RU2639757C1 - Ammunition of multiple-factor and trans-barrier actions - Google Patents

Abstract

FIELD: weapons and ammunition.SUBSTANCE: device comprises a body, initiation means, main and extra explosive charges, one or more sections in the main charge. These sections are made as chamfer or funnels, or the chutes of various geometrical shapes, or as a combination of various geometrical shapes, completely or partially filled with combustible powdery or liquid substances or their mixes in various aggregate states which can be located in various parts of ammunition. The device contains a damage agent or an assembly of damage agents at the bottom part of the sections, replicating the bottom part of the sections, located beneath a layer with combustible substances, by form. The extra explosive charge location is related to location of the sections.EFFECT: improved reliability of the device operation due to the multiple-factor and trans-barrier action on openly positioned and covered objects, remote by considerable distances from the site of the explosion.3 cl, 2 tbl, 3 dwg

Description

The invention relates to defense technology and can be used in various types of ammunition (PSU) for destruction by the multifactor high-explosive, optical, incendiary, kinetic action of the striking elements and the flow of particles of reactive energy-intensive material of objects located in an open area and in beyond-the-air space.

Various types of ammunition are known that combine target destruction with high-explosive and kinetic actions (for example, the Arms of Russia catalog, vol. 7 - M .: AOZT, Military Parade, 1997). This catalog presents kinetic ammunition that is carried out by various types of damaging elements, including fragments of natural fragmentation, compact damaging elements, cumulative jets formed by metal funnels with a small deflection.

The disadvantage of the known ammunition is the predominantly one-factor nature of the interdiction and, mainly, kinetic damaging elements. High-explosive and optical factors of influence make an insignificant contribution to the damaging effect of backward action. The disadvantages of the listed ammunition also include the weakly expressed nature of their incendiary effect.

The closest analogue, to the essence of the present invention, selected as a prototype, is the technical solution according to patent RU 2556046 with a priority of 02.25.14, “Ammunition of multifactorial and forbidden actions”. The munition in accordance with this invention consists of sections that are separately placed in the main charge, forming kinetic damaging elements, and shaped sections, filled with energetic reaction materials, forming powerful flows of reacting substances, amplifying or giving the munition high-explosive, optical and incendiary factors. Ammunition successfully solves the problems of destruction of various protected objects, however, when operating on remote defensive structures, its effectiveness is reduced for several reasons. Among them, a drop with the distance of the velocity head of the flow of reacting components, a discrepancy in the trajectories of the striking elements and the flow, and, as a result, a decrease in its incendiary ability in the after-space, parameters of high explosive and optical effects.

The aim of this invention is the creation of ammunition of multifactorial and backward action, with enhanced joint action on remote openly located and protected objects of focused flows of burning particles from energy-intensive materials and damaging elements, covered in the process of explosion with a layer of energetic material, which amplifies optical due to its burning on the surface of the damaging element radiation, shock waves, thermal field and incendiary effect of the device in the after-space TBE.

This goal is achieved by the fact that in an ammunition of multifactorial and backward action, containing a housing, means of initiation, the main and additional charges of an explosive, the main charge contains one or more sections made in the form of funnels, recesses, grooves or in the form of a combination of various geometric shapes, filled with partially or completely combustible liquid or powdery substances, or their mixtures of various state of aggregation, which can be located in different parts of the ammunition, and ADDITIONAL charge located in association with the sections located in different parts of the munition. Ammunition contains in the bottom of the sections of the damaging element or block of damaging elements, reproducing in shape the bottom of the section. The striking elements can also be made in the form of thickenings of the bottom of the cladding sections and can be made of materials that differ in physico-mechanical and physico-chemical properties, and vary in size and molding methods.

Thus, the distinguishing features of the invention are:

- a combination in the equipment of sections of reactive materials of different consistency of the state of aggregation and kinetic damaging elements in the form of a separate element or block of elements, which may differ in the composition of the block in size, the material from which they are made and the method of their molding;

- the relative position of the component parts of the equipment section, the kinetic damaging elements in the bottom, and reactive materials in the upper part of the section;

- conformity of the shape of the damaging elements to the shape of the bottom of the sections;

- the implementation of the bottom of the cladding sections with a thickening, ensuring the formation of the damaging element from the bottom of the cladding.

These features of the invention together expand the range of functionality of ammunition for hitting distant objects located both in open terrain and in shelters, and can be implemented both in ground-based ammunition and in means of defeating trajectory activation, including in corrected and adaptable PSUs.

Combustible energy-intensive materials of various consistencies located in the upper part of the recesses or linings, in the recesses under the influence of the detonation of the main charge, are heated to higher temperatures due to increased compressibility, compared with the damaging elements located in the bottom part, and are coated with a film of combustible material due to melting or evaporation the surface of the striking element located in the bottom. The combustion of particles located on the surface of the striking element increases the parameters of the optical and shock-wave components and the incendiary effect of ammunition in the air and in the after-space. The combination in sections of the damaging elements, forming various physical factors of influence and the order of their mutual arrangement, ensures the unidirectional movement of the damaging elements and combustible materials, focusing their impact on the affected object and also provides an increase in the degree of damage to the object of damage due to the addition of influencing factors, as well as due to effects of their mutual reinforcement (synergistic effects).

The formation of the bottom of the cladding with a thickening simplifies the design of those ammunition for which there are no increased requirements for the size of the holes in the target.

Various options for the design of the ammunition are presented in figures 1-3. In FIG. 1 shows the options for the execution of ammunition with an axial orientation of the joint movement of kinetic striking elements and the flow of reacting components.

The ammunition of FIG. 1 a, b, c, d consists of a housing - 1, a main charge - 2, an additional charge - 3, an additional charge shell - 4, initiating means - 5, a recess lining in the main charge - 6, a kinetic damaging element - 7 or a block kinetic damaging elements - 9, or a damaging element in the form of a thickening of the bottom of the cladding - 10, equipping sections of combustible substances in the form of powder or granules, or liquids of various viscosities, or mixtures thereof in various states of aggregation, including in the form of tablets - 8. Sections are filled with fuel ETS completely, as shown in FIG. 1a or partially FIG. 1b. Various metals or their alloys can be used as the material of the striking elements, the formation of the striking elements can be carried out by casting, turning, stamping from powder materials and other techniques.

Variants of mock axial munitions of FIG. 1 also differ in the shape of the sections. For options a and c, the section has a cylindrical shape; for options b and d, the section in the main charge is a combination of a hemisphere and a cylinder.

Due to the difference in the degree of filling and in the shape of the section, option a differs from option b in higher parameters of optical action, option b - in increased parameters of incendiary action, since enlarged particles of incendiary substance are formed from compressed compressed material in the after-space. The alternation in the block in the striking elements of various materials and the increased size of the block compared to the block of combustible material provide advantages for this option in the size of the holes in the defensive structures, while maintaining an acceptable level of optical and high-explosive action, including as a result of covering the surface of the striking elements with a layer of combustible material. Variant g is slightly inferior to Variant a in terms of the complex of damaging factors in the after-space, at the same time this variant is more technologically advanced in the mass production of weapons.

The variant of the ammunition of FIG. 2 differs from the variants of FIG. 1 radial direction of action of damaging factors and the number of sections in the main charge. This option is preferable for use in large-sized ammunition and is intended for action on group targets. According to the parameters of backward action, it is similar to the variant of FIG. 1b.

The ammunition of the radial action of the damaging factors of FIG. 3 differs from the ammunition of FIG. 1 and FIG. 2 displacement of an additional explosive charge relative to the main axis of the munition and the action of damaging factors in the direction opposite to this area. It is advisable to use it in the means of defeat of adaptive action. In terms of the parameters of backward action, it is in many respects similar to the variant of FIG. 1g

Ammunition of the proposed design works as follows. The initiating means drives an additional bursting charge, which causes the detonation of the main charge. The location of the additional charge determines the direction of action of the damaging factors of the options for the execution of the main charge.

The detonation of the main charge affects primarily the lining of the sections, if any, and on the bottom of the equipment section, deforms their bottom. The striking elements adjacent to the bottom of the section partially bend, taking a streamlined shape. The movement of the striking elements and layers of combustible material occurs in one direction along the main axis of the munition, as is the case with the variants of FIG. 1, and in the radial direction, as is the case with the variants of FIG. 2 and FIG. 3. In this case, part of the combustible substance adheres to the striking elements, and its main part moves in the same direction in which the striking elements move.

Thus, the unidirectionality of movement and impact on the target of damaging factors is formed. The mutual reinforcement of the influencing factors is a consequence of the sticking of a part of the combustible substance to the damaging elements, as well as the consequence of the thermal effect of the flame of burning particles on the walls of the defensive structure, which reduces its resistance to the kinetic and high-explosive effect of the damaging factors. As a result of the combined action of these factors, the size of the hole, the penetration depth and the mass of the substance brought into the after-space increases, and, therefore, the parameters of the factors acting in the after-space increase.

A comparative evaluation of the effectiveness of the prototype (see patent RU 2556046) and the developed device was carried out by determining the parameters of the barrage, high explosive and optical effects of the models of explosive devices behind a steel barrier. The barrier was installed at a distance of 30 m from the location of the layouts, the diameter and length of which were respectively 150 and 200 mm. The parameters of a high-explosive action behind an obstacle with a wall thickness of 14 mm were evaluated by pressure sensors of the company PCB type ICP. Pressure sensors were installed at a distance of 3 m behind the barrier. The parameters of optical radiation were determined in the wavelength range of 0.4 ÷ 4.5 μm module ADC E-440. Table 1 presents comparative data on the ratio of pressure levels in a shock wave propagating behind an obstacle due to exposure to damaging elements and the flow of burning particles from energy material, and table 2 presents data on the ratio of radiation powers in the after-space to the prototype and the developed device.

The data presented in tables 1 and 2 confirm the advantage of various versions of the developed device over the prototype in the parameters of the damaging effect in the target's back-space, which is a considerable distance (30 m) from the blasting site.

By the maximum pressure at the front of the shock wave (table 1), the variants of the developed device exceed the prototype by 1.4-1.7 times, by the strength of radiation in the after-space (table 2) in the wavelength range of 0.4-4.5 microns in 3 -4 times.

As follows from the experimental data, a clear superiority over the prototype is demonstrated by all the options considered, despite the differences in the state of aggregation of the combustible material, the degree of filling of the sections, the shape of the recesses and facings in the main charge and the number of damaging elements, the relative position of the sections and the additional bursting charge.

Claims (3)

1. An ammunition of multifactorial and foreign action, comprising a housing, means of initiation, primary and secondary explosive charges, one or more sections in the main charge, made in the form of recesses or funnels, or gutters of various geometric shapes, or in the form of a combination of various geometric shapes, filled with fully or partially combustible powdery or liquid substances or their mixtures of various state of aggregation, which can be located in different parts of the munition, distinguishing The fact that it contains a damaging element or a block of damaging elements in the bottom of the sections reproducing in shape the bottom of the sections located under the layer with combustible substances, and the additional explosive charge is located in relation to the location of the sections. 2. Ammunition according to claim 1, characterized in that the block of damaging elements is made of parts that differ in size, physico-chemical and physico-mechanical properties of the material from which they are made, and by the method of their molding. 3. Ammunition under item 1, characterized in that the striking element is made in the form of a thickening of the bottom of the cladding sections.

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