RU2339898C2 - "inrog" vehicle self-defense system - Google Patents

Abstract

FIELD: armament.

SUBSTANCE: proposed system comprises a launching container anti-shells provided with war-heads, the said container being mounted on the rotary base and furnished with a vertical guidance mechanism, a radar to detect an enemy shell and to measure its trajectory parameters, a driven sighting system. Every anti-shell incorporates a trajectory initiated time-set or proximity fuse with detonator arranged at its bottom. The war-head contains charge of explosive with a splinter unit arranged on its front part and representing a set of injurious elements with a shape allowing their dense arrangement. The anti-shell rear accommodates a solid-propellant jet engine and a folded fin. The launching container barrels incorporate the devices designed to send electromagnetic signals into the fuse. The anti-shell outer surface accommodates the electromagnetic signal receivers isolated from the shell casing and connected to the base fuse.

EFFECT: reliable anti-shell protection.

14 cl, 4 dwg

Description

The invention relates to self-defense systems of vehicles, mainly tanks, against attacking shells, mainly anti-tank guided missiles and anti-tank grenades. Typically, these systems contain a fragmentation anti-projectile thrown towards the attacking shell and hit it with a circular or directed fragmentation field. These systems are also often referred to as active protection systems (CAS). Famous domestic SAZ "Arena" (Kolomenskoye Design Bureau of Mechanical Engineering), "Drozd" (Tula Design Bureau of Instrumentation), SPATEM (French company GIAT) and many others.

As a prototype of the claimed invention adopted self-defense system according to patent No. 56661254 USA, declared by the German company "Diehl" 01/21/97. Unlike the SAZ Arena, it provides for the interception of attacking shells over long distances. Attack breakdown can be achieved in one of two ways:

- defeat of the control system, leading to the passage of the projectile past the target (applicable for all types of warheads);

- defeat (destruction) of the warhead (applicable for cumulative warheads).

In close-range interception systems, only the second method is possible, because damage to the control system at short distances from the protected object does not result in a miss. Meanwhile, guided projectiles with armor-piercing cores, such as the US X-ROD tank projectile, which can only be hit in the first way, which, in turn, requires a long interception range, are being intensively developed.

The self-defense system contains a launch container with anti-shells mounted on a rotating base and equipped with a vertical guidance mechanism, a radar station for detecting and measuring the trajectory parameters of the attacking projectile, an aiming system with a drive, and anti-shells contain a head trajectory fuse of a temporary or non-contact type, fragmentation warhead containing a charge explosive (BB), a fragmentation block located between the head fuse and the explosive charge and the bottom detonator, and in the backside its parts are a solid fuel jet engine and a drop down stabilizer.

The main disadvantage of the system is the location of the trajectory fuse of the projectile in front of the fragmentation unit, and, as a result, the decrease in the effectiveness of the action. As shown in a number of works (see, for example, the article by V.A. Odintsov, “Directional Shrapnel Flows,” “Technique and Armament,” No. 9, 2000, p. 26), the location of the fuse in front of the unit leads, on the one hand, to a decrease in the speed of throwing due to an increase in the total throwing mass, and on the other hand, to an upset of axial flow with the loss of a significant part of the finished striking elements.

Another, less significant drawback of the anti-projectile design is the placement of the feather stabilizer inside the shell of the projectile, which leads to a decrease in the volume of the jet engine, and, consequently, to a decrease in the speed reported by it. The low acceleration rate of the anti-projectile will be additionally due to the absence of a propellant powder charge in the barrel (the so-called "active" charge) in the system. The fragmentation block is made in bulk from spherical prefabricated damaging elements (GGE), which leads to severe plastic deformation of the GGE during explosive loading, significant energy consumption for this deformation and, as a consequence, to a decrease in the GGE speed. It should also be noted that the description does not specify the method of introducing the installation into the head fuse.

The present invention addresses these drawbacks. The technical solution is that:

- the anti-projectile fuse is transferred to its bottom and combined with the detonator;

- feather stabilizer with flat feathers recessed in the shell of the projectile is replaced with a stabilizer containing stabilizer blades made in the form of parts of a cylindrical surface, the axis of rotation of which are located along the generatrix of the housing;

- in the rear part of the anti-projectile is a propellant powder charge with a means of ignition;

- the finished striking elements of the fragmentation block are made in a shape that ensures their tight packing, for example, in the form of a cube or a hexagonal prism;

- the launch container trunks are equipped with contactless input devices, for example, inductors located in planes passing through the bottom fuses of the anti-projectiles, and on the outer surface of the anti-shells there are electromagnetic signal receivers isolated from the anti-projectile casing and connected to the bottom fuses.

The invention is illustrated by drawings: figure 1 - self-defense system mounted on a tank; figure 2 is a longitudinal section of the barrel of the launch container placed with an anti-projectile; figure 3 - General diagram of the anti-projectile; 4 is a diagram of the action of a self-defense system.

The general layout of the tank’s self-defense system is shown in FIG. The system comprises a launch container 1 mounted on a rotating base 2 and equipped with a vertical guidance mechanism 3 and, in general, a failure brake and a knurling device (shown as a single unit 4), a radar station 5 for detecting and measuring trajectory parameters of an attacking projectile with antenna 6, an aiming system with drive.

In the diagram of Fig. 1, the launch container is mounted on the tank tower in a single unit with a large-caliber anti-aircraft machine gun 7 and its magazine 8. Other options for placing the launch container and the machine gun are also provided. The launch container is made in the form of a set of trunks 9 (figure 2) containing anti-shells 10 (figure 1 is shown after departure from the container). The trunks have a closed rear end. At the rear of each barrel there is a propellant (starting) powder charge 11 installed either at the rear end of the anti-projectile or at the rear of the barrel with ignition means 12. Inductors are installed on the surface of the trunks, for example, in the form of inductive coils 13, while the inductors are located in planes passing through anti-projectile fuses.

The anti-projectile shown in Fig. 3 contains a head cap 14, a housing 15 with a charge of explosives 16 and a bottom trajectory electronic fuse 17 with a detonator 18. A fragmentation unit 19 is adjacent to the front end of the charge of explosives 19. An electromagnetic signal receiver 20 is insulated on the outer surface of the anti-missile 20 from the anti-projectile housing and connected to the fuse.

In the rear part of the anti-projectile there is a solid fuel jet engine 21 and a drop down stabilizer 22, the blades of which are made in the form of parts of a cylindrical surface, the axis of rotation of which are located along the generatrix of the housing. Throwing (starting) powder charge 11 with ignition means 12 in this embodiment is installed in the annular space between the engine and the anti-projectile housing. The fragmentation block of the anti-projectile is made in the form of a single-layer or multi-layer set of ready-made striking elements (GGE) made of steel or heavy alloys based on tungsten or tantalum, in a shape that ensures their tight packing in the block, for example, in the form of a cube or a hexagonal prism.

To implement firing with a shock gap, the anti-projectile fuse can be equipped with a contact (shock) action mechanism. In this case, the part of the body that is in contact with the explosive charge can be made with predetermined crushing or contain ready-made damaging elements.

The action of the system (figure 4) is as follows. The radar station detects the attacking shell and measures its trajectory parameters, the aiming system directs the launch container at the attacking shell and determines the moment of launch of the anti-projectile, and in the case of the use of a temporary fuse, introduces a temporary installation into it. The anti-projectile is ejected from the barrel of the launch container by a powder propellant charge. Closed trunk pattern allows you to get a fairly high initial speed. The absorption of the recoil is produced by the recoil brake. Further acceleration of the anti-projectile is carried out by its jet engine.

Detonation of the anti-projectile at a given distance U from the attacking projectile can be realized either with the help of a proximity fuse such as a rangefinder, or with the help of a temporary fuse. A non-contact fuse provides a smaller scatter of the distance U, but it is subject to the effects of signals reflected from the surface of the earth and, on the other hand, to electronic countermeasures during a flat trajectory. The anti-projectile with a temporary fuse is more reliable. The optimal value of the distance U is calculated according to the condition of the maximum likelihood of an anti-projectile strike by a GGE beam (see V.A. Odintsov, “Axial Action Designs,” Publishing House of Bauman Moscow State Technical University, 1995).

As already mentioned above, the proposed SAZ can include a tank anti-aircraft machine gun, and, under certain conditions, a course machine gun. Their action is synchronized by a special system. In the simplest scheme, the anti-aircraft machine gun is rigidly mounted on the launch container. The disadvantage of this scheme is the impossibility of simultaneously combating an attacking shell and an air target. In another embodiment, the launch container and the anti-aircraft machine gun are installed on different bases and have separate drives.

The following is a variant of the design characteristics of the system:

Total weight kg 400 Number of trunks 8 Caliber anti-projectile, mm 80 Anti-projectile mass, kg 3,5 Speed at the end of the active section, m / s 250 Maximum interception range, m 300 GGE block weight, kg 1,0 The mass of one GGE, g 2 The number of GGE in the block 500 Detonation range from the attacking shell, m 10 The radius of the affected circle, m 1,0 The average density of the GGE in the affected circle, 1 / m ² 160 Frontal area of the attacking projectile (ATGM TOW USA, diameter 152 mm), m ² 0.018 The number of GGEs falling into the frontal area ~ 3

The system can also be used to combat various ground tank-dangerous targets, for example, RPG calculations, etc. In this case, firing can be carried out both with installation on the trajectory gap (the action of the axial field of the GGE), and with installation on the shock gap (the action of the circular field of fragments of the shell).

The advantage of a self-defense system based on the use of fragmentation-beam anti-shells will be especially pronounced when there are fragmentation-beam shells in the tank gun’s ammunition (see, for example, Pat. No. 2018779 of the Russian Federation, article by V.A. Odintsov “New projectile for tanks”, "Military Parade", November-December 1996, p. 50), since in this case a general high-precision trajectory blasting system can be used.

Claims (14)

1. Vehicle self-defense system, comprising a launch container with barrels with anti-shells with a warhead mounted on a rotating base and equipped with a vertical guidance mechanism, a radar for detecting and measuring trajectory parameters of an attacking projectile, an aiming system with a drive, characterized in that each anti-projectile contains a temporary or non-contact trajectory fuse located in its bottom with a detonator, the warhead contains an explosive charge a solid-fuel fragment, at the front end of which there is a fragmentation block made in the form of a set of ready-made striking elements with a shape that ensures their tight packing, in the rear part of the anti-projectile there is a solid fuel rocket engine and a swinging stabilizer, and the launch container trunks are equipped with devices for contactless input of electromagnetic signal installations into fuse, located in planes passing through the bottom fuses of anti-shells, and on the outer surface of the anti-shells mounted electromagnetic receivers th signal isolated from the housing and connected to antisnaryada bottom fuses. 2. The system according to claim 1, characterized in that the fragmentation anti-projectile block is made in the form of a multilayer or single-layer set of ready-made striking elements made of steel or heavy alloys based on tungsten or tantalum. 3. The system according to claim 2, characterized in that the finished striking elements are made in the form of a cube or a hexagonal prism. 4. The system according to claim 1, characterized in that the anti-projectile is equipped with a thin-walled head cap. 5. The system according to claim 1, characterized in that the launch container is made in the form of a set of trunks having a closed rear end. 6. The system according to claim 5, characterized in that a propellant powder charge with a means of ignition is placed in the rear of the barrel. 7. The system according to claim 5, characterized in that the launch container is made with a rollback brake and a recuperator. 8. The system according to claim 1, characterized in that the trunks of the launch container are made in the form of a set of pipes open on both sides. 9. The system according to any one of paragraphs.5 or 8, characterized in that the contactless input devices of the electromagnetic signal into the fuse are made in the form of inductors. 10. The system according to claim 1, characterized in that the launch container with the base is located on the roof of the tower of the vehicle, mainly the tank. 11. The system according to claim 1, characterized in that the launch container is made in a single unit with an anti-aircraft machine gun. 12. The system according to claim 1, characterized in that the anti-projectile fuse is additionally equipped with a contact action mechanism. 13. The system according to claim 1, characterized in that the part of the body in contact with the explosive charge is made with predetermined crushing or contains ready-made damaging elements. 14. The system of claim 10, characterized in that the elements in the trajectory fuse of a temporary type of anti-projectile are the same as the system of trajectory detonation of the shells of a tank gun.

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