RU174197U1 - MULTIFUNCTIONAL BOOSTER BUSHING FOR PERFORATION SYSTEMS - Google Patents

Abstract

The utility model relates to perforating explosive equipment, specifically, receiving and transmitting charges (boosters) and their fixation, designed to ensure detonation in cumulative perforators. The tasks of creating a utility model are: simplifying the assembly of a unit containing a booster, ensuring the reliability of mounting a booster, the repeated use of a downhole drill, and expanding the arsenal of tools for a specific purpose, i.e. downhole perforators. Achieved technical results: simplification of the assembly of the booster, ensuring the reliability of fastening of the booster, the repeated use of a downhole perforator and the expansion of the arsenal of means for a specific purpose, i.e. downhole perforators. The solution of these problems was achieved in a multifunctional booster sleeve for perforation systems, containing a cylindrical part with an axial hole for installing a booster, having a collet clamp on one side having an external conical part, and on the other a cover with a central hole and a shoulder, a nut with an internal conical part screwed onto the threaded section and the cover with a stop, in that a second collar is made in the axial hole of the cylindrical part of the sleeve to stop the booster, and on the side opposite the nut, on In the cylindrical section, a second threaded section is made, onto which the cover is screwed. The cylindrical part, collet clamp and nut can be made of non-metallic material. The cylindrical part, collet clamp and nut can be made of polyamide material. The cylindrical part, collet clamp and nut can be made of plastic. The cylindrical part and collet clamp can be made of polyamide material, and the nut is made of plastic. The collet clip may contain elastic petals. Elastic petals may have annular slots. 1 n and 6 z.p. f-ly, 9 ill.

Description

The utility model relates to perforating explosive equipment, specifically, booster position fixation units designed to amplify and transmit detonation from one body to another in cumulative perforators.

Triggering with a low detonation pulse can lead to a malfunction of the detonation cord or to an unsteady mode (low-speed combustion) or to a complete stop of the detonation of the detonation cord, which excludes a high-quality opening of the intended formation or leads to other emergency consequences.

Low-speed combustion can lead to a high-explosive effect, which leads to the destruction of the punch and jamming.

Trouble-free operation must be ensured in all cases.

A well-known booster from the Internet site: http://www.bvt-s.ru/production/8/62/.

Known node fixing the position of the booster in the device for transmitting detonation according to the patent of the Russian Federation for utility model No. 94280, IPC ЕВВ 47/117, publ. 05/20/2010, the prototype.

The disadvantages of the prototype:

The booster can move in the axial direction and the detonation cord can move away from the end of the booster, which can lead to a decrease in the reliability of operation of the perforation system. This disadvantage is due to the fact that the detonation cord is fixed at a considerable distance from the end of the booster, which does not have a fixation from axial movement towards the detonation cord. Centering of the booster is not provided. Insufficient working surface of the collet due to the large angle of the inner cone of the nut and the complicated design of the collet clamp.

The tasks of creating a utility model: simplifying the assembly of a node containing a booster, ensuring the reliability of mounting a booster, expanding the arsenal of means for a specific purpose, i.e. booster bushings for perforation systems.

Achieved technical results: simplification of assembly of the booster, ensuring the reliability of mounting the booster and expanding the arsenal of means for a specific purpose, i.e. booster bushings for perforation systems.

The solution of these problems was achieved in a multifunctional booster sleeve for perforation systems, containing a cylindrical part with an axial hole for installing a booster, having a collet clamp on one side having an external conical part, and on the other a cover with a central hole and a shoulder, a nut with an internal conical part screwed onto the threaded section and the cover with a stop, in that a second collar is made in the axial hole of the cylindrical part of the sleeve to stop the booster, and on the side opposite the nut, on In the cylindrical section, a second threaded section is made, onto which the cover is screwed.

The cylindrical part, collet clamp and nut can be made of non-metallic material. The cylindrical part, collet clamp and nut can be made of polyamide material. The cylindrical part, collet clamp and nut can be made of plastic. The cylindrical part and collet clamp can be made of polyamide material, and the nut is made of plastic. The collet clip may contain elastic petals. Elastic petals may have annular slots.

The essence of the utility model is illustrated in the drawings (Fig. 1-9), where:

- in FIG. 1 shows a multifunctional booster sleeve as part of a downhole drill,

- in FIG. 2 shows a multifunction booster sleeve for complete perforation systems,

- in FIG. 3 shows the housing of the multifunctional booster sleeve,

- in FIG. 4 is a view A of FIG. 3

= in FIG. 5 is a view B of FIG. 3

- in FIG. 6 shows a section CC in FIG. 3

- in FIG. 7 is a view D in FIG. 3

- in FIG. 8 is a nut

- in FIG. 9 shows the cover.

The multi-function booster sleeve (Fig. 1-9) is installed in one of the perforator bodies 1 and a booster 2 and detonation cord 3 are installed inside it. The basis of the multi-function booster sleeve is a cylindrical part 4 with an axial hole 5 and a collet clamp 6 (Fig. 1).

The diameter of the axial hole 5 is equal to the diameter of the booster 2, this eliminates its radial displacement.

A threaded section 7 and a second threaded section 8 are made at the ends of the cylindrical part 4. A nut 9 is installed on the threaded section 7, and a cover 10 with a central hole 11 and a collar 12 is screwed onto the second threaded section 8. In the axial hole 5 from the collet side 6 second flange 13. The purpose of the flanges 12 and 13: to prevent axial movement of the booster 2.

The cylindrical part 4 and the nut 9 can be made of non-metallic material. The cylindrical part of the sleeve 4 and the nut 9 can be made of polyamide material. The cylindrical part of the sleeve 4 and the nut 9 can be made of plastic. The cylindrical part of the sleeve 4 may be made of polyamide material, and the nut 9 may be made of plastic. All other parts of the proposed multifunctional booster sleeve of non-metallic material are possible.

In FIG. 3-7 show a more detailed construction of the collet clamp 6. The collet clamp 6 contains elastic tabs 14 with longitudinal grooves 15 between them. The elastic petals 14 have a working surface 16. On the petals 14 can be made annular grooves 17 (Fig. 7). The annular grooves 17 are made through, have a triangular shape and are designed to increase the elasticity of the petals 14.

On the housing 4 there are flats 18 turnkey (Fig. 6).

The nut 9 (Fig. 8) has an internal thread 19 and a conical hole 20 with a taper angle ϕ to create a radial force during the operation of the collet clamp.

A collet clamp 6 with elastic tabs 14 is placed inside the conical hole 20 and when screwing the nut 9, the elastic tabs 14 compress the detonation cord 3 (Fig. 1).

Optimum taper angle:

ϕ = 7-10 °.

In this case, the working surface 16 of the collet clamp 6 (Fig. 3 and 4) will be large enough to prevent the movement of the detonation cord 3 relative to the end of the detonator.

The cover 10 (Fig. 9) has an internal thread 21 and through holes 22 made parallel to the axis of the device and are designed to install the key during assembly and disassembly.

ASSEMBLY OF MULTIFUNCTIONAL BOOSTER BUSHING FOR PUNCHING SYSTEMS

First, a booster 2 and detonation cord 3 (Fig. 1) are installed in the axial hole 5 of the cylindrical part 4 and a collet clamp 6 (Fig. 2) is assembled by screwing the nut 9 onto the threaded section 7. Then, the cover 10 is screwed onto the second threaded section 8.

Install the multifunctional booster sleeve in the body of the perforator 1 (Fig. 1). Collect the perforation system for its descent into the well.

WORK OF THE MULTIFUNCTIONAL BOOSTER BUSH FOR PUNCHING SYSTEMS

A downhole drill, equipped with the proposed multifunctional sleeve, is lowered into the well at the tubing - tubing or geophysical cable. When the initiating head is triggered, the initiating device (not shown) is triggered, initiating detonation along the explosive chain of the perforator. The detonation wave through the Central hole 11 is transmitted to the booster 2, to the detonation cord 3 (Fig. 1) and then to the cumulative charges (not shown) or to another housing of the perforation system.

To reuse the adapter of the downhole perforator, disassemble it and take out the collet holder, unscrew the nut 9, clean the internal cavity and install a new booster 2 and detonation cord 3 (Fig. 1) and screw the cover 10. Re-assemble the downhole perforator by re-installing it Assembled multifunction booster sleeve.

Multiple use of the adapter of the downhole drill and its main parts is possible. The proposed multifunctional sleeve can be used in all perforation systems, sub, tandems, etc.

Application of the utility model allowed:

1. Significantly increase the reliability of operation of the knock transmission device due to the fact that:

- completely excluded the possibility of moving the booster in the axial direction due to the use of two shoulders,

- center the booster and eliminate its radial displacement,

- increase the working surface of the collet.

2. To ensure the unification of the multi-function booster bush for various perforation systems.

3. To ensure the multiple use of a downhole drill.

4. Simplify the design and facilitate assembly.

5. Ensure the safety of working with boosters.

6. To expand the arsenal of funds for a certain purpose, ie receiving and transmitting devices with boosters for downhole drills.

Claims (7)

1. A multifunctional booster sleeve for perforation systems, comprising a cylindrical part with an axial hole for installing the booster, having a collet clamp on one side having an external conical part, and on the other a cover with a central hole and a collar, a nut with an internal conical part screwed onto a threaded section, characterized in that a second flange is made in the axial hole of the cylindrical part of the sleeve to support the booster, and on the side opposite the nut, a second The screwed part on which the cover is screwed. 2. A multifunctional booster sleeve for perforation systems according to claim 1, characterized in that the cylindrical part, collet clamp and nut are made of non-metallic material. 3. The multifunctional booster sleeve for perforation systems according to claim 2, characterized in that the cylindrical part, collet clamp and nut are made of polyamide material. 4. The multifunctional booster sleeve for perforation systems according to claim 2, characterized in that the cylindrical part, collet clamp and nut are made of plastic. 5. The multifunctional booster sleeve for perforating systems according to claim 2, characterized in that the cylindrical part and the collet clamp are made of polyamide material, and the nut is made of plastic. 6. A multifunctional booster sleeve for perforating systems according to claim 2, characterized in that the collet clamp contains elastic petals. 7. The multifunctional booster sleeve for perforating systems according to claim 6, characterized in that the elastic petals have annular slots.

Images