RU85996U1 - COMBAT PART - Google Patents

Abstract

1. The warhead, comprising a housing with a shell of a given crushing, a head fuse with a detonator, an explosive charge with a cumulative lining and an additional detonator, characterized in that the cumulative lining is made in the form of a spherical segment with a hole in its apex through which an additionally inserted tube passes with a transfer charge of an elastic explosive in the shell connecting the detonator of the head fuse with an additional detonator located in the central part of the charge jerky substance. ! 2. The warhead according to claim 1, characterized in that the radius of the spherical surface of the cladding is taken equal to R = 0.7 ... 0.9dv, where dv is the diameter of the inner surface of the warhead. ! 3. The warhead according to claim 1, characterized in that the distance from the base of the cumulative lining to the end face of the detonator of the head fuse is selected in the interval L = 0.8 ... 1.2 dv. ! 4. The warhead according to claim 1, characterized in that the diameter of the transfer charge is selected from the condition dz> 1.5dcr, where dcr is the critical diameter of the detonation. ! 5. The warhead according to claim 1, characterized in that the shell of the transfer charge is made of a porous material, for example polyurethane foam.

Description

The utility model relates to the field of military equipment and can be used in warheads (warheads) of aircraft unguided rockets of small and medium caliber.

It is known that high-explosive fragmentation warheads are widely used in aircraft unguided missiles (NAR). A characteristic feature of such shells is the flat nature of the trajectories with a scattering ellipse extended in the direction of fire.

A typical design of a high-explosive fragmentation warhead for the NAR contains a cylindrical body with a shell of a given crushing, an explosive and an instant fuse (see, for example, "Means of destruction and ammunition: Textbook / A.V. Babkin, V.A. Veldanov, E .F. Gryaznov et al .; Under the general editorship of VV Selivanov. - M.: Publishing House of the MSTU named after N.E.Bauman, 2008., p. 519). When this warhead is undermined, a narrow lesion zone is formed, perpendicular to the direction of fire. As a result, a low probability of hitting a point target.

It is possible to increase the affected area if you use the central initiation of the explosive charge of the warhead, which was implemented, for example, in the design described in application No. 2617955 MKI 4 F42B 13/18, publ. 01/13/1989, "High-explosive projectile, having a shell with notches to increase efficiency and method of its manufacture." The proposed design has a metal casing of small thickness, tightly fitting with its inner surface to the rings with notches that form the shell of the shell. The main explosive charge (BB), located in the shell, has an additional explosive charge, playing the role of the main detonator, and located in the middle of the main charge. To transmit a detonation pulse from the fuse to an additional charge, a tube is located along the axis of the main charge.

When the head fuse is triggered, the detonation pulse is transmitted through the tube to an additional explosive charge, upon detonation of which the detonation of the main explosive charge is initiated. With central initiation, the angle of the sector for the expansion of fragments increases, as a result, the reduced area of fragmentation damage of warheads increases.

The disadvantage of this design is the lack of damaging elements in the sector in the direction of the projectile and the inability to use ammunition to destroy lightly armored vehicles.

These shortcomings are eliminated in the design of the cumulative fragmentation warhead for the NAR S-5KO (see "Means of destruction and ammunition: Textbook / A.V. Babkin, V.A. Veldanov, E.F. Gryaznov, etc.; Under the general ed. . V.V. Selivanova. - M .: Publishing House of MSTU named after N.E.Bauman, 2008., p.519 "), adopted by the authors for the prototype. The cumulative fragmentation warhead contains a body, a head fuse and a fairing. An explosive charge with cumulative lining, an inert lens with a capsule, a detonator and a detonator, and a safety cone are placed inside the case. The cylindrical casing of the warhead has a thin outer shell, on the inside of which there are ten rings with notches that form 220 fragmentation elements weighing 2 g each when blown. The principle of operation of this warhead is as follows: when meeting with an obstacle, a head fuse is triggered, a detonation pulse is transmitted to the capsule detonator and detonator, as a result of detonator detonation, detonation of explosive charge is initiated. The front of the detonation wave acts on the cumulative lining and when it is compressed, a cumulative jet is formed, which breaks through the armor barrier. In addition, detonation products act on the inner surface of the warhead case, destroy annular fragmentation elements and the outer shell. The resulting fragments can affect unarmored vehicles and manpower.

The disadvantages of this design include the following.

Strengthening the reservation of the main tanks led to the fact that the equivalent anti-cumulative resistance of armor protection reaches values of 1000 mm and higher. The defeat of such targets by aviation missiles of caliber up to 80 mm inclusive is almost impossible. The real targets for a cumulative fragmentation warhead of caliber up to 80 mm are lightly armored and unarmored vehicles and manpower. However, the cumulative jet when exposed to lightly armored vehicles (such as infantry fighting vehicles, armored personnel carriers) has a slight damaging ability, since lightly armored vehicles have a low density of the internal layout of vital aggregates, and the cumulative stream has weak armor effects. The cumulative funnel, lens unit, safety cone occupy a fairly large space inside the warhead and significantly reduce the amount of explosive placed there. As a result, the fragmentation and high-explosive action of warheads will also be negligible.

The technical task of this utility model is to increase the striking ability of the warhead of an unguided small and medium caliber missile. This problem is solved by increasing the armor-borne damaging effect when defeating lightly armored targets and increasing the area of high-explosive and fragmentation destruction of manpower and unarmored equipment.

In this utility model, the technical problem is solved in that in the NAR warhead containing a housing with a shell of a given crushing, a head fuse with a detonator, an explosive charge with a cumulative lining and an additional detonator, the cumulative lining is made in the form of a spherical segment with a hole in its apex, which passes an additionally inserted tube with a transfer charge of elastic explosive in the shell connecting the detonator of the head fuse with an additional detonator located in the central part ti explosive charge. The radius of the spherical surface of the cumulative lining is equal to R = 0.7 ... 0.9d _in , where d _in - the diameter of the inner surface of the warhead. The distance from the base of the lining to the end face of the detonator of the head fuse is selected from the ratio L = 0.8 ... 1.2d _in . The diameter of the transfer charge is selected from the condition d _z ≥1.5d _cr , where d _cr is the critical diameter of the detonation, which ensures reliable transmission of the detonation pulse to the central detonator. The shell of the transfer charge is made of a porous material, for example, polyurethane foam with a thickness of δ> 3d _s , which eliminates the possible undesirable initiation of the explosive charge through the walls of the tube with the transfer charge during the transfer of the detonation pulse to an additional detonator.

The utility model is illustrated by the drawing, where in Fig.1 shows a General view of the warhead.

The warhead consists of a housing 1 made in the form of a cylindrical shell of a given crushing, for example, by applying a fragmentation grid by laser processing of the outer surface. An instantaneous fuse head 2 with a detonator 3 is fixed in front of the housing 1. An explosive charge 4 is placed inside the housing 1. A cumulative lining 5 is made at the front end of the explosive charge 5, made in the form of a spherical segment with an aperture at the top through which the tube 6 with the transfer charge 7 of the elastic explosive in the shell 8. In the central part of the explosive charge 4 is an additional detonator 9, which is connected through a tube 6 with the detonator 3 of the fuse 2. Between the base of the cumulative lining 5 and the end face of the detonator 3 the head fuse 2 has a free volume that allows the formation of a compact damaging element in the process of deformation of the cumulative lining 5 by the detonation products of the explosive charge 4.

The proposed device operates as follows. Upon contact with the obstruction of the head fuse 2, the detonation pulse from the detonator 3 of the head fuse initiates the explosive transfer charge 7. The detonation pulse propagates along the transfer charge 7 and triggers the additional detonator 9. The detonation pulse of the additional detonator 9 initiates the detonation of the main charge of explosive 4 in its central part . A spherical detonation wave propagates from the center of the explosive charge 4 to the periphery, destroys the warhead shell into fragments of a given mass, 90% of which fly apart in the expansion zone bounded by two sectors with an angle at the apex of about 24. When loading a spherical cumulative lining 5 with explosive charge detonation products 4, it is deformed by the “eversion” type without the formation of a cumulative jet, forming a compact damaging element moving along the axis of the warhead in the direction of the obstacle and hitting it.

The formation of a compact damaging element from a cumulative lining instead of a cumulative jet is characteristic of spherical cumulative lining. Calculations show that the damaging element formed from a spherical lining with a radius of a spherical surface of approximately R = 0.7d _in has the maximum energy, where d _in is the diameter of the inner surface of the warhead housing. It is advisable to slightly increase this radius in order to increase the mass of explosives placed in the warhead casing and increase the fragmentation and high-explosive action of warheads. A compact damaging element, when interacting with an armored obstacle, forms a hole that is 3 ... 5 times larger than the hole from the cumulative jet and has a high zabronovoe effect.

The spherical cumulative lining has smaller dimensions than the conical lining with a solution angle of 50 ... 60, typical of traditional cumulative charges. In addition, for it, the distance necessary for the formation of the damaging element decreases, the lens assembly eliminating the front of the detonation wave is no longer needed. As a result, the mass of explosives placed in warheads with a fixed length increases approximately twofold. This leads to an increase in the high-explosive and fragmentation effects of warheads.

The initiation of explosives from the central part of the charge increases the angle of the sector of expansion of fragments by about two times compared with the initiation of a charge from the end. This increases the area of fragment expansion, which is most important for shells with flat trajectories, which include NAR. As a result, the reduced area of fragmentation damage increases by approximately 10–20% and the probability of hitting a target increases due to better matching of the dispersion ellipse of HAP with the configuration of the fragmentation area.

Claims (5)

1. The warhead, comprising a housing with a shell of a given crushing, a head fuse with a detonator, an explosive charge with a cumulative lining and an additional detonator, characterized in that the cumulative lining is made in the form of a spherical segment with a hole in its apex through which an additionally inserted tube passes with a transfer charge of an elastic explosive in the shell connecting the detonator of the head fuse with an additional detonator located in the central part of the charge jerky substance. 2. The warhead according to claim 1, characterized in that the radius of the spherical surface of the cladding is taken equal to R = 0.7 ... 0.9d _in , where d _in - the diameter of the inner surface of the warhead. 3. The warhead according to claim 1, characterized in that the distance from the base of the cumulative lining to the end face of the detonator of the head fuse is selected in the interval L = 0.8 ... 1.2 d _in . 4. The warhead according to claim 1, characterized in that the diameter of the transfer charge is selected from the condition d _s > 1,5d _cr , where d _cr is the critical diameter of the detonation. 5. The warhead according to claim 1, characterized in that the shell of the transfer charge is made of a porous material, for example polyurethane foam.