RU2637349C1 - Complex method and device for performing perforation of wells and associated technological operations (versions) - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method includes lowering a tubing string including a hydromechanical perforator comprising a dispensing unit to control the flow of working fluid, a tool or combination of process equipment for carrying out required operations in the well; supplying the working fluid through a distributing unit of the perforator under the perforator to the process equipment or into bottom of the tubing string to annular space; performing appropriate process operations by means of process equipment; feeding working fluid through the distributing unit into the perforator; performing perforation; working fluid is fed through the distributing unit of the perforator to the process equipment or into bottom of the tubing string into the annular space; performing corresponding process operations after perforation with the help of process equipment.

EFFECT: reduced time for complete complex of operations associated with perforation of wells and associated operations: milling a wellbore, cementing the well, cleaning the walls of the production string by means of a scraper, washing the well bottom with a feather, namely, carrying out a complex of operations in one running-lifting operation.

38 cl, 1 dwg

Description

The proposed group of inventions relates to the field of drilling and operation of wells and can be used in the construction and repair of wells for various purposes, including wells designed for oil and gas production.

Known technologies, methods and devices for the secondary opening of reservoirs with hydromechanical perforation: RU 2249678 C2, IPC ⁷ ЕВВ 43/112, 04/10/2005, RU 2371569 С1, IPC Е21В 43/112, 10.27.2009, RU 2365743 C1, IPC Е21В 43/112, 08/27/2009, RU 2490434 С2, IPC ЕВВ 43/112, 08/20/2013, RU 60132 U1, IPC Е21В 43/114, 01/10/2007, RU 2043486 С1, IPC Е21В 43/114, 09/10/1995, RU 2070959 C1, IPC Е21В 43/11, 12/27/1996

Comprehensive methods and devices are also known that make it possible to carry out some additional technological operations simultaneously with perforation, for example, exposure to a jet pump (RU 92466 U1, IPC ЕВВ 43/25, 03/20/2010, RU 102676 U1, IPC Е21В 43/25, 10.03. 2011).

The use of complex methods and devices can achieve significant time savings by reducing the number of tripping operations required for well operations. Thanks to integrated technologies for conducting well operations, several types of technological operations in a well can be carried out at once for one round tripping of a tubing string.

In known arrangements, including a perforator, additional technological operations are performed on the perforator, and equipment for their implementation is located on the tubing string above the perforator.

At the same time, there are cases when it is economically justified to carry out technological operations together with perforation during one run of the tubing, requiring the supply of working fluid under the perforator (below the perforator).

For example, before perforation, as a rule, the wellbore is prepared for the trouble-free passage of technological equipment (perforator) to the perforation interval.

In accordance with the Rules for conducting repair work in wells (RD 153-39-023-97, issued: Federal Mining and Industrial Supervision of Russia on 05.22.1997, approved by: Ministry of Fuel and Energy of Russia on 08.18.1997), preparatory work for all types of bottom-hole treatment formation zone (SCR) is mandatory and includes in its composition the provision of necessary equipment and tools, as well as the preparation of the wellbore, bottom and filter for processing (paragraph 4.9.1.1.6. of these Rules).

Preparatory work, depending on the condition of the well, may include: development (milling) of the wellbore using a riber (milling cutter), checking the patency of the well using a template (well patterning). The technologies for patterning and milling a wellbore are known in open application, as well as, for example, from patents RU 2386783 C2, IPC Е21В 27/00, publication date 04/20/2010, RU 2274720 С2, IPC Е21В 7/08, Е21В 7/08 April 20, 2006

The riber (a body with cylindrical and conical sections, with teeth on their surface and a through hole for passage of flushing fluid, equipped with a downhole hydraulic motor for its rotation) is intended for milling damaged sections of casing strings during overhaul of wells; it is used, in particular, for restoration patency of deformed casing strings. The template (hollow module of a given shape) is used to check the patency of the production casing, as well as for its cleaning (flushing).

The use of a riber (or other milling tool) is associated with the need to supply working fluid to the downhole motor, which sets it in motion. Application of the template is carried out with the supply of working fluid to the bottom of the tubing and then into the annulus for removal of unwanted contaminants from the well through the annulus.

To prepare the well for subsequent technological operations carried out after perforation, it is also necessary to carry out a number of works, for example, eliminating technological damage and blockages that occur during perforation (burrs, shavings, residues of insulating materials, etc.) using a riber (milling cutter) flushing the bottom of the contaminants (normalization of the bottom) with a "pen", cleaning the wellbore with a scraper or other tool of a similar purpose, for example, for the subsequent planting of the packer.

A scraper (scraper) can be used to mechanically remove clay or a cement layer, stuck bullets, perforating burrs, rust, paraffin and other substances from the inner surface of the casing string. The “feather” (pointed flushing tube) is used to clean (flush) the barrel and / or bottom of the production casing. In some cases, the above devices can be used together to achieve the best result in normalizing the face, for example, a combination of scraper - template - pen is effective.

The technologies of well scraping and flushing with a pen are known in open application, as well as, for example, from patents RU 2459925 C1, IPC Е21В 21/00, 08/27/2012, US 8826986, IPC Е21В 37/02, 09.09.2014 .

The use of the scraper can be carried out with the supply of working fluid to the bottom of the tubing and then into the annulus for removal of undesirable contaminants eliminated by the scraper from the well through the annulus. The use of a pen, traditionally located at the very bottom of the tubing, is associated with the supply of flushing fluid to it, which also removes blockages washed out by the feather through the annulus.

Thus, the above operations (milling of the wellbore, patterning of the well, cleaning the walls of the production string using a scraper, flushing the bottom with a pen), carried out immediately before perforation or after perforation, for one reason or another require the supply of working fluid to the lower part of the tubing.

The objective of this group of inventions is to offer an effective integrated technology and the creation of an integrated device (layout) to reduce the number of tripping operations associated with perforation and associated perforation with technological operations, and, preferably, to perform previous perforation work, perforation, as well as work in well after perforation in one round trip.

An attempt to partially solve the specified problem can be traced in the application RU 2002102905 A, IPC ЕВВ 43/25, 10.10.2003, the technical solution contained in it, if properly disclosed, could be taken as a prototype. According to published information, this application proposes a "method for processing the bottom-hole zone of the formation, including lowering the perforator on the pipe string to the perforation interval, creating pressure in these pipes, cutting a slot by moving the perforator and washing the cavity through the perforation slot, and then returning the perforator to the transport position, characterized in that the subsequent processing of the bottom-hole zone of the formation is carried out by the working agent without raising the perforator by installing a shear circulation valve on it with m with additional washing windows. " At the same time, it is not clear from this wording what is meant by “post-treatment”, is this treatment carried out using any technological equipment, is it aimed at cleaning or restoring the patency of the well, or is it just a well-known wash operation caverns in the bottomhole formation zone (PZP) or treatment of the formation with caustic compounds (acid treatment).

No other close analogues of the proposed integrated technology were found in the prior art, which allows us to conclude that the proposed group of inventions meets the patentability conditions of “novelty” and “inventive step”.

The technical result achieved by the proposed group of inventions consists in a significant reduction in the time required to carry out a full range of works related to well perforation and related work (milling a wellbore, patterning a well, cleaning the walls of a production string using a scraper, flushing the bottom with a pen), namely carrying out a set of works in one round trip.

According to preferred embodiments of the invention in terms of the method, when performing perforation in combination with previous and subsequent operations in one round trip operation, the time savings for carrying out the entire full complex of works will be equal to two round trip operations (for wells in fields of Western Siberia this time is about 2 days).

According to additional variants of the proposed method, if for any technological reasons there is no need to perform previous or subsequent work in the well, and, accordingly, only one cycle of additional work is carried out together with perforation (either only preliminary or only subsequent work), saving time on the entire range of perforation and related works will be equal to one round trip (for wells in Western Siberian fields this time is It lasts about 1 day).

The specified technical result is achieved through the use of an integrated method of perforation and related work in the well for one tripping, including descent into the well on the tubing string of the arrangement, including a hydromechanical drill, containing a distribution unit for controlling the flow of the working fluid, and a tool or a combination of technological equipment to carry out the necessary work in the well (milling the walls of the well, cleaning the wellbore, checking the patency of the well, flushing with battlefield) (hereinafter - the technological equipment); the supply of working fluid through the distribution unit of the perforator under the perforator to the technological equipment or to the bottom of the tubing into the annulus; carrying out using technological equipment of relevant technological operations; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the puncher repeatedly to the technological equipment or to the bottom of the tubing into the annulus; carrying out with the help of technological equipment the corresponding technological operations after perforation.

The used technological equipment and the composition of technological operations in the method are selected depending on the state of a particular well, depending on this, various options for implementing the method are proposed.

According to the first option, a comprehensive method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string, including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a tool for milling the walls of the well; the supply of working fluid through the distribution node of the punch to the milling tool; preliminary milling of the wellbore; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the puncher repeatedly to the milling tool; milling of the wellbore after perforation.

The tool for milling the walls of the well can be made in the form of a riber (milling cutter) with a downhole motor, ensuring its operation.

According to the second option, a comprehensive method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a scraper; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; cleaning the wellbore with a scraper and flushing it with the removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the hammer drill repeatedly into the annulus; cleaning the wellbore with a scraper and flushing it with the removal of contaminants through the annulus to the surface.

At the same time, the layout in its lower part can be additionally equipped with a flushing pen, which allows for better flushing of the well, including in the method an additional operation to normalize (flush) the face.

According to the third option, a comprehensive method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string, including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a template; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; checking the patency of the wellbore with flushing through the annulus; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator again under the perforator into the annulus; checking the patency of the wellbore after perforation with washing through the annulus.

At the same time, the arrangement in its lower part can also be additionally equipped with a flushing pen, which allows for better flushing of the well, including in the method an additional operation to normalize (flush) the bottom.

According to the fourth option, a complex method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a pen; the supply of working fluid through the distribution node of the perforator on the pen; cleaning and washing the face with the removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the puncher repeatedly to the pen; cleaning and washing the face with the removal of contaminants through the annulus to the surface.

According to the fifth option, a complex method is proposed for conducting perforation and related technological operations in one round trip, including putting down a layout into a well on a tubing string, including a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a scraper and a template; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; conducting a cycle of work in the well on cleaning the wellbore and checking the patency of the well with flushing and removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator again under the perforator into the annulus; re-conducting a series of works on cleaning the wellbore, checking the patency of the well with flushing and removal of contaminants through the annulus to the surface.

In this embodiment of the method, the technological operations disclosed in the second and third embodiments of the method are combined. The layout in its lower part can be additionally equipped with a pen.

According to the sixth option, a comprehensive method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string, including a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a tool for milling the walls of the well and a template; the supply of working fluid through the distribution node of the perforator to the milling tool and further into the annulus; conducting a cycle of preliminary milling of the walls of the well in the well and checking the patency of the well with flushing through the annulus; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the puncher repeatedly to the milling tool and further into the annulus; re-conducting the cycle of milling the walls of the well and checking the patency of the well after perforation with washing through the annulus.

In this embodiment of the method, the technological operations disclosed in the first and third embodiments of the method are combined. The tool for milling the walls of the well can be made in the form of a riber (milling cutter) with a downhole motor, ensuring its operation.

In addition to the above preferred options, twelve additional embodiments of the method are also proposed, which, depending on the technological conditions, can be used in situations where for any reason there is no need to perform previous or subsequent work in the well, and, accordingly, only one is carried out with perforation a cycle of additional work (either only preliminary or only subsequent work).

According to the seventh option, a comprehensive method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string, including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a tool for milling the walls of the well; the supply of working fluid through the distribution node of the punch to the milling tool; preliminary milling of the wellbore; supply of working fluid through the distribution unit to the perforator; perforation. The tool for milling the walls of the well can be made in the form of a riber (milling cutter) with a downhole motor, ensuring its operation.

According to the eighth option, a complex method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into the well on a tubing string, including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a tool for milling the walls of the well; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the punch to the milling tool; milling of the wellbore after perforation. The tool for milling the walls of the well can be made in the form of a riber (milling cutter) with a downhole motor, ensuring its operation.

According to the ninth variant, a complex method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a scraper; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; cleaning the wellbore with a scraper and flushing it with the removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation. The layout in its lower part can be additionally equipped with a pen for better flushing the well.

According to the tenth embodiment, a complex method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a scraper; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator into the annulus; cleaning the wellbore with a scraper and flushing it with the removal of contaminants through the annulus to the surface. The layout in its lower part can be additionally equipped with a pen.

According to the eleventh embodiment, a comprehensive method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a template; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; checking the patency of the wellbore with flushing through the annulus; supply of working fluid through the distribution unit to the perforator; perforation. The layout in its lower part can be additionally equipped with a pen.

According to the twelfth embodiment, a comprehensive method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a template; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; checking the patency of the wellbore after perforation with washing through the annulus. The layout in its lower part can be additionally equipped with a pen.

According to the thirteenth embodiment, a comprehensive method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a pen; the supply of working fluid through the distribution node of the perforator on the pen; cleaning and washing the face with the removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation.

According to the fourteenth option, a complex method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a pen; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the puncher repeatedly to the pen; cleaning and washing the face with the removal of contaminants through the annulus to the surface.

According to the fifteenth embodiment, an integrated method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a scraper and a template; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; conducting a cycle of work in the well on cleaning the wellbore and checking the patency of the well with flushing and removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation. Moreover, the layout in its lower part can be additionally equipped with a pen.

According to the sixteenth embodiment, a complex method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string including a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a scraper and a template; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator again under the perforator into the annulus; conducting a cycle of work on cleaning the wellbore, checking the patency of the well with flushing and removal of contaminants through the annulus to the surface. Moreover, the layout in its lower part can be additionally equipped with a pen.

According to the seventeenth option, a comprehensive method is proposed for conducting perforation and related technological operations in one round trip, including launching a layout into a well on a tubing string, including a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a tool for milling the borehole walls and a template; the supply of working fluid through the distribution node of the perforator to the milling tool and further into the annulus; conducting a cycle of preliminary milling of the walls of the well in the well and checking the patency of the well with flushing through the annulus; supply of working fluid through the distribution unit to the perforator; perforation. In this case, the tool for milling the walls of the well can be made in the form of a riber (milling cutter) with a downhole motor, ensuring its operation.

According to the eighteenth option, a complex method is proposed for conducting perforation and related technological operations in one round-trip, including putting down into the well on a tubing string an assembly including a hydro-mechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a tool for milling the borehole walls and a template; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator to the milling tool and further into the annulus; conducting a cycle of work on milling the walls of the well and checking the patency of the well after perforation with washing through the annulus. The tool for milling the walls of the well can be made in the form of a riber (milling cutter) with a downhole motor, ensuring its operation.

To implement the method, device options are provided - layouts for perforation in a well and related technological operations.

According to the first embodiment, the arrangement for perforating and related technological operations according to the invention includes a hydromechanical hammer drill mounted on a tubing string and at least one of the following tools: a tool for milling the walls of the well and / or a template; wherein the perforator contains a distribution unit for controlling the flow of the working fluid, providing the possibility of an adjustable supply of fluid to the perforator or under the perforator to the tool and / or into the annulus located below the perforator.

The design of the distributor assembly of the perforator may include hydrochannels made in the perforator body and bushings with saddles for a ball mounted sequentially in the upper part of the perforator body along its axis with the possibility of moving and opening and / or overlapping these hydrochannels.

The tool for milling the walls of the well can be made in the form of a riber (milling cutter) with a downhole motor.

According to a second embodiment, the arrangement for perforating and related technological operations according to the invention includes a hydro-mechanical perforator mounted on a tubing string and at least one of the following tools: a scraper and / or template, and / or a feather, wherein the perforator a distribution unit for controlling the flow of the working fluid, providing the possibility of a regulated supply of fluid to the punch or under the punch to the tool located under the punch and / or in the hole wide space.

The design of the distribution assembly of the perforator, as in the first embodiment of the device, may include hydraulic channels made in the perforator body, and bushings with saddles for the ball mounted sequentially in the upper part of the perforator body along its axis with the possibility of moving and opening and / or overlapping these hydro channels .

Technological equipment in the composition of the proposed layouts is selected depending on the condition of a particular well and preferably should be an optimal combination of tools for specific well conditions.

The figure 1 presents the proposed device in one of the possible options for its execution.

The arrangement for complex perforation of wells includes a hydromechanical perforator 1 and a tool 2 for milling the walls of the well located below the perforator 1, the perforator 1 containing a distribution unit 3 for controlling the flow of working fluid, which allows the adjustable supply of fluid to the milling tool 2 or to the perforator 1. Distribution the node 3 includes hydrochannels 4, made in the housing 5 of the perforator 1, and bushings 6 with saddles 7 under the ball, mounted sequentially in the upper part of the housing 5 perforator 1 along its axis, with the ability to move and open and / or overlap the indicated hydraulic channels 4. Tool 2 for milling the walls of the well is made in the form of a riber (milling cutter) with a downhole motor.

The proposed method is carried out during operation of the proposed device according to one of the preferred options (namely, according to the first embodiment of the proposed method) as follows.

An assembly including a hydromechanical perforator 1 containing a distribution unit 3 for controlling the flow of working fluid, and a tool 2 for milling the walls of the well (for example, a riber (milling cutter) with a downhole motor) are lowered into the well at the tubing string. The working fluid is supplied through the distribution unit 3 of the perforator 1 to the milling tool 2, the borehole is milled, then, by dropping the ball, the sleeve 6 of the distribution unit 3 is moved down, opening the channel 4 for supplying the working fluid to the perforator, the working fluid is supplied through the distribution unit to the perforator 1 , perforation is carried out according to the technology used, then, by dropping the second ball, the second sleeve 6 of the distribution unit 3 is moved down, opening the channel 4 for supplying the working fluid the bones to the milling tool 2, feed the working fluid through the distribution unit 3 of the perforator 1 again to the milling tool 2 and re-milling the perforation interval or wellbore after perforation.

The implementation of the method according to 2-6 variants is carried out in a similar way, with a difference only in the form of the used technological equipment and in the application in the method of technological operations corresponding to the selected equipment before or after perforation. The sequence of operations does not change, using the distribution unit 3 of the punch 1, the working fluid is initially supplied under the punch to the technological equipment or into the annulus for direct washing of the well, then to the punch to perform punching, and then again under the punch to the technological equipment or into the annulus for direct flushing of the well.

In the case of the implementation of the method according to 7-18 options, part of the operations (in the direction and supply of the working fluid to the process equipment (or in the annulus) and on the use of the corresponding process equipment before or after perforation) are excluded.

At the end of the whole complex of works, the entire layout is raised to the surface.

Claims (38)

1. An integrated method of conducting perforation and related technological operations in a single descent, including descent into the well on a tubing string of an assembly comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a tool for milling the walls of the well; the supply of working fluid through the distribution node of the punch to the milling tool; preliminary milling of the wellbore; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the puncher repeatedly to the milling tool; milling of the wellbore after perforation. 2. The integrated method according to p. 1, characterized in that the tool for milling the walls of the well is a riber with a downhole motor, ensuring its operation. 3. An integrated method of perforation and related technological operations in one well during one descent, including descent into the well on a tubing string of an assembly comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a scraper; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; cleaning the wellbore with a scraper and flushing it with the removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the hammer drill repeatedly into the annulus; cleaning the wellbore with a scraper and flushing it with the removal of contaminants through the annulus to the surface. 4. The integrated method according to p. 3, characterized in that the layout in its lower part is additionally equipped with a pen. 5. An integrated method of perforation and related technological operations in one well during one descent, including descent into the well on a tubing string of an assembly comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a template; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; checking the patency of the wellbore with flushing through the annulus; supply of working fluid through the distribution unit to the perforator; perforation: the supply of working fluid through the distribution node of the perforator repeatedly under the perforator into the annulus; checking the patency of the wellbore after perforation with washing through the annulus. 6. The integrated method according to p. 5, characterized in that the layout in its lower part is additionally equipped with a pen. 7. An integrated method of conducting perforation and related technological operations in one well during one descent, including descent into the well on a tubing string of an arrangement comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a pen; the supply of working fluid through the distribution node of the perforator on the pen; cleaning and washing the face with the removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the puncher repeatedly to the pen; cleaning and washing the face with the removal of contaminants through the annulus to the surface. 8. An integrated method of perforation and related technological operations in one well for one descent, including descent into the well on a tubing string of an assembly comprising a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a scraper and a template; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; conducting a cycle of work in the well on cleaning the wellbore and checking the patency of the well with flushing and removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator again under the perforator into the annulus; re-conducting a series of works on cleaning the wellbore, checking the patency of the well with flushing and removal of contaminants through the annulus to the surface. 9. The integrated method according to p. 8, characterized in that the layout in its lower part is additionally equipped with a pen. 10. An integrated method of conducting perforation and related technological operations in a single descent, including descent into a well on a string of tubing assembly comprising a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a tool for milling the walls of the well and a template ; the supply of working fluid through the distribution node of the punch to the milling tool and then into the annulus; conducting a cycle of preliminary milling of the walls of the well in the well and checking the patency of the well with flushing through the annulus; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the puncher repeatedly to the milling tool and further into the annulus; re-conducting the cycle of milling the walls of the well and checking the patency of the well after perforation with washing through the annulus. 11. The integrated method according to p. 10, characterized in that the tool for milling the walls of the well is a riber with a downhole motor that ensures its operation. 12. An integrated method of conducting perforation and related technological operations in a single descent, including descent into the well on a tubing string of an assembly comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a tool for milling the walls of the well; the supply of working fluid through the distribution node of the punch to the milling tool; preliminary milling of the wellbore; supply of working fluid through the distribution unit to the perforator; perforation. 13. The integrated method according to p. 12, characterized in that the tool for milling the walls of the well is a riber with a downhole motor, ensuring its operation. 14. An integrated method of conducting perforation and related technological operations in a single descent, including descent into a well on a tubing string of an assembly comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a tool for milling the walls of the well; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the punch to the milling tool; milling of the wellbore after perforation. 15. The integrated method according to p. 14, characterized in that the tool for milling the walls of the well is a riber with a downhole motor, ensuring its operation. 16. An integrated method of conducting perforation and related technological operations in one well during one descent, including descent into the well on a string of tubing assembly comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a scraper; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; cleaning the wellbore with a scraper and flushing it with the removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation. 17. The integrated method according to p. 16, characterized in that the layout in its lower part is additionally equipped with a pen. 18. An integrated method of conducting perforation and related technological operations in one well during one descent, including descent into the well on a tubing string of an assembly comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid and a scraper; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator into the annulus; cleaning the wellbore with a scraper and flushing it with the removal of contaminants through the annulus to the surface. 19. The integrated method according to p. 18, characterized in that the layout in its lower part is additionally equipped with a pen. 20. An integrated method of conducting perforation and related technological operations in a single descent, including descent into the well on a tubing string of an arrangement comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a template; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; checking the patency of the wellbore with flushing through the annulus; supply of working fluid through the distribution unit to the perforator; perforation. 21. The integrated method according to p. 20, characterized in that the layout in its lower part is additionally equipped with a pen. 22. An integrated method of conducting perforation and related technological operations in one well during one descent, including descent into the well on a tubing string of an assembly comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a template; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; checking the patency of the wellbore after perforation with washing through the annulus. 23. The integrated method according to p. 22, characterized in that the layout in its lower part is additionally equipped with a pen. 24. An integrated method of conducting perforation and related technological operations in a single descent, including descent into a well on a tubing string of an arrangement including a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a pen; the supply of working fluid through the distribution node of the perforator on the pen; cleaning and washing the face with the removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation. 25. An integrated method of conducting perforation and related technological operations in a single descent, including descent into a well on a tubing string of an arrangement comprising a hydromechanical perforator containing a distribution unit for controlling the flow of working fluid, and a pen; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator on the pen; cleaning and washing the face with the removal of contaminants through the annulus to the surface. 26. An integrated method of perforation and related technological operations in one well for one descent, including descent into the well on a tubing string of an assembly comprising a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a scraper and a template; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; conducting a cycle of work in the well on cleaning the wellbore and checking the patency of the well with flushing and removal of contaminants through the annulus to the surface; supply of working fluid through the distribution unit to the perforator; perforation. 27. The integrated method according to p. 26, characterized in that the layout in its lower part is additionally equipped with a pen. 28. An integrated method of conducting perforation and related technological operations in one well during one descent, including descent into the well on a tubing string of an assembly including a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a scraper and a template; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the perforator under the perforator into the annulus; conducting a cycle of work on cleaning the wellbore, checking the patency of the well with flushing and removal of contaminants through the annulus to the surface. 29. The integrated method according to p. 28, characterized in that the layout in its lower part is additionally equipped with a pen. 30. An integrated method of perforation and related technological operations in one well for one round trip, including the descent into the well on a tubing string of an assembly including a hydromechanical perforator equipped with a distribution unit for controlling the flow of working fluid, a tool for milling the walls of the well and a template ; the supply of working fluid through the distribution node of the punch to the milling tool and then into the annulus; conducting a cycle of preliminary milling of the walls of the well in the well and checking the patency of the well with flushing through the annulus; supply of working fluid through the distribution unit to the perforator; perforation. 31. The integrated method according to p. 30, characterized in that the tool for milling the walls of the well is a riber with a downhole motor that ensures its operation. 32. An integrated method of perforating and related technological operations in one run, including lowering into a well on a tubing string of an assembly including a hydromechanical drill equipped with a distribution unit for controlling the flow of working fluid, a tool for milling the walls of the well and a template ; supply of working fluid through the distribution unit to the perforator; perforation; the supply of working fluid through the distribution node of the punch to the milling tool and then into the annulus; conducting a cycle of work on milling the walls of the well and checking the patency of the well after perforation with washing through the annulus. 33. The integrated method according to p. 32, characterized in that the tool for milling the walls of the well is a riber with a downhole motor that ensures its operation. 34. An arrangement for conducting perforation in a well and related technological operations, including a hydro-mechanical perforator mounted on a tubing string and at least one of the following tools: a tool for milling the walls of the well and / or a template, the perforator containing a distribution unit for controlling working fluid flow, providing the possibility of controlled fluid supply to the perforator or under the perforator to the tool located under the perforator and / or in the hole wide space. 35. The arrangement according to p. 34, characterized in that the distribution unit includes hydrochannels made in the perforator body and bushings with seats for a ball mounted sequentially in the upper part of the perforator body along its axis with the possibility of moving and opening and / or overlapping said hydrochannels . 36. The arrangement according to p. 34 or 35, characterized in that the tool for milling the walls of the well is made in the form of a riber with a downhole motor. 37. An arrangement for conducting perforation in a well and related technological operations, including a hydro-mechanical perforator mounted on a tubing string and at least one of the following tools: a scraper and / or template, and / or a feather, the perforator containing a distribution unit for control of the flow of the working fluid, providing the possibility of an adjustable supply of fluid to the perforator or under the perforator to the tool located under the perforator and / or into the annulus. 38. The arrangement according to p. 37, characterized in that the distribution unit includes hydrochannels made in the perforator body and bushings with seats for a ball mounted sequentially in the upper part of the perforator body along its axis with the possibility of moving and opening and / or overlapping said hydrochannels .

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