RU169176U1 - Reception device for a reusable unit for connecting and transmitting detonation of a cumulative case perforator - Google Patents

Abstract

The utility model relates to reusable sites for connecting cumulative rock drills. The task of creating a utility model: the ability to reuse individual elements of the receiving device. The technical result of the claimed technical solution is to enable reuse of individual elements of the receiving device. The solution to this problem was achieved in the receiver for a reusable connection node and detonation transmission of a cumulative case perforator containing a housing and a top part with an axial channel and a radial partition, in that it contains a sleeve that is replaceable, and the upper part and the partition are made on this sleeve, a conical truncated hole is made in the sleeve in front of the radial partition. A nut is installed on the thread on the external surface of the sleeve. A conical truncated hole can be made with a cone angle at the apex γ, which allows the cumulative stream to pass from the transmitter. The cone angle at the apex can be made in the range: γ = 16 ... 20 °, and the depth of the truncated conical hole δ = 10 ... 12 mm. The lower end of the sleeve can be made stepwise and a rubber ring washer is installed between it and the body. Two parallel turnkey flats can be made on the side surface of the sleeve. The upper part of the sleeve can be made in the form of a cylindrical part, the outer surface of which is rounded on both sides by spherical surfaces. A threaded section may be made on the lower part of the housing for connection with a downhole drill. On the outer surface of the housing can be performed

Description

The utility model relates to reusable connection nodes of cumulative perforators, specifically to receiving detonation transmission devices in downhole perforators.

Known node connection and transmission of detonation in perforators (RF patent for the invention No. 2386793, IPC EV 43/117, publ. 04/20/2010).

This assembly contains a frame, an adapter, a detonating cord, a booster, a booster sleeve, which is made in the form of a disk and a cylindrical part with an axial hole for accommodating the booster. The adapter has a through hole along the longitudinal axis with a cylindrical groove to accommodate the booster sleeve and detonating cord. The knock transmission unit is additionally equipped with a detonating cord, a booster, a booster bushing, a frame bushing. The boosters are mounted on detonating cords, the additional booster sleeve is made in the form of a disk and a cylindrical part with an axial hole to accommodate the additional booster and is placed in the inner hole of the frame sleeve from the side of the cylindrical groove at the end of the frame sleeve to accommodate the disk. A recess is made on the end side of the adapter, forming a cylindrical guide inside it, and a groove with an external diameter equal to the diameter of the recess is made on the end of the frame sleeve in contact with the end side of the adapter. At the same time, an annular thickening is made outside the middle part of the carcass sleeve, which is integral with the carcass sleeve.

Disadvantages: the complexity of the design and its one-time use.

Known node connection and transmission of detonation in perforators (RF patent for the invention No. 2307237, IPC EV 43/1185, publ. 09/27/2007).

This unit contains an adapter, a sleeve located in the inner hole of the adapter, a booster, a detonation cord, the end of which is connected to the booster. The booster is located in the sleeve. The sleeve is made in the form of a disk and a cylindrical part with an axial hole. On the outer side of the cylindrical part of the sleeve are annular beads. A partial longitudinal section is made at one end of the cylindrical part of the sleeve. The sleeve of the cumulative hammer drill detonation transmission device comprises a cylindrical part with an axial hole, a disk located on the outside of the cylindrical part. The sleeve is provided with annular beads located on the outer side of the cylindrical part of the sleeve, and a partial longitudinal section of the cylindrical part of the sleeve from one end. Disadvantage: one-time use of the design.

Known receiving device (RF patent for the invention No. 2519091, IPC ЕВВ 43/117, publ. 06/10/2014, prototype).

This technical solution contains transmitting and receiving parts interconnected by a detachable swivel. The transfer charge is located in the transmitting part and is connected to the detonating cord. A booster is placed in the receiving part and connected to the second detonating cord. In the transmitting part, a blind hole is made with a thread on the part of the hole in which the shock-absorbing sleeve is placed. Inside the shock-absorbing sleeve, a cumulative transfer charge is placed. The shock absorbing sleeve and the cumulative transfer charge are fixed inside the blind hole of the transmitting part by means of a sleeve connected by a threaded connection to the housing of the transmitting part.

Disadvantage: one-time use of the main parts and components of downhole perforation systems.

The task of creating a utility model: the ability to reuse individual elements of the receiving device.

The technical result of the claimed technical solution is to enable the reuse of individual elements of the receiving device.

The solution to this problem was achieved in a receiving device for a reusable connection and detonation transmission unit of a cumulative case perforator containing a body and an upper part with an axial channel and a radial partition, in that it contains a sleeve that is replaceable, and the upper part and the partition are made on this sleeve , a conical truncated hole is made in the sleeve in front of the radial partition. A nut is installed on the thread on the external surface of the sleeve.

A conical truncated hole can be made with a cone angle at the apex γ, providing the passage of the cumulative jet from the transmitting device. The angle of the cone at the top can be performed in the range:

γ = 16 ... 20 °, and the depth of the truncated conical hole δ ₁ = 10 ... 12 mm

The lower end of the sleeve can be made stepwise and a rubber ring washer is installed between it and the body. Two parallel turnkey flats can be made on the side surface of the sleeve. The upper part of the sleeve can be made in the form of a cylindrical part, the outer surface of which is rounded on both sides by spherical surfaces. A threaded section may be made on the lower part of the housing for connection with a downhole drill. On the outer surface of the housing, annular grooves may be provided for installing the sealing rings.

The essence of the utility model is illustrated in the drawings of FIG. 1 ... 3, where

 in FIG. 1 shows an assembly drawing,

 in FIG. 2 shows a drawing of the housing,

 in FIG. 3 shows a drawing of the upper part of the sleeve.

The receiving device for transmitting detonation in downhole perforators (Fig. 1 ... 3) contains a housing 1 and a sleeve 2 interconnected by a thread 3. The sleeve 2 is removable with the possibility of replacement after each actuation of the cumulative charge.

The housing 1 (Fig. 1 and 2) is cylindrical in shape and contains an internal axial hole 4 with a thread 3 for connection with the sleeve 2 and the axial channel 5. The connection of the housing 1 and the sleeve 2 is locked with a nut 6.

At the end 7 of the internal axial hole 4, two annular grooves 8 and 9 (Fig. 2) are made for installing the rubber ring washer 10 (Fig. 1).

On the outer surface 11 of the housing 1, annular grooves 12 are made for installing the sealing rings (the sealing rings in FIGS. 1 ... 3 are not shown). In addition, an annular shoulder 13 is made on the housing 1, the end of which 14 is in contact with the corresponding end face of the nut 6.

The sleeve 2 (Fig. 1) contains an axial channel 15, which is made stepped and contains a non-through axial hole 16, communicating through the transition section 17 in the form of a truncated cone with an opening of a relatively larger diameter 18.

The diameter of the hole 16 is determined from the condition

D ₂ = (1.5 ... 2.0) D _1.

The diameter of the channel 5 is determined from the ratio

D ₃ = D _2.

The sleeve 2 has an upper part 19, in which a conical truncated hole 20 is made, separated from the non-through axial hole 16 by a radial partition 21, which is integral with the sleeve 2.

Radial Partition Thickness:

δ ₂ = 2 ... 4 mm and depends mainly on the strength of the steel of which the sleeve is made using a standard detonator.

The depth of the conical truncated hole 20δ ₁ is determined from the condition of the passage of the cumulative stream through the center of the end surface of the booster installed later on, regardless of the angle of rotation of the transmitting and receiving parts (8 ° ... 10 °).

The depth of the conical truncated hole is

δ ₁ = 10 ... 12 mm.

The radial partition 21 and the rubber ring washer 10 are necessary to ensure complete tightness of the cavities of the internal axial channels 5 and 15 to protect the pyrotechnic devices installed in them from moisture.

The conical truncated hole 20 (Figs. 1 and 3) can be made with a cone angle at the apex γ, allowing the passage of the cumulative jet from the transmitting device.

The angle of the cone at the top can be performed in the range:

γ = 16 ... 20 °, and the depth of the truncated conical hole δ ₁ = 10 ... 12 mm

This will ensure the rotation of the receiving part relative to the transmitting (not shown) by an angle of 8 ° to 10 °, which is enough to pass the radius of the horizontal well.

In more detail, the construction of the upper part 19 is shown in FIG. 3. It contains a cylindrical part 22 and two spherical surfaces made of radius R1 and R2, while the surface of a larger radius carries the main load when the detonator is triggered.

On the side surface 23 of the sleeve 2 is made two flats 24 turnkey.

In the lower part of the housing, a connecting thread 25 is made for connecting the device to a perforator (Figs. 1 and 2).

Device operation

During operation (Fig. 1 ... 3), the proposed device for connecting thread 25 is screwed into the downhole drill. A transmitter with a detonator (not shown) is installed on top. When the detonator is triggered, a detonating pulse with a detonator (not shown). When the detonator is activated, the detonating pulse is transmitted from the detonator to a conical truncated hole 20 and burns through the radial partition 21.

After extracting the downhole perforator, the nut 6 is unscrewed, the sleeve 2 and the rubber ring washer 10 are replaced. The remaining parts are reused.

This operation can be done several times, usually 10..20 times. The application of the utility model allowed

 provide reusability of the use of almost all parts of the device,

 ensure the tightness of the internal cavity of the device,

 provide security.

Claims (11)

1. The receiving device for a reusable node for connecting and transmitting detonation of a cumulative casing punch, comprising a housing and an upper part with an axial channel and a radial partition, characterized in that it contains a sleeve that is replaceable, and the upper part and the partition is made on this sleeve, in the sleeve in front of the radial partition has a tapered truncated hole. 2. A receiving device for a reusable knot for connecting and transmitting detonation of a cumulative casing punch according to claim 1, characterized in that a nut is installed on the external surface of the sleeve on the thread. 3. A receiving device for a reusable node for connecting and transmitting detonation of a cumulative casing punch according to claim 1 or 2, characterized in that the conical truncated hole is made with a cone angle at apex γ, which allows the cumulative stream to pass from the transmitting device. 4. The receiving device for a reusable node for connecting and transmitting detonation of a cumulative casing punch according to claim 3, characterized in that the cone angle at the apex is made in the range: γ = 16 ... 20 °, and the depth of the truncated conical hole δ ₁ = 10 ... 12 mm 5. A receiving device for a reusable unit for connecting and transmitting detonation of a cumulative casing punch according to claim 1 or 2, characterized in that the lower end of the sleeve is stepped and a rubber ring washer is installed between it and the casing. 6. A receiving device for a reusable knot for connecting and transmitting detonation of a cumulative casing punch according to claim 1 or 2, characterized in that two turnkey parallel flats are made on the side surface of the sleeve. 7. A receiving device for a reusable unit for connecting and transmitting detonation of a cumulative casing punch according to claim 1 or 2, characterized in that the upper part of the sleeve is made in the form of a cylindrical part, the outer surface of which is rounded on both sides by spherical surfaces. 8. A receiving device for a reusable unit for connecting and transmitting detonation of a cumulative casing punch according to claim 1 or 2, characterized in that a threaded section is made on the lower part of the casing for connection with a downhole puncher. 9. A receiving device for a reusable unit for connecting and transmitting detonation of a cumulative casing punch according to claim 1 or 2, characterized in that annular grooves for installing the sealing rings are made on the outer surface of the housing.

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