RU222429U1 - Device for creating perforation channels in a well - Google Patents

Abstract

The utility model relates to the field of drilling and operating wells, namely to a device for creating perforation channels in a well. The technical result is to increase reliability and increase the technological capability of well perforation as a whole. The device contains a housing and punches. Each punch has a piston with a flushing channel for supplying working fluid and is installed with the ability to move in the radial direction, relative to the well axis, under the influence of working fluid pressure. The body consists of body segments connected to each other by flexible high-pressure rubber hoses. Each housing segment has a technological channel and a punch having a piston with a flushing channel for supplying working fluid. Technological holes are made in flexible high-pressure rubber hoses under the piston and flushing channel. A check valve is installed at the bottom of the lower housing segment. The upper segment of the housing is designed to be installed on a tubing hanger. 1 ill.

Description

The utility model relates to the field of drilling and operation of wells, namely to a device for secondary opening of productive formations by creating perforations in the production strings of oil, gas and injection wells, destroying the cement ring and creating channels in the perforation interval.

Various devices for secondary opening of the formation are known from the state of the art, for example:

hydrosandblasting perforators for casing strings, the operation of which is based on the formation of perforations under the influence of a jet of working fluid with abrasive elements (sand, proppant...). The disadvantage of such hammer drills is the rapid wear of the hydraulic jet nozzles, and the rise in cost of hammer drills (in the manufacture of nozzles from sapphires, or closed nozzles that open when the balls are dropped and the next ports are opened), which leads to the need for additional hoisting operations to replace them and, as a consequence, to an increase in process duration and material costs;

hydromechanical hammer drills using cutting tools in the form of knurled discs. When repeated rolling along the surface of the production string under load, plastic deformation occurs. A disk hammer includes a housing, a retractable cutting tool in the form of two cutting disks mounted on axes, a piston-pusher with a central and two side hydraulic channels equipped with two hydraulic jet nozzles. Almost all known hydromechanical perforators used to open casing columns form one or two slots located in the same plane, which does not allow them to withstand rock pressure of tens of MPa for a long time. The structural integrity of the production string is compromised, resulting in a high probability of collapse of the production string.

A device for perforating wells is known (patent RU No. 60132, MPK E21B 43/114, published January 10, 2007, Bulletin No. 1), containing a housing with a piston located in its cylindrical cavity, which is connected to tubing ), at least two punches, each of which has at least one flushing channel for supplying working fluid, clamps configured to bring them into contact with the inner surface of the production string to keep the device from moving below the perforation interval, when In this case, each punch is installed with the ability to move in the radial direction by means of a corresponding power cylinder communicated with the cylindrical cavity of the housing with the ability to ensure movement of the punches as a result of creating working fluid pressure in the cylindrical cavity of the housing under the influence of the weight of the tubing suspension. Each punch is made with a stop that allows you to uniformly form holes in the production string and center the device along the axis of the well.

A device is known for creating deep penetration perforation channels in oil and gas wells (patent RU No. 2403380, IPC E21B 43/114 publ. November 10, 2010, Bulletin No. 31), containing punches located in the housing, each of which has a piston and flushing channel for supplying working fluid and is installed with the ability to move in the radial direction under the influence of working fluid pressure, the device is equipped with a pressure transducer installed in the housing, designed for connection with tubing and having a through channel passing through its piston and plunger , as well as a hydromechanical lock for switching the fluid flow, installed in the specified channel and configured to open when pressure of the working fluid is created in the tubing and ensure the flow of working fluid from the tubing into the body cavity and influence the pistons of the punches and with the ability to close when the pressure in the tubing is removed working fluid.

In addition, the hydromechanical lock for switching the fluid flow may include two check valves spring-loaded in opposite directions, wherein the seat of the first valve is fixed to the piston of the pressure converter, and the seat of the second check valve is connected to the plunger of the pressure converter, and the said plunger is spring-loaded towards the piston of the pressure converter .

The punches are preferably placed in pairs with an angular displacement of the punch axes of each pair relative to each other and with a displacement of the punches along the axis of the device coinciding with the axis of the pressure transducer.

The disadvantages of these devices are:

complexity of the design as a whole;

preparation of the well is required, namely the production string for landing the anchor;

reperforation is not possible, since anchors are not placed at the site of perforation;

the anchor can be planted from five to ten times; after planting, the anchor crackers wear out and need to be replaced;

Due to the large length of the device, large bending moments arise, which requires large dimensions in the cross section of the device and there is a possibility of pistons jamming due to deformation of the piston holes.

The closest technical solution chosen by the applicant as a prototype is a hydromechanical hammer drill (utility model patent RU No. 2515669, IPC E21B 43/112 published on May 20, 2014, Bulletin No. 14), where:

The hammer drill is equipped with an additional hydraulic cylinder and a mechanism for transmitting force to the working unit, located in the housing below the working unit with the possibility of this lower hydraulic cylinder creating additional force on the working unit, directed upwards opposite to the force created by the hydraulic cylinder located above the working unit, while the force created by the lower hydraulic cylinder , is ensured by the action of liquid on it, supplied to it under pressure through the hydraulic system made in the hammer drill;

working tools are made in the form of punches;

the working unit contains at least one stop located diametrically with respect to the working tool, or diametrically to the vector of the sum of the forces of several working tools;

the working unit is equipped with hydraulic monitor attachments;

the hammer drill is equipped with an additional working unit with one or more working tools located oppositely under the first one, and hydraulic cylinders with mechanisms for transmitting force to the working units are placed in the housing opposite to each other above the upper working unit and below the lower working unit with the possibility of the hydraulic cylinders creating oppositely directed forces on the working units nodes, while the force created by the lower hydraulic cylinder (hydraulic cylinders) is provided by the action on it (them) of the liquid supplied to it (them) under pressure through the hydraulic system made in the hammer drill;

that the working tools of the working units are located one at another or at an angle to each other;

the hammer drill is equipped with at least one additional working unit with a mechanism for transmitting force to it, while the additional working unit is located sequentially under the first working unit, and the hydraulic cylinders are placed in the housing sequentially above each of the working units with the possibility of hydraulic cylinders creating individual forces on the working units , in this case, the force created by the hydraulic cylinders is provided by the action on them of the fluid supplied to them under pressure through the hydraulic system made in the hammer drill;

at least one working unit contains at least one stop located diametrically with respect to the working tool, or diametrically to the vector of the sum of the forces of several working tools;

the hammer drill is equipped with at least two additional working units located below the first working unit opposite it or opposite each other with the possibility of hydraulic cylinders creating individual forces on the working units, while the force created by the hydraulic cylinders is provided by the action on them of the fluid entering them under pressure through the hydraulic system made in the hammer drill;

The disadvantage of this device is:

punches in a single housing and the total length of the device reaches 5-6 m.

expensive production and transportation;

maintainability deteriorates (if one segment is rejected, only one segment can be replaced, but the entire product as a whole is rejected);

the body part is large, since when manufactured in one piece, the body experiences large bending loads from the reaction of the pistons;

It is impossible to produce punches for small production strings due to the low bending strength of the product body. (A large moment of resistance of the cross-section of the product is required, which leads to a decrease in the punching ability of the hammer and the impossibility of manufacturing small-diameter hammers).

with axial power pistons, in real conditions it is possible to punch only 2 holes (small cross sections and, as a consequence, low effort for punching holes);

difficulties with perforation phasing due to the symmetry of loads in a single body.

The objective of the claimed utility model is to create a reliable, cost-effective device for creating perforation channels in a well, reducing the time and cost of perforating a well and allowing:

operation of each piston separately, while the load from the punch in the center of the housing segment eliminates distortions and jamming of the piston;

connect two or more segments to each other, reducing the time of penetration of the formation as a whole;

attach body segments with the possibility of any perforation phasing (rotation relative to the well axis);

perforation of sections of the production string with large curvature;

perforation followed by hydraulic fracturing with a closely installed packer.

The technical result is reliability and an increase in the technological capability of well perforation as a whole.

The claimed technical result is achieved by the fact that a device for creating perforation channels in a well, containing a housing, punches, each punch of which has a piston with a flushing channel for supplying working fluid and is installed with the ability to move in the radial direction, relative to the axis of the well, under the influence of working fluid pressure , characterized in that the body consists of body segments connected to each other by flexible high-pressure rubber hoses, in each body segment there is a technological channel and a punch is placed, which has a piston with a flushing channel for supplying working fluid, under the piston and the flushing channel there are technological holes in the flexible high-pressure rubber hoses, with a check valve installed in the lower part of the lower segment of the housing, and the upper segment of the housing is designed to be installed on a tubing hanger.

What is new is that the device for creating perforation channels in a well, containing a housing consists of housing segments connected to each other by flexible high-pressure rubber hoses, in each housing segment there is a technological channel and a punch is placed, which has a piston with a flushing channel for supplying working fluid, Under the piston and the flushing channel, technological holes are made in flexible rubber high-pressure hoses, and a check valve is installed in the lower part of the lower segment of the housing, and the upper segment of the housing is designed to be installed on a tubing hanger.

In fig. Figure 1 shows a design diagram (longitudinal section) of a device for creating perforation channels in a well.

A device for creating perforation channels in a well (see Fig. 1) consists of housing segments 1, pistons 2, punches 3, flexible high-pressure rubber hoses 4, technological channels 5, flushing channels 6, technological holes of high-pressure rubber hoses 7, check valve 8.

The operating principle of the device for creating perforation channels in a well is as follows. A device for creating perforation channels in the well is lowered into the well (see Fig. 1) with a production string 9 on a tubing hanger 10. With the help of geophysics, punching devices are installed in the well to create perforation channels in the well in the required zone (interval) according to the work plan. When lowering the tubing hanger 10 with underground equipment into the well, through check valve 8, the well fluid fills the internal cavity of the device for creating perforation channels in the well and hanging the tubing 10. After reaching the required depth and installing the device for creating perforation channels in the well in the perforation zone, At the wellhead, process fluid is supplied under pressure into the internal cavity of the tubing 10. The pressure of the process fluid through the internal cavity of the tubing 10 enters the technological channel 5 of the device for creating perforation channels in the well, the first (upper) segment of the housing 1, and then through the flexible rubber high-pressure hose 4 to the technological channel 5 of the housing segment 1 (middle), creating pressure under the piston 2 devices for creating perforation channels in the well. Next, through the technological channel 5 of the housing segment (lower) 1 of the device for creating perforation channels in the well, the process fluid flows to the check valve 8 of the device for creating perforation channels in the well. Check valve 8 does not allow liquid to pass further. Pressure is created in the technological holes, flexible rubber high-pressure hoses 7, under the pistons 2 and the flushing channels 6 of the device for creating perforation channels in the well. When pressure arises under piston 2, piston 2 with a punch 3 comes out of the corresponding segment of the housing 1 and pierces the production string 9. After piercing the production string 9 with a punch 3, the process fluid under pressure from the process channel 5 enters the flushing channel 6 of the device and washes the cavity behind the production column, creating favorable conditions for formation fluid to enter the well.

In this case, the use of a device for creating perforation channels in a well, containing a housing which consists of housing segments interconnected by flexible high-pressure rubber hoses, in each segment of the housing there is a technological channel and a punch is placed, which has a piston with a flushing channel for supplying working fluid, under the piston and a flushing channel, technological holes are made in flexible rubber high-pressure hoses, and a check valve is installed in the lower part of the lower segment of the housing, and the upper segment of the housing is designed to be installed on a tubing hanger, which allows increasing the technological capabilities of perforating the well as a whole.

Claims (1)

A device for creating perforation channels in a well, containing a housing, punches, each punch of which has a piston with a flushing channel for supplying working fluid and is installed with the ability to move in the radial direction, relative to the axis of the well, under the influence of working fluid pressure, characterized in that the housing consists from segments of the body connected to each other by flexible rubber high-pressure hoses, in each segment of the body a technological channel is made and a punch is placed, which has a piston with a flushing channel for supplying working fluid; technological holes are made under the piston and the flushing channel in flexible rubber hoses of high pressure, and a check valve is installed in the lower part of the lower segment of the housing, and the upper segment of the housing is designed to be installed on a tubing hanger.

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