RU53428U1 - CUMULATORY CHARGE OF PUNCHES - Google Patents

Abstract

The utility model relates to the field of geophysics, in particular to perforating and blasting operations in wells and may be part of cumulative perforators. The technical result is expressed in obtaining an increased diameter of the hole when the cumulative charge of the hammer and the stability of its operation. The essence of the cumulative charge of the perforator is expressed in that it contains an axisymmetric explosive block in a body with an open cavity in the form of a spherical segment in the body of the block, a cladding made of an inert material adjacent to the cavity surface, and an intermediate detonator in the end of the case, opposite the cladding, this cladding is made in the form of a sphere conjugated with a truncated cone, and the conical part of the cladding is at the base. In one embodiment of the cumulative charge, a spherical or cylindrical element is mounted on the inside of the sphere along an axis directed towards the intermediate detonator.

Description

The utility model relates to the field of geophysics, in particular to perforating and blasting operations in wells and can be part of cumulative perforators.

Known cumulative charges of a perforator containing a housing filled with an explosive with a cumulative recess with a lining, an intermediate detonator, (see, for example, descriptions of inventions to patents RU 2193152 7 F 42 B 1/028, published 2002.11.20; RU 2239150 7 F 42 B 1/028, published 2004.10.27; RU 2250359 7 E 21 B 43/117, F 42 B 1/028, published 2005.4.20). The disadvantage of these cumulative charges is the lack of stability and insufficient diameter of the hole obtained when the charge is triggered.

The closest analogue is the charge of a perforator (see, for example, the description of the invention to patent RU 2250359 7 E 21 V 43/117, F 42 B 1/028, published 2005.04.20), containing an axisymmetric explosive bomb in an open cavity in the form a spherical segment in the body of the checker, a cladding adjacent to the surface of the cavity made of an inert material, and a detonator at the end opposite the cladding,

The disadvantage of the closest analogue is the lack of stability and insufficient diameter of the hole obtained when the charge is triggered.

The technical result is expressed in obtaining an increased diameter of the hole when the cumulative charge of the hammer and the stability of its operation.

The essence of the cumulative charge of the perforator is expressed in that it contains an axisymmetric explosive block in a body with an open cavity in the form of a spherical segment in the body of the block, a cladding made of an inert material adjacent to the cavity surface, and an intermediate detonator in the end of the case, opposite the cladding, this cladding is made in the form of a sphere conjugated with a truncated cone, and the conical part of the cladding is at the base. In one embodiment of the cumulative charge, a spherical or cylindrical element is mounted on the inside of the sphere along an axis directed towards the intermediate detonator.

The essence of the cumulative charge of the perforator is illustrated by drawings, where

figure 1 shows a view in longitudinal section;

figure 2 shows a view in longitudinal section with a cylindrical element;

figure 3 shows a view in longitudinal section with a spherical element.

The cumulative charge of the perforator contains an axisymmetric checker 1 of the explosive in the body 2 with an open cavity in the form of a spherical segment in the body of the checker, a cladding 3 adjacent to the surface of the cavity made of an inert material, and an intermediate detonator 4 at the end of the case 2 opposite the cladding 3. Cladding 3 made in the form of a sphere conjugated with a truncated cone, and the conical part of the cladding 3 is located at the base of the housing 2. On the inner side of the sphere of the cladding 2 along an axis directed towards the intermediate child Ator 4 is mounted a spherical or cylindrical member 5. The truncated cone part 3 is facing the opening angle in the range of 95 to 105 degrees. The lining 3 can be made of metal from a plastic material such as copper. Spherical or cylindrical elements 5 can be made of metal from steel.

The cumulative charge of the punch is as follows.

In the explosion of an axisymmetric checker 1 from the intermediate detonator 4, a high-speed compression of the cladding 3 occurs. The detonation wave loads the cladding 3 from the top so that the top of the sphere of the cladding 3 is pressed into the inside of the central part and forms a jet that has a maximum speed of about 4000 m / s. When the detonation wave passes along the generatrix of the cladding 3 downward, the lower part of the cladding 3 collapses together with the conical part of the cladding 3. A multilayer jet structure is created. The speed of the jet is about 2000-2500 m / s. The multilayer jet has a diameter significantly larger than the jet formed by the classic conical lining. This gives a significant increase in the inlet during perforation, with a diameter of at least 24-26 mm. with a depth of 150-210 mm. When using a spherical or cylindrical element 5, which is inside the jet during the formation of the central part of the jet and if this element 5 is not plastic, the central jet retains the diameter of the installed element 5 and when the side surface of the cladding 3 collapses, the diameter of the central part of the jet is much larger than when normal spherical cladding. To obtain a large hole, a cumulative jet during perforation is used for facing

plastic materials, for example, copper, which are stretched under the influence of a detonation wave, forming the central part in which element 5 is located. Installing element 5 on the spherical lining 3 inside the axisymmetric checker 1 allows you to synchronize the process, since element 5 moves together with the jet.

Claims (3)

1. The cumulative charge of the perforator, containing an axisymmetric explosive block in the body with an open cavity in the form of a spherical segment in the body of the block, a cladding adjacent to the surface of the cavity made of an inert material, and an intermediate detonator in the end of the case, opposite the cladding, characterized in that the cladding made in the form of a sphere conjugated with a truncated cone, and the conical part of the cladding is at the base. 2. The cumulative charge of the perforator according to claim 1, characterized in that the lining is made of metal from a plastic material such as copper. 3. The cumulative charge of the perforator according to any one of claims 1 and 2, characterized in that a spherical or cylindrical element is installed on the inner side of the shell sphere along an axis directed towards the intermediate detonator.