into the housing of a hydromechanical perforator, made in the form of a cylinder 9, in the upper part of which a piston cavity 10 is formed, co Flying with the internal cavity of the implosion chamber 1 and the tubing, through the overflow channel 8. In the lower part of the cylinder 9 there is a support 11 on which two punches 12 are installed, each of which interacts with the corresponding working plane of the wedge-piston 6 through the dovetail connection. In the wedge 6, the inlet channels 13 are made, communicating the piston cavity 10 with the jetting channels 14 of the piercers 12. The cylinder 9 is adapted to axially move relative to the wedge-piston 6. When operating in wells requiring a greater energy of a hydraulic shock to break the casing 15 into the inlet channel 13 can be installed overflow valve 16 (Fig. 3), which opens the outlet of the working fluid in the jetting channel 14, only after the cylinder 9 is fully moved upwards.

The operation of the device is as follows.

The hydromechanical piercing punch on the tubing string is lowered into the well to a predetermined perforation interval and the inner cavity of the tubing and the implosion chamber 1 is filled with working fluid (acid solutions, hydrocarbon solvents, surfactants, etc.). Then, the plunger 4 is lowered into the lower part of the implosion chamber 1 on the rope 5, after which the plunger 4 starts to move upwards, creating a vacuum underneath, since the inflow of the well fluid is blocked by a shut-off valve 7. At this time, the pressure in the tubing cavity corresponds to hydrostatic. Therefore, the differential pressure above and below the plunger 4 reaches values in the hundreds of atmospheres. As soon as the plunger 4 enters the expansion 3 of the implosion chamber 1, then under the action of a pressure differential, the working fluid rushes down. In this case, the pressure differential accelerates the flow of fluid and when meeting it with the shut-off valve 7, it has a high speed (up to 100 m / s) and a significant shock pulse (the kinetic energy of the falling fluid turns into the energy of a water hammer and reaches values in the hundreds of atmospheres). As a result, the shut-off valve 7 opens and the liquid flows through the flow-through channel 8 into the piston cavity 10 of the cylinder 9, moving it and the support 11 fixed with it upwards. When this, the punches 12, mounted on the support 11, sliding along the working planes of the wedge-piston 6, move from its tip to the base and form holes in the casing string 15 and the hydraulic channels 14 of the piercers 12 are aligned with the supply channels 13 of the wedge-piston 6. Then the plunger 4 is again moved to create a vacuum in the implosion chamber 1 and, when it enters the expanded part 3, the working fluid again rushes down. The fluid passes through the overflow 8, the inlet 13 and the jetting 14

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channels at high speed, rushes into the annular space, acting on the PPP impulse of water hammer, which leads to the formation of a network of cracks in it. PZP processing cycles in this interval are performed as many times as necessary, after which the tubing is moved upwards to the next perforation interval. While moving, the tubing carries away the implosion chamber 1 with a wedge-piston 12. At the same time, the punches 12 are removed from the column 15 due to their rigid connection with the working planes of the wedge-piston 12. The punches are shifted to the initial, transport position, and with them cylinder 9 returns to its initial position. At the end of the perforation and processing of all intervals, the claimed device is removed from the well.

The simple design of the inventive device allows to increase reliability by fixing it from unwanted axial movements when operating in the well, and does not require the use of packers to ensure the concentration of pressure during the hydroimpulse treatment of the PPP.

Claims (3)

CLAIM 1. A device for hydro-impulse treatment of the near-wellbore zone of the formation contains a hydromechanical piercing punch that can be installed in the well and interacts with the tubing string, in which case at least one piercer is installed, which is capable of moving in the radial direction under the influence of the working fluid pressure , moreover, the punch is equipped with a hydraulic channel, installed in the upper part of the punch housing hydraulic actuator with a shut-off valve; the hydraulic drive is made in the form of an implosion chamber having a cylindrical shape with an expansion in the upper part, inside which the plunger is placed with the possibility of its movement, a perforation channel is made in the perforator, characterized in that the perforator housing has the shape of a cylinder, in the lower part of which is a support, in the cylinder a wedge-piston is installed, equipped with at least one supply channel, and the wedge-piston is rigidly connected to the implosion chamber, between which a stop valve, at least one piercer is built mounted on a support and configured to move along the working plane of the wedge-piston to align the supply channel of the wedge-piston with at least one jetting channel of the piercer. 2. The device according to claim 1, characterized in that the flow channel of the wedge-piston is equipped with an overflow valve. - 3 028831