RU2064650C1 - Device for protection of obstacles against shells - Google Patents

Abstract

FIELD: devices for protection of obstacles against shells. SUBSTANCE: device comprises housing 1 accommodating at least one pair of containers 2, 3 with an explosive. Each pair of containers 2, 3 forms a single detonating net and its containers 2, 3 are installed in such a way that in the plane perpendicular to surfaces 4, 5 of containers 2, 3 facing each other these surfaces form an active angle whose vertex is directed towards one of the side walls of housing 1. Spacing member 9 engageable with each of containers 2, 3 may be made in the form of a clamp and may be installed between containers 2, 3. At least one of flexible member 11 may be positioned between one of walls 10 of housing 1 and one of the containers of each pair on the side of its surface opposite to the surface of this container. EFFECT: enhanced reliability. 4 cl, 4 dwg

Description

 The present invention relates to the field of protection of obstructions, and most particularly to devices for protecting obstructions from shells.

 The most effectively proposed device is used to protect the armored barriers of tanks and other armored vehicles from shells that have a large supply of energy, for example, cumulative shells or kinetic shells.

 A device of combined reactive and passive armor is known (US patent N 5070764 dated 10.12.91), designed to protect obstacles from cumulative warheads and sub-caliber shells. It contains a housing in which at least one reactive element is installed in the form of a container in which an explosive layer is located between two metal plates. Each of the reactive elements is supplemented by a passive protective element, also in the form of a container, containing a layer of intumescent passive (non-explosive) material located between two metal plates, the reactive container being located in front. Reactive and passive containers can be located with a gap relative to each other, or close to each other; parallel to the housing cover. or at an angle to it. The known device may have two pairs of reactive and passive containers connected together in the form of two parallel V-shaped blocks.

 When a projectile having high energy, for example, a cumulative projectile, gets into the front wall of the combined reactive and passive armor device, the projectile fuse is blown up, its subversive charge is detonated and a cumulative jet is formed. The cumulative jet pierces the front wall of the device body, penetrates into the reactive container and initiates an explosive charge in it. The metal plates of the jet container under the action of the explosion of its explosive charge come into motion in a direction close to the normal to their surface. The metal plates of the container cross the trajectory of the cumulative jet, collide with it and cause the cumulative jet of damage, breaking it into separate fragments and deflecting them from the original trajectory of movement. The process of ruptures of a 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 container. The material contained in it swells when fragments of a cumulative jet hit, pushing apart the metal plates of the passive container in a local area close to the place where the fragment of the jet hits. Such movement of the plates leads to additional destruction of the fragments of the cumulative jet, although to a lesser extent than the explosion of a jet container. Thus, the device of combined reactive and passive armor is able to protect the main armored obstacle of the object from cumulative shells.

 However, it is known that the effectiveness of the impact on the cumulative jet of the specified device and other similar devices substantially depends on the angle of impact of the cumulative jet with the reactive (and passive) container. At meeting angles (the angle is measured from the normal to the surface of the container) of 50-70 degrees, the greatest efficiency of the effect of the movement of the metal plates of the container on the cumulative stream is achieved. At the meeting angles about 30 degrees. the impact of the jet container still significantly reduces the armor-piercing ability of the cumulative jet. But at meeting angles close to normal to the surface of the container, the device loses most of its effectiveness and, as a rule, cannot provide protection for the main armor barrier from a cumulative jet. Since it is difficult to predict in advance how to place the container on the protected barrier so that its impact on the cumulative stream is maximum, the degree of protection of the barrier is highly dependent on the direction of fire. Moreover, in the known device, the reactive and passive containers in each pair are always parallel to each other and the degree of their impact on the cumulative stream changes equally when the direction of the shelling changes.

 The basis of the present invention is the creation of a device for protecting the barrier from shells with such an arrangement of containers in the housing, which would significantly reduce the dependence of the degree of protection of the barrier on the direction of its shelling.

 The problem is solved in that in a device for protecting against shells containing a housing in which at least one pair of containers is installed, each of which is made three-layer with a middle layer of explosive, according to the invention, each pair of containers forms a single detonation chain , and its containers are installed in the case so that in a plane perpendicular to the container surfaces facing each other, these surfaces form an acute angle, the apex of which is directed towards one of the side housing knock.

 This creates such conditions for the penetration of a cumulative jet or kinetic projectile through this device such that the angle of contact with at least one of the containers will not be close to the normal to its surface, which will ensure the effective action of the plates of this container moving under the influence of its explosion on the cumulative a jet or kinetic projectile in a wide range of directions of shelling of the protected obstacle.

 In addition, the pairwise placement of containers in this device and their connection into a single detonation circuit ensures the operation (explosion) of both containers when a cumulative jet or kinetic projectile hits at least one of them. The transfer of detonation from one container to another is carried out by a shock wave, without the use of any additional devices. In this case, the container plates moving towards each other collide. At angles of 10-40 degrees. the collision of the plates can be accompanied by the formation of a high-speed secondary cumulative flow of dispersed particles and a low-speed compact body; at other angles, the collision of these plates is accompanied by the formation of a low-speed compact body. In all these cases, the direction of movement of the cumulative flow and the compact body in the cavity between the containers is close to the bisector of the angle between them.

 The secondary cumulative flow and the compact body must move along the protected barrier, so that they can be affected by the means of destruction in the entire range of probable angles of fire of the protected barrier.

 The plates of the containers moving in opposite directions collide with the walls of the housing of the device and set them in motion with a reduced speed after impact, but with increased mass due to the addition of the mass of the walls of the body to the mass of plates of containers. Together, they have a destructive effect on the tail sections of the cumulative jet, which have a lower speed but a larger diameter in comparison with its head sections. Thus, the mass of the material crossing the trajectory of the cumulative jet in the course of its movement increases, which provides a more effective destructive effect on the middle and tail sections of the cumulative jet, which have a lower speed but a larger diameter (mass) in comparison with its head sections.

 Such a constructive implementation increases the efficiency of the device on the cumulative jet or kinetic projectile and extends the range of angles of fire of the obstacle, in which the proposed device is able to effectively act on the cumulative jet or kinetic projectile.

 To ensure these conditions, it is necessary that between the containers in each pair a spacer element is installed that interacts with each of these containers.

 It is advisable that each spacer element is in the form of a bracket. Such a structural embodiment of the spacer element is easy to manufacture and makes it easy to vary the dimensions of the angle between the containers in pairs.

 It is desirable to place at least one elastic element between one of the walls of the housing and one of the containers of each pair on the side of its surface, the opposite surface of this container, interacting with the spacer element.

 The presence of an elastic element allows the containers to be fixed in the required position and excludes the movement of containers in the housing and, therefore, protects them from external mechanical influences.

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 an apparatus for protecting an obstacle from shells made in accordance with the invention;
FIG. 2, an apparatus for protecting an obstacle from shells, made according to the invention, using a spacer element;
FIG. 3 embodiment of the proposed device with two pairs of containers and using another structural embodiment of the spacer element;
FIG. 4 installation on a protected barrier of several devices made according to the invention, in two variants of structural execution.

 A device for protecting an obstacle from shells, made according to the invention, comprises a housing 1 (FIG. 1), in which at least one pair of containers 2 and 3 are placed, made three-layer with a middle layer of explosive. Containers 2, 3 form in each pair a single detonation chain, and the connection of containers 2, 3 into a single detonation chain is carried out functionally, without the use of any additional devices. The containers 2, 3 are installed in the housing 1 so that the surfaces 4 and 5 of the containers 2 and 3 facing each other, respectively, in each pair form an acute angle in a plane perpendicular to these surfaces 4, 5, the apex of which is directed towards one of the side the walls of the housing 1. In each pair, the containers 2, 3 (Fig. 2) are in contact with each other, which extends the range of the angle of fire of the obstacle 7, at which the described device is able to effectively act on a cumulative jet or kinetic projectile. To ensure the preloading of the containers 2, 3 in each pair between them there is a spacer element 9, which interacts with each of the containers 2, 3. The spacer element 9 may have a different design. In FIG. 2 shows an embodiment of a spacer element 9 in the form of a bracket, which makes it easy to vary the dimensions of the acute angle between the containers 2, 3.

 One of the walls 10 of the housing 1, located between the containers 2, 3 and the protected barrier 7, is installed at a distance from this barrier 7. Between the wall 10 and the container 3 are installed elastic elements 11 (the minimum number of which is one), which protect the containers 2, 3 from external mechanical influences, with the container 3 located parallel to the wall 10. The housing 1 may have a different design, depending on the required conditions for protecting the barrier 7. So in FIG. 3 shows an embodiment of the proposed device used to protect the barrier 7 from kinetic shells. To protect the barrier 7 from the cumulative jet, various structural variants of the proposed device are used, shown in FIG. 4.

 The work of the proposed device is as follows.

 When, for example, a cumulative projectile hits the front wall 8 (Fig. 2) of the housing 1, its fuse is cocked, the explosive charge of the projectile is blown up, and a cumulative jet is formed; striking the container 2, it initiates an explosive in this container 2. The detonation wave propagating through the explosive of the container 2 reaches the edge of the container 2 closest to the edge of the container 3. In the form of a shock wave, it passes from the container body 2 to the container body 3, and then into the explosive of this container 3, initiating its detonation. The metal plates of containers 2 and 3 under the action of the explosion move in a direction close to the normal to the surface of the corresponding container 2, 3. At the same time, they begin to have a destructive effect on the head sections of the cumulative jet, which have a high speed but small diameter. In the process of further movement, one of the metal plates of the container 2, moving in the direction of the front wall 8 of the housing 1, collides with this wall 8 and sets it in motion. The metal plate of the container 3, moving in the direction of the wall 10, installed at a distance from the protected barrier 7, collides with this wall 10 and sets it in motion. The plate of the container 2, moving together with the wall 8 of the housing 1, and the plate of the container 3, moving together with the wall 10 of the housing 1, with a reduced speed after impact, but with an increased mass due to the connection of the masses of the containers 2, 3 to the mass of the walls 8, 10 buildings 1, have a destructive effect on the tail sections of the cumulative stream, which have a lower speed but a larger diameter compared to its head sections. Thus, the mass of the material crossing the trajectory of the cumulative jet in the course of its movement increases, which provides a more effective destructive effect on the middle and tail sections of the cumulative jet, which have a lower speed but a larger diameter (mass) in comparison with its head sections. To realize this important property of the device, containers 2, 3 must be placed in the housing 1 so that one of the plates of the container 2 can engage the front wall 8 in motion, and one of the plates of the container 3 the wall 10 of the housing 1.

 In addition, one of the metal plates of the container 2, moving in the direction of the container 3, collides with the metal plate of the container 3, moving towards it. The collision zone of these plates is close to the bisector of the angle between containers 2 and 3. Depending on the angle between the containers 2, 3 and the speed of movement of the plates of containers 2, 3, the result of the collision of the metal plates of these containers 2, 3 may be different. At impact angles of 10–40 degrees, the impact of the plates can be accompanied by the formation of a high-speed secondary cumulative flow of dispersed particles and a low-speed compact body; at other angles, the impact of these plates is accompanied by the formation of a low-speed compact body. A similar result is achieved when the plates of containers 2, 3 collide with the walls 8, 10 of the housing 1 at an angle. In all these cases, the direction of movement of the cumulative flow and the compact body in the cavity between the containers 2, 3 is close to the bisector of the angle between them. The secondary cumulative flow and the compact body must move along the protected barrier 7, so that they can be affected by the means of destruction in the entire range of probable angles of fire of the protected barrier 7. The products of the impact of the plates should create a kind of moving curtain along the surface of the protected barrier 7. The ideal case would be movement the cumulative flow and the compact body parallel to the surface 6 of the protected barrier 7. In the real case, they should move in such a direction that 6 CECA surface perimeter barrier 7 at least within the space defined by the pair of containers 2, 3, triggered when hit by a cumulative destruction means. The presence of this property of the proposed device reduces the dependence of the destructive effect exerted on the weapon, from the angle of its meeting with the proposed device. Hence. containers 2, 3 in the housing 1 of the proposed device should be installed so that a high-speed secondary cumulative flow of dispersed particles and a low-speed compact body formed upon impact of the plates of containers 2, 3 facing each other move along the surface 6 of the protected barrier 7.

 Thus, the placement of containers 2, 3 in the housing 1 of the proposed device should correspond to that shown in FIG. fourteen.

 Detonation of explosives in containers 2, 3 of the proposed device drives the material of the construction of this device (metal plates of containers 2 and 3, walls 8 and 10 of the housing 1) in three or four different directions, which reduces the dependence of the destructive effect of the inert material in the proposed device on a cumulative stream, from the direction of shelling of the protected barrier 7 (that is, from the angle of the meeting with the device). In addition, in the process of functioning of this device, an increase in the mass of moving material occurs, which has a destructive effect on the cumulative stream. As a result, the degree of security of the barrier 7 increases.

 The operation of another embodiment of the device shown in FIG. 3, as well as in the case of a kinetic projectile, for example, armor-piercing projectile projectile, is basically carried out similarly to the above, but it must be borne in mind that for an effective effect on the kinetic projectile moving material during the operation of the device should be 2-10 times greater than for a cumulative jet.

 The design parameters of the proposed device is largely determined by the characteristics of the containers 2 and 3, placed inside this device. The installation angle of one of these containers, for example container 2, with respect to the front wall 8 of the housing 1 is determined from the existing restrictions on the overall dimensions of this device, taking into account the desired result of the impact of the plates of containers 2, 3 and the range of angles of fire in which it is necessary to provide the greatest degree of protection barriers 7. The distance from the protected barrier 7, on which the wall 10 of the housing 1 is installed, is determined by the time during which it is necessary to ensure the functioning of this device Twa (this time depends on the length and speed of the cumulative jet or kinetic projectile, as well as the angle of their meeting with the proposed device). The most effectively proposed device to use as part of a set of reactive armor, which is installed on armored ground objects: tanks, infantry fighting vehicles, armored personnel carriers, self-propelled guns, building structures, vehicles, as well as on river and sea vessels.

Claims (4)

 1. Device for protecting barriers from shells, comprising a housing in which at least one pair of containers is installed, each of which is made three-layer with a middle layer of explosive, characterized in that each pair of containers forms a single detonation chain, and its containers are installed so that in a plane perpendicular to the container surfaces facing each other, these surfaces form an acute angle, the apex of each is directed towards one of the side walls of the housing.  2. The device according to claim 1, characterized in that between the containers in each pair a spacer element is installed, interacting with each of these containers.  3. The device according to claim 2, characterized in that the spacer element is made in the form of a bracket.  4. The device according to claim 2 or 3, characterized in that at least one elastic element is placed between one of the walls of the housing and one of the containers of each pair on the side of its surface, the opposite surface of this container, interacting with the spacer element.

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