EA002363B1 - Reactive armor structure - Google Patents

Abstract

1. A reactive armor structure for protection against hollow explosive charge jets, said structure comprising an enclosure in which at least two reactive explosive elements are arranged, each of them is a three-layered element, the medium layer is an explosive charge lined with two metal plates, and the reactive explosive elements are positioned at an angle to the enclosure front wall, characterized in that the angle between the reactive explosive elements and the enclosure front wall is 5..90 degree , the explosive charge is divided in the reactive explosive element into at least two portions by a partition parallel to one of its face walls, the enclosure is provided with a protective shield installed with a gap respective to the container back wall. 2. A reactive armor structure according to claim 1, characterized in that neighboring reactive explosive elements are positioned in parallel planes, and the distance between the neighboring reactive explosive elements is 5...20 of the charge thickness of the explosive product. 3. A reactive armor structure according to claim 1, characterized in that the explosive charge of the reactive explosive elements is divided by a T-shaped partition into three rectangular compartments so that these two compartments abut the front or the back wall of the enclosure by their short sides, while the third side abuts by its longer side to the short sides of two other portions of the charge. 4. A reactive armor structure according to claim 1, characterized in that each portion of the divided charge together with the lining metal plates in the reactive explosive element is designed as a separate assembly, and the dividing partitions are formed be contacting face walls of these assemblies. 5. A reactive armor structure according to claim 1, characterized in that a filling layer with an apparent density 30...250 kg/m<3> is arranged in the enclosure cavity between neighboring reactive explosive elements. 6. A reactive armor structure according to claim 1, characterized in that the protective shield is made of high-strength armored steel and has a thickness 0,5...3,0 of the charge thickness of the reactive explosive element. 7. A reactive armor structure according to claim 1, characterized in that the reactive explosive members are elastic elements abutting the surface of the reactive explosive elements. 8. A reactive armor structure according to claim 1, characterized in that the reactive explosive members are elastic elements arranged inside the filling layer between the reactive explosive element. 9. A reactive armor structure according to claim 5, characterized in that the filling layer arranged between the reactive explosive elements is a foamed polymer material. 10. A reactive armor structure according to claim 6, characterized in that the protecting shield is common for 2..5 enclosures, and provided with fastening units to fasten enclosures to the protecting field, and fastening units to fasten the shield to an object to be protected. 11. A reactive armor structure according to claim 7, characterized in that the elastic element is made as a rubber plate and has a thickness 0,3...4,0 of the charge thickness of the reactive explosive element. 12. A reactive armor structure according to claim 7 or 8, characterized in that each elastic element is divided by a partition into two layers arranged inside of this elastic element and made of a material having density 2700...7850 kg/m<3>, wherein the partition has a thickness 0,1...0,5 of the charge thickness of the reactive explosive element. 13. An assembly arrangement for protection against hollow explosive charge jets, comprising a set of reactive armor structures according to any preceding claim.

Description

The present invention relates to the field of protection of objects from cumulative anti-tank weapons, and more particularly to devices for protection from cumulative anti-tank melee weapons.

The most effectively proposed device can be used to protect infantry fighting vehicles, armored personnel carriers and other light armored vehicles from cumulative weapons such as anti-tank rocket-propelled grenades, grenade launchers, rifle grenades and anti-tank guided missiles, as well as unguided aircraft missiles.

A device for reactive armor is known according to US patent No. 5070764 dated 10.12.91 (it is also according to Israeli patent No. 88986 dated January 18, 89) designed to protect an obstacle from cumulative warheads and sub-caliber shells. It contains a housing in which two explosive reactive elements are installed in the form of an assembly in which an explosive layer is located between two metal plates. Each of the explosive reactive elements is supplemented by a passive protective element, also in the form of an assembly containing a layer of intumescent passive (non-explosive) material located between two metal plates, the explosive reactive element being located in front. Explosive reactive and passive elements can be located with a gap relative to each other or closely; parallel to the housing cover or at an angle to it. The known device may have one or two pairs of explosive reactive and passive elements connected together in the form of two parallel U-shaped blocks. When a projectile with high energy, such as a cumulative projectile, enters the front wall of the combined reactive and passive armor device, the projectile fuses, detonates its explosive charge and forms a cumulative jet. The cumulative jet pierces the front wall of the device body, penetrates into the explosive reactive element and initiates an explosion of the explosive charge in it. The metal plates of an explosive reactive element under the action of an explosion of its explosive charge come into motion in a direction close to the normal to their surface. These metal plates cross the trajectory of the cumulative jet, collide with it and cause the cumulative jet of damage, destroying it into individual fragments and deflecting them from the original trajectory of movement. The process of destruction of the cumulative jet is accompanied by the dispersion of part of its material to a dust state. As a result of this effect, the armor-piercing ability of the cumulative jet decreases. The remaining unaffected sections of the cumulative jet in the process of further movement fall into the passive element. The material contained in it swells when fragments of a cumulative jet hit, pushing apart the metal plates of the passive element in a local area close to the place where the fragment of the jet hits. This movement of the plates leads to additional destruction of fragments of the cumulative jet, although to a lesser extent than the explosion of a reactive element. Thus, the device of combined reactive and passive armor is able to provide protection of the main armored obstacles of the object from cumulative shells.

However, the explosion of an explosive charge in an explosive reactive element can destroy not only the cumulative jet. The air shock wave arising from the explosion, the flow of gaseous products of the explosion, and the fragments of the hull parts of the reactive armor device scattered by the explosion also affect the protected object, together with similar damaging factors arising from the explosion of cumulative ammunition. In the case when the armored parts of the protected object have sufficient thickness (and strength), for example, such as that of the main battle tanks, the combined high-explosive and fragmentation effect of the explosion of a weapon and an explosive reactive element does not cause significant damage to the protected object. But if the protected object is a light armored vehicle, such as an infantry fighting vehicle or an armored personnel carrier, with less than the tanks values of thickness (and strength) of the armored parts, then with such a joint explosion, the protected object can be seriously damaged. As the available test results show, under the indicated conditions, breaks and significant residual plastic deformations of the armor parts, cracks in the welds of the hulls and towers of the protected object can occur. In addition, in this case, in the internal volume of the protected object, a complex superposition of several shock waves arises with an amplitude and duration sufficient to cause damage to crew members (rupture of the eardrum, etc.).

The basis of the present invention is to create such a device of reactive armor, which, on the one hand, would provide protection for light armored vehicles from penetration by cumulative means of destruction, and, on the other hand, would have a reduced high-explosive and fragmentation effect on the protected object, that is, so that when the cumulative munition and reactive armor are fired together, there is no damage to the protected object and crew members by the shock wave, the flow of gaseous products of the explosion and chopping.

The problem is solved in that in the device of reactive armor containing a container in which at least two explosive reactive elements are placed, each of which is made three-layer, with a middle layer of explosive lined with two metal plates, and explosive reactive elements are installed at an angle to the front wall of the container, according to the invention, the angle between the explosive reactive elements and the front wall of the container is 5-90 °. The metal cladding plates of explosive reactive elements dispersed by the explosion of an explosive charge mounted at a large angle to the front wall of the container will hit the surface of the protected armor also at a large angle. As a result, the amount of movement (momentum) and the kinetic energy of the shock transmitted to the protected armor part will be significantly reduced.

In explosive reactive elements, the explosive charge is divided, according to the invention, into at least two parts by a partition parallel to one of its end faces and ensuring that detonation is not transmitted between these parts of the charge. As a result, the mass of the explosive charge in the explosive reactive element, exploding when a cumulative weapon is hit, is reduced by at least two times, which leads to a decrease in both high-explosive and fragmentation effects on the protected object. Accordingly, this effect will increase when the explosive charge is divided into three parts. However, when dividing the explosive charge into parts, it is necessary to maintain the effectiveness of its effect on the penetrating cumulative jet. Therefore, in this case, it is advisable to divide the explosive charge with a T-shaped partition into three approximately equal parts of a rectangular shape so that these two parts are adjacent to the front or back wall of the container with short sides, and the third part of this charge is adjacent its long side to the short sides of the other two parts of the charge.

Such parts of the charge are conveniently performed in the form of separate structures, introducing into their composition the corresponding parts of the metal facing plates and dividing walls as end walls. Moreover, two parts of the explosive charge are adjacent to the front or back wall of the container with short sides, and the third part is rotated relative to the first two at an angle of 90 ° and adjoins (through the separation wall) its long side to the short sides of the first two parts of the charge. Such an arrangement of the parts of the explosive charge ensures the high efficiency of the impact on the penetrating cumulative jet in a wide range of angles of fire of the protected barrier with a small mass of explosive charge operating in the elements of explosive reactive protection when the weapon is hit.

In the cavity of the container according to the invention, a filler layer with an apparent density of 30-250 kg / m ^{3 is} placed between adjacent explosive reactive elements. The specified layer of filler provides smooth braking of metal plates of explosive reactive elements scattered by the explosion, which, on the one hand, allows them to cause damage to the penetrating cumulative jet, the path of which they cross; on the other hand, the braking of the plates in the specified filler reduces the speed of their impact on the adjacent explosive reactive elements to a value safe from the point of view of excitation of detonation in the explosive charges of the neighboring explosive reactive elements. In addition, the braking of metal plates of explosive reactive elements is favorable from the point of view of reducing the impact of their impact on the protected object. To achieve these effects, it is necessary that the gap between adjacent explosive reactive elements, in which the filler layer is placed, be 5-20 thickness of the explosive charge of the explosive reactive element. It is advisable to make filler layers of foamed polymeric material. Nearby explosive reactive elements can be located in parallel planes.

The container according to the invention is provided with a protective screen mounted with a gap relative to the back wall of the container. This screen provides reflection of the air shock wave arising from the explosion of a cumulative weapon and an explosive reactive element, so that the passing part of this wave falls on the surface of the protected armored parts greatly weakened. In addition, the protective shield inhibits small fragments of the body of the cumulative weapons and explosive reactive element, and also further reduces the speed of movement of the metal plates of the explosive reactive element. The thickness of the protective shield made of high hardness armored steel should be 0.5-3.0 of the explosive charge of an explosive reactive element. For the convenience of placing a prefabricated structure in the form of a set of the proposed reactive armor devices on the protected object, the protective screen can be made common for 2-5 containers and equipped with nodes for attaching containers to the screen and nodes for attaching the screen to the protected object.

In order to fix explosive reactive elements and filler layers in the container cavity in the required position, to exclude their mutual movement and protect from external mechanical influences, according to the invention, explosive reactive elements are supplemented with elastic elements. These elastic elements can be made adjacent to the surface of the explosive reactive elements, and the elastic elements can be located inside the filler layer, dividing it into two parts. It is desirable that the elastic element was made in the form of a plate with a thickness of 0.3-4.0 thickness of the explosive charge of an explosive reactive element. The material of the elastic element may be rubber or other elastic material. Elastic elements made in the form of plates additionally contribute to protection against detonation initiation in explosive charges of neighboring explosive reactive elements. The elastic elements in the form of plates can be further divided into two layers by plates made of material with a density of 2700-7850 kg / m ³ , having a thickness of 0.1-0.5 of the thickness of the explosive charge of an explosive reactive element. This provides an additional reduction in the probability of transmission of detonation between adjacent explosive reactive elements, as well as, as is known, an increase in the efficiency of the device for protection against cumulative weapons.

The present invention is illustrated by a detailed description of examples of specific performance with reference to the accompanying drawings, in which:

FIG. 1 schematically depicts a reactive armor device made in accordance with the invention;

FIG. 2 - a reactive armor device made according to the invention, with an explosive reactive element explosive charge divided by a T-shaped partition into three parts, made in the form of separate structures, and using elastic elements in the form of plates;

FIG. 3 - installation of several containers on one protective screen, made according to the invention and equipped with nodes for attaching containers to the screen and nodes for attaching the screen to the protected object;

FIG. 4 is a prefabricated structure containing a set of reactive armor devices made according to the invention mounted on an infantry fighting vehicle.

The reactive armor device made according to the invention contains a container 1 (Fig. 1), in which four explosive reactive elements 2, 3 are placed, each of which is made of a three-layer, with a middle layer of explosive 4, lined with metal plates 5, 6. Explosive the reactive elements 2, 3 are installed at an angle to the front wall 7 of the container 1, so that the angle between the explosive reactive elements 2, 3 and the front wall 7 of the container 1 is 90 °. In the cavity of the container 1 between adjacent explosive reactive elements 2, 3 there is a layer of filler 8 with an apparent density of 30-250 kg / m ³ . The container 1 is equipped with a protective screen 9, installed with a gap relative to the back wall of the container 10, while the protective screen 9 is made of high hardness armored steel and has a thickness of 0.53.0 thickness of the explosive charge 4 of the explosive reactive element 2, 3. In explosive reactive elements 2, 3 the explosive charge 4 is divided into two parts 11, 12 by a partition 13 parallel to one of its end sides 14. Explosive reactive elements are located in parallel planes, and the distance between adjacent explosive reactive ementami 2, 3 their thickness is 5-20 explosive charge 4.

Explosive reactive elements 2, 3 are supplemented with elastic elements 15 (Fig. 2) adjacent to the surface of the explosive reactive elements 2, 3. The elastic element 15 is made in the form of a plate of rubber, 0.34.0 thick thickness of the explosive charge 4 of the explosive reactive element 2. The elastic element 15 is divided into two layers by a partition 23 made of a material with a density of 7850 kg / m ³ (steel). The explosive charge 4 in explosive reactive elements 2, 3 is divided by a T-shaped partition 16 into three rectangular parts 11, 12 and 17 so that these two parts 11, 12 are adjacent to the front wall 7 or the rear wall 10 of the container 1 with short sides, and the third part 17 of this charge is adjacent its long side to the short sides of the other two parts 11, 12 of the charge. In the explosive reactive element 2, each part 11, 12, 17 of the separated explosive charge 4 with its corresponding cladding metal plates 5, 6 is made in the form of a separate structure 18, and the separation walls 16 are the end walls of these separate structures 18.

The protective screen 9 is made common for 25 containers 1 (Fig. 3) and is equipped with attachment points 19 of the containers 1 to the screen 9, as well as attachment points 20 of the screen 9 to the protected object 21.

The prefabricated structure 22 (Fig. 4) for protection against cumulative ammunition contains a set of reactive armor devices made according to the invention and placed on the protected object 21 (infantry fighting vehicle BMP-3).

The work of the proposed device is as follows. When a cumulative anti-tank grenade enters the front wall 7 of the container 1, its fuse is cocked, the explosive charge of the grenade is detonated, and a cumulative stream is formed. It pierces the front wall of the container 7 and penetrates into the explosive reactive element 2, initiates the charge of the explosive 4 in this element 2. The fragments of the anti-tank grenade body moving in the direction of the protected object 21 pierce the front wall of the container 1, losing some of its energy. If these fragments still have sufficient energy, they penetrate the cavity of the container 1 and its rear wall 10, continuing to lose energy, and hit the protective shield 9. The protective shield 9, made of high hardness steel, provides almost complete braking of these fragments, which are already cannot penetrate the armor parts of the protected object 21.

It should be noted that the combination, on the one hand, of the container 1, containing metal cladding plates 5, 6 of explosive reactive elements 2, 3, and, on the other hand, of a protective shield 9 made of high hardness armored steel, increases the security of light armored vehicles from kinetic weapons (armor-piercing bullets and shells of automatic guns), as well as from fragments, including fragments of high-explosive fragmentation shells of large caliber.

The shock wave propagates from the place of the explosion in all directions, first passing through the details of the reactive armor device located in the internal cavity of the container 1. When passing through the layers of filler 8, the shock wave attenuates intensively due to the low density (30-250 kg / m ³ ) of the filler material 8. Once in a neighboring explosive reactive element 3, such a weakened shock wave can no longer lead to the initiation of detonation in the explosive charge 4 of this neighboring element 3. Penetrating through the walls of the container 1 into the surrounding airspace, the shock wave in the process of further movement, is mainly reflected from the armor screen 9 to the outside, relative to the protected object 21. The part of the shock wave penetrating through the armor shield 9 in the direction of the protected object 21 has little energy and is not able to cause damage to the protected object 21. In the case of separation of the explosive charge 4 into two or three parts 11, 12, 17, between which there is no detonation transmission, high explosive the explosion effect of the explosive reactive element 2 will be further reduced in proportion to the decrease in the mass of the charge 4.

The metal plates 5, 6 of the explosive reactive element 2 under the action of an explosion of its explosive charge 4 move in a direction close to the normal to the surface of this element 2. Moreover, they have a destructive effect on the cumulative jet, breaking it into separate fragments and deflecting these fragments from the trajectory of the cumulative jet. In the case of separation of the charge of explosive 4 into two or three parts 11, 12, 17, the location of these parts 11, 12, 17 is chosen so that when the charge mass 4 is reduced, the required working length of metal plates 5, 6 is maintained (the working length of these plates 5, 6 is their length in the direction coinciding with the direction of movement of the cumulative jet). The location of one of the parts 17 of the explosive charge 4 with the long side across the long sides of the other two parts 11,12 of this charge 4 leads to a significant expansion of the range of angles of fire of the protected object, at which the work of the proposed reactive armor device to destroy the cumulative jet is quite effective.

Simultaneously with the defeat of the cumulative jet, braking of the metal plates 5, 6 occurs in the layers of the filler 8 and on the elastic element 15, made in the form of a plate. When the metal plate 6, which continues to have a destructive effect on the cumulative stream during the further movement, reaches the adjacent explosive reactive element 3, the speed of the plate 6 decreases to a value that ensures that no charge of the explosive 4 in the explosive reactive element 3 is initiated by the impact of this plate 6.

The part of the metal plate 6, not falling on the explosive reactive element 3, continues to move. It pierces the back wall 10 of the container 1 and collides with the steel armor screen 9 at a large angle, which reduces the impact pulse of the plate 6 on the armor screen 9. This deforms the screen 9 and the final braking of the metal plate 6, so that it becomes unable to cause any damage to the protected object 21.

Thus, the proposed device of reactive armor provides protection of the protected object from penetration by a cumulative jet, as well as from secondary damaging factors arising from a joint explosion of a cumulative weapon and explosive reactive elements.

The most effectively proposed device can be used as part of a prefabricated structure containing a set of reactive armor, which is installed on armored ground objects: infantry fighting vehicles, armored personnel carriers, self-propelled artillery pieces, special vehicles, as well as on building structures, ships and boats.

Claims (13)

CLAIM 1. The device of reactive armor for protection against cumulative ammunition, containing a container in which at least two explosive reactive elements are placed, each of which is made three-layer, with a middle layer of explosive lined with two metal plates, and explosive reactive elements are installed at an angle to the front wall of the container, characterized in that the angle between the explosive reactive elements and the front wall of the container is 5-90 °, in explosive reactive elements the explosive charge The substance is divided into at least two parts by a partition parallel to one of its end sides, while the container is equipped with a protective screen installed with a gap relative to the back wall of the container. 2. The device of reactive armor according to claim 1, characterized in that the adjacent explosive reactive elements are installed in parallel planes, and the distance between adjacent explosive reactive elements is 5-20 of the thickness of their explosive charge. 3. The reactive armor device according to claim 1, characterized in that the explosive charge in the explosive reactive elements is divided by a T-shaped partition into three rectangular parts so that these two parts are adjacent to the front or back wall of the container with short sides, and the third part this charge is adjacent its long side to the short sides of the two other parts of the charge. 4. The device of reactive armor according to claim 1, characterized in that in the explosive reactive element each part of the separated explosive charge with its corresponding cladding metal plates is made as a separate structure, and the partitions separating the explosive charge are formed by the end walls of these contacting each other individual designs. 5. The device of reactive armor according to claim 1, characterized in that in the cavity of the container between adjacent explosive reactive elements there is a filler layer with an apparent density of 30-250 kg / m ³ . 6. The device of reactive armor according to claim 1, characterized in that the protective shield is made of high hardness armored steel and has a thickness of 0.5-3.0 thickness of the explosive charge of an explosive reactive element. 7. The device of reactive armor according to claim 1, characterized in that the explosive reactive elements are supplemented with elastic elements adjacent to the surface of the explosive reactive elements. 8. The device of reactive armor according to claim 1, characterized in that the explosive reactive elements are supplemented by elastic elements installed inside the filler layer located between the explosive reactive elements. 9. The reactive armor device according to claim 5, characterized in that the filler layer placed between the explosive reactive elements is made of foamed polymeric material. 10. The device of reactive armor according to claim 6, characterized in that the protective screen is made common for 2-5 containers and is equipped with nodes for attaching containers to the protective screen, as well as nodes for attaching the screen to the protected object. 11. The device of reactive armor according to claim 7, characterized in that the elastic element is made in the form of a plate of rubber with a thickness of 0.34.0 thickness of the explosive charge of an explosive reactive element. 12. The device of reactive armor according to claim 7 or 8, characterized in that each elastic element is divided into two layers by a partition located inside this elastic element and made of material with a density of 2700-7850 kg / m ³ , and the partition has a thickness of 0, 1-0.5 thickness of the explosive charge of an explosive reactive element. 13. A prefabricated design for protection against cumulative ammunition, containing a set of reactive armor devices in accordance with any preceding paragraph.