RU2450239C1 - Destructing agent of cassette ammunition - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: destructing element comprises a vessel, an explosive, a detonating fuse and localisers of vessel breaking up into fragments. The vessel comprises a cylindrical and a bottom parts. Localisers of vessel breaking up into fragments are made in the form of circular bores on the outer surface of the cylindrical part of the vessel and on the outer surface of the bottom part. There are dead holes arranged in vessel links formed by circular bores.

EFFECT: production of fragments of approximately one optimal weight.

14 cl, 7 dwg

Description

The invention relates to cluster munitions, the shell of which contains many individual damaging elements, mainly fragmentation-cumulative effects.

Known damaging element of cluster munition, containing a housing consisting of a cylindrical and bottom parts, as well as localizers crushing the body into fragments made in the form of annular grooves on the outer surface of the cylindrical part, while the grooves have a conical shape (RF patent No. 2137087, IPC: F42B 12/58).

The disadvantages of this striking element are the presence of a “dead zone” of expansion of fragments in the gap between the fragmentation fields of the lower cylindrical and bottom parts, which leads to a decrease in the reduced area of damage, a small number of fragmentation locators, which leads to heterogeneity of the fragmentation field and an insufficient number of “killed” fragments, t .e. having the required energy to defeat.

Known damaging element of cluster munition, comprising a housing comprising a cylindrical and bottom parts, an explosive, a fuse and localizers crushing the body into fragments made in the form of annular grooves on the outer surface of the cylindrical part of the housing, while the annular grooves are additionally made on the outer surface of the bottom, which has a lively shape and a length greater than the length of the cylindrical part, while the annular grooves are made with a depth of 35-60% of the thickness of the body (RF patent No. 2277692, Application 2004124601/02 from 12.08.2004, IPC: F42B 12/66 - prototype).

This striking element of cluster munitions works as follows.

The meeting of the striking element with an obstacle causes the fuse to fire. In this case, through the hole in the end of the bottom of the body, the detonation pulse is transmitted to the explosive charge placed in the body, where a symmetrical blast wave is formed. As a result of the explosion, high pressures act on the inner surface of the casing, which leads to the expansion of its walls. Intense stresses arise in the material of the walls, the concentrators of which are annular grooves of rectangular cross section. As a result of this, the housing is divided into rings along the grooves. Further expansion of the rings leads to their spontaneous separation into fragmentation elements. As a result, a fragmentation field is formed, consisting of ring groups of fragments. The casing consists of a cylindrical part and a bottom part of an animated shape, therefore, the ring groups of fragments are evenly distributed in the meridional plane, which leads to the exclusion of the "dead zone" between the ring groups of the cylindrical and bottom parts. The ring groups of fragments of the cylindrical part move towards the surface of the barrier and provide damage in the near zone of the striking element. The ring groups of fragments of the bottom part scatter with elevation angles and provide damage at a greater distance as the transition from the cylindrical part of the body to the end of the bottom part.

The disadvantage of this device is that, after an organized separation of the body into rings along the grooves, with the formation of several ring groups of fragments of approximately the same mass and size, further separation of the rings occurs arbitrarily, in a chaotic order. This leads to the subsequent formation of fragments of different mass and size and, accordingly, various destructive forces, which, ultimately, reduces the effectiveness of the destructive action of the damaging element of the cluster munition.

The objective of the invention is to remedy these disadvantages and create a striking element of cluster munitions with the receipt of fragments of approximately the same optimal mass and speed with the technological suitability of the striking element for manufacture.

The solution to this problem is achieved by the fact that in the proposed striking element of a cluster munition containing a body including a cylindrical and bottom part, an explosive, a fuse and localizers for crushing the body into fragments made in the form of annular grooves on the outer surface of the cylindrical part of the shell and on the outer surface of the bottom the part, which has an animated shape and length, is greater than the length of the cylindrical part, according to the invention, in the body jumpers formed by annular grooves, g bored holes.

The presence of blind holes in the annular bulkheads of the case will allow the formation of additional localizers for crushing the ring into fragmentation elements on the surface of the rings, and in this case fragments of approximately the same mass and size are formed, which will increase the effectiveness of the destructive effect of the damaging element of the cluster munition.

The implementation of blind holes in the annular lintels of the housing with a depth of 35-60% of the thickness of the housing allows you to reduce the number of fragments of small fractions that are not "slaughter". At a depth of less than 35%, an uneven distribution and division into inhomogeneous fractions occurs, and at more than 60% the strength of the hull decreases.

The implementation of blind holes in the annular bulkheads of the body along the generatrix of the body profile will lead to the subsequent division of the ring into fragments of approximately the same mass and size, which will increase the effectiveness of the destructive effect of the damaging element of the cluster munition.

The number of holes in each jumper is selected in the range from 1 to 12, mainly 4-8, based on the fact that in the complete absence of blind holes on the surface of the jumper no additional localizers of crushing the ring into fragments are formed, and with the number of holes more than 12, fragments of a sufficiently small mass and size, which will lead to a decrease in their damaging effect.

The presence of grooves in the form of a spiral, especially multi-pass, will allow the formation of additional localizers of crushing the ring into fragmentation elements on the surface of the rings, and in this case fragments of approximately the same mass and size are formed, which will increase the effectiveness of the destructive effect of the damaging element of the cluster munition.

This spiral can be made by turning after or before the main annular grooves are completed, which will ensure the technological suitability of the striking element for manufacture.

The execution of a spiral with a coil elevation angle of approximately 45 ° will lead to the formation of fragmentation elements approximately equal in mass and size, since the division of the ring will occur approximately in the center, while the presence of angles on the fragments will increase their damaging effect.

The implementation of additional grooves in the form of a spiral with a depth of 15-25% of the thickness of the body allows you to reduce the number of fragments of small fractions that are not "slaughter". At a depth of less than 15%, an uneven distribution and division into inhomogeneous fractions occurs, and at a depth of more than 25%, the manufacturability of production decreases and the strength of the case decreases.

Grooves can be made in a rectangular shape.

The angle of inclination of the tangent to the generatrix of the housing at the transition point of the bottom to the cylindrical part to the axis of the housing may not exceed 7 °.

The butt end of the bottom can be made of different thickness, with thinning from the periphery to the center.

A central axial hole may be made at the end of the bottom.

The fuse may have rolling elements placed in an annular groove closest to the end face of the bottom of the body.

The implementation of crushing localizers on the outer surface of the bottom of the hull allows you to increase the solid angle of expansion of the fragments, the number of fragments and an increase in their speed, which increases the reduced area of damage.

The implementation of the bottom part longer than cylindrical, leads to an increase in the reduced area of the lesion due to an increase in the number of fragments that hit the target at a greater distance.

The execution of the bottom part of the animated form leads to the elimination of the "dead zone" in the gap between the fragmentation fields of the lower cylindrical and bottom parts of the body. In this case, the angular distribution of the expansion of the ring groups of fragments in the meridional plane is leveled, the gap in the fragmentation field disappears, and the reduced lesion area increases.

The implementation of annular grooves with a depth of 35-60% of the thickness of the body allows you to reduce the number of fragments of small fractions that are not "slaughter". At a depth of less than 35%, an uneven distribution and division into inhomogeneous fractions occurs, and at more than 60% the strength of the hull decreases.

The implementation of the rectangular grooves allows to improve the conditions for the separation of fragments, which leads to uniformity of the fragmentation field.

The angle of inclination of the tangent to the generatrix of the surface of the hull at the point of transition of the bottom to cylindrical to the axis of the hull does not exceed 7 °, which makes it possible to increase the angles of expansion of fragments of the bottom in the meridional plane while maintaining the continuity of the fragmentation field density.

The execution of the end face of the bottom of the housing with different thickness and / or with the Central hole allows you to improve the condition of the transfer of the detonation pulse to the charge enclosed in the housing, and to form a given front of the blast wave.

The presence of rolling elements of the fuse located in the annular groove closest to the end of the bottom of the body allows to increase the strength of the body and to eliminate the destruction of the explosive charge when installing the fuse on the body.

The invention is illustrated by drawings, where in Fig.1 shows a General view of the inventive device, Fig.2 is a housing of the inventive device with holes, Fig.3 is a cross section of a ring with holes, Fig.4 is a housing of the inventive device in a variant with one spiral, in Fig.5 is a cross section of a ring, in Fig.6 is a housing of the inventive device in the embodiment with several spirals, in Fig.7 is a cross section of a ring.

The main elements of the proposed device are:

1 - housing;

2 - cylindrical part of the body;

3 - bottom of the hull;

4 - annular groove;

5 - end face of the bottom of the hull;

6 - fuse;

7 - axial hole in the end of the bottom of the body;

8 - rolling elements of the fuse;

9 - explosive charge;

10 - additional groove;

11 - a spiral;

12 - hole.

The striking element of the cluster munition contains a housing 1 with a cylindrical 2 and bottom 3 parts, respectively. On the outer surface of the cylindrical 2 part of the body and on the outer surface of the bottom 3 part are located localizers crushing the body 1 into fragments made in the form of annular grooves 4. Outside the body 1, at the end of the bottom part 5, a fuse 6. In the bottom part 3 of the body 1 is made hole 7. The fuse 6 is attached to the housing 1 using rolling elements of the fuse 8. Inside the housing 1 is an explosive charge 9. On the outer surface of the cylindrical 2 parts of the housing and on the outer surface of the bottom 3 parts Additional localizers for crushing the housing 1 into fragments made in the form of additional grooves 10 having the shape of a spiral 11 are made. Blind holes 12 are made in the body bridges formed by the annular grooves 4.

The proposed device operates as follows.

The meeting of the striking element with an obstacle causes the fuse to fire. In this case, through the hole 7 in the end face of the bottom part 5 of the housing 1, the detonation pulse is transmitted to the explosive charge 9 located in the housing 1, where a symmetrical blast wave is formed. As a result of the explosion, high pressures act on the inner surface of the housing 1, which leads to the expansion of its walls.

In the main version, intense stresses arise in the wall material, the concentrators of which are the main annular grooves 4 of rectangular cross section and additional crushing localizers made in the form of blind holes 12. As a result, at the initial moment of time, the housing 1 is divided into rings along the grooves 4, because this requires less pressure. Further expansion of the rings leads to their spontaneous separation at the locations of additional crushing locators, made in the form of blind holes 12, into fragmentation elements of a certain shape and approximately equal mass. As a result of this, a fragmentation field is formed, consisting of fragments having approximately equal mass and geometric dimensions.

In the embodiment, intense stresses arise in the wall material, the concentrators of which are the main annular grooves 4 of rectangular cross section and additional crushing localizers made in the form of additional grooves 10 having the shape of a spiral 11. As a result, at the initial moment of time, the housing 1 is divided into rings along grooves 4, since grooves 4 have a greater depth than grooves 10. Further expansion of the rings leads to their spontaneous separation along grooves 10 into fragmentation elements nts of a certain shape and approximately equal mass. As a result of this, a fragmentation field is formed, consisting of fragments having approximately equal mass and geometric dimensions. The casing consists of a cylindrical part 2 and a bottom part 3 of a lively shape, so the groups of fragments are evenly distributed in the meridional plane. There is no "dead zone" between the groups of cylindrical 2 and bottom 3 parts. Groups of fragments of the cylindrical part 2 move towards the surface of the barrier and provide damage in the near zone of the striking element. The groups of fragments of the bottom part 3 scatter with elevation angles and provide damage at an ever greater distance as the transition from the cylindrical part 1 of the body to the end of the bottom part 5.

Using the proposed technical solution will allow you to create a striking element of cluster munitions with the receipt of fragments of approximately the same optimal mass and speed with the technological suitability of the striking element for manufacture.

Claims (14)

1. The striking element of a cluster munition, comprising a housing comprising a cylindrical and bottom part, an explosive, a fuse and localizers for crushing the body into fragments made in the form of annular grooves on the outer surface of the cylindrical part of the shell and on the outer surface of the bottom part, which has an animated shape and a length greater than the length of the cylindrical part, characterized in that blind holes are made in the body bridges formed by the annular grooves. 2. The striking element of the cluster munition according to claim 1, characterized in that the blind holes are made with a depth of 35-60% of the thickness of the shell. 3. The striking element of the cluster munition according to claim 1, characterized in that the blind holes are located along the generatrix of the profile of the body. 4. The striking element of the cluster munition according to claim 1, characterized in that the number of holes in each jumper is from 1 to 12, mainly 4-8. 5. The striking element of the cluster munition according to claim 1, characterized in that on the outer surface of the hull and the outer surface of the bottom part, additional grooves are made in the form of at least one spiral. 6. The striking element of the cluster munition according to claim 5, characterized in that the helix is multi-launch. 7. The striking element of the cluster munition according to claim 5, characterized in that the spiral is made with a coil angle of approximately 45 °. 8. The striking element of the cluster munition according to claim 5, characterized in that the additional grooves in the form of a spiral are made with a depth of 15-25% of the thickness of the shell. 9. The striking element of the cluster munition according to claim 1, characterized in that the annular grooves are made with a depth of 35-60% of the thickness of the shell. 10. The striking element of the cluster munition according to claim 5, characterized in that the additional grooves in the form of a spiral are made in a rectangular shape. 11. The striking element of the cluster munition according to claim 1, characterized in that the angle of inclination of the tangent to the generatrix of the shell at the junction of the bottom to cylindrical to the axis of the shell does not exceed 7 °. 12. The striking element of the cluster munition according to claim 1, characterized in that the end face of the bottom of the hull is made of different thickness with thinning from the periphery to the center. 13. The striking element of the cluster munition according to claim 1, characterized in that a central axial hole is made in the end of the bottom of the hull. 14. The striking element of the cluster munition according to claim 1, characterized in that the fuse has rolling elements placed in a groove closest to the end of the bottom of the shell.

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