RU2738401C1 - Cluster ammunition - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to military equipment, in particular to cluster ammunition equipped with a volumetric-detonating, incendiary or smoke mixture and intended for engagement of enemy manpower and equipment, as well as smoke masking of troops and objects and dazzle enemy. In the ammunition used is a capsule, which body is filled with a volume-detonating mixture, in flight, the ammunition stabilization occurs due to empennage, distribution of fuel-air mixture at approach to target - due to actuation of dispersive charge, simultaneous detonation by initiating charges is provided. Cluster ammunition consists of two inserted one into another cylindrical barrels with covers, with blow-out charges, electric cup of the introduced cylindrical barrel and ammunition coaxially fixed to it in an inner cylindrical cup, a blowout charge with an impact mechanism is located inside the inner sleeve, exhaust cord in space between two cylindrical cups in container is fixed by one end to outer cylindrical barrel, and by the other to impact mechanism of the knockout charge of the inner cylindrical barrel. Ammunition is intended for target destruction. It is a fired artillery round projecting about a longitudinal axis in flight. Ammunition consists of capsule filled with fuel-and-air mixture, fuse, dispersing charge initiating charges.

EFFECT: invention can be used for fire extinguishing, destruction of ice congestion and ice on narrow sections of rivers during ice drift.

1 cl, 4 dwg

Description

The invention relates to the field of military technology, in particular to cluster munitions equipped with a volume-detonating, incendiary or smoke mixture and intended to defeat enemy personnel and equipment, as well as smoke masking of troops and objects and blind the enemy. It is possible to use the invention for extinguishing fires, destroying ice jams and jamming in narrow river sections during ice drift

The ammunition cassette consists of two cylindrical cups with lids inserted one into the other. An expelling charge and a block are located inside the outer glass. The block consists of an inner glass and includes: a feathered ammunition, an expelling charge with a percussion mechanism, a lanyard.

As part of the ammunition, a capsule is used, the body of which is filled with a volume-detonating (smoke) mixture; in flight, the stabilization of the ammunition occurs due to the plumage, the spread of the air-fuel mixture when approaching the target due to the operation of a dispersing (bursting) charge, providing simultaneous detonation with initiating charges (a block of tablets ).

In addition, this ammunition provides for the versatility of its use, for which an on-board computer is additionally included in the on-board equipment of an aircraft (AC), and if it is available, additional programs for executing commands for the use of the proposed ammunition, depending on the method of use: to defeat and blind enemy personnel and equipment, as well as smoke masking of troops and objects, extinguishing fires, destroying congestion and ice clogs in narrow sections of rivers during ice drift

There is a method of increasing the effectiveness of hitting targets with a volumetric detonating ammunition (hereinafter - ODB) as a rocket, the warhead of which is formed by a single-cycle volumetric detonating mixture, placed in a thin-walled body and equipped with a fuse and a block to delay its operation, installed in the bottom of the body (see. Ammunition with a volume-detonating mixture. Patent for invention of the Russian Federation No. 2191983, IPC 7 F42B 15/00). Open edition. The well-known technical solution allows you to hit the enemy's manpower located in cover, dugouts, pillboxes, etc. However, the main disadvantage of this design is that most of the fuel-air mixture is initiated before reaching the fuel concentration in the cloud, which ensures the completeness of the detonation process, i.e. part of the fuel is actually ballast, and also the fact that the fuel-air mixture located in one thin-walled body spreads in the atmosphere when the body is destroyed over a relatively small area, which reduces the damaging effect of the projectile.

Known invention patent RU 2429445: the technical solution of which is the use of several cassettes in the ODB, each case of which contains a fuel-air mixture, while the cassettes are interconnected by a wired communication line - a coupler so that when moving in the air, cassettes are the composition of the plumage scatters a certain distance, limited by the length of the wire communication line - the coupling, the propagation and subsequent detonation of the air-fuel mixture, released from the body of each cassette separately, occurs through the use of dispersing and initiating charges interconnected by moderators. (Prototype)

At the same time, the method of increasing the effectiveness of destruction of ODB targets is based on the fact that several cassettes are used in the ammunition, the hulls of which are filled with an air-fuel mixture. When the projectile is flying in the airspace of the cassette, due to the existing tail and the action of the aerodynamic air resistance on them, they scatter one relative to the other and are stabilized in flight at a distance limited by a wired communication line - a coupling. When the cassette bodies approach the target, dispersing charges are triggered, and the air-fuel mixture spreads in the air. After a time interval provided by the moderator, the initiating charges are simultaneously fired and the air-fuel mixture is undermined.

However, the use of a wire coupling line also depends on the flight path of the munition, the aerodynamic air resistance and on the simultaneous operation of dispersing charges, and the flight speed of the aircraft. It is always possible to twist these connecting lines, which will lead to an uncontrollable chaotic nature of the fall. In addition, there is no possibility of using ammunition in smoke equipment.

The objective of the present invention is to increase the effectiveness of the destruction of ODB targets by increasing the amount of the fuel-air mixture used and its uniform distribution in space over a much larger area and the possibility of using the ammunition with a smoke mixture to camouflage their troops and objects and blind the enemy, as well as the use of ammunition with incendiary mixture.

The technical solution consists in the fact that the proposed design of the cluster munition differs in that the ammunition contains a capsule, the body of which is filled with a volumetric detonating (smoke) mixture; in flight, the ammunition is stabilized due to the plumage, the spread of the air-fuel mixture upon approaching the target due to triggering by a dispersing (bursting) charge, providing simultaneous detonation with initiating charges (block of tablets). Cluster munition 1 consists of two cylindrical cups 2, 3 inserted into one another, with covers 4, 5 with expelling charges 6, 7, an electric capsule 8 of an outer cylindrical cup 2 and ammunition 9 fixed in an inner cylindrical cup 3 coaxially with it, expelling charge 7 s percussion mechanism 10, located inside the inner cup 3, a lanyard 11 in the space between two cylindrical cups 2, 3 in the container, fixed at one end to the outer cylindrical cup 2, and the other to the kick mechanism of the expelling charge 7 of the inner cylindrical cup 3. Ammunition 9 designed to hit the target. It is a feathered artillery shell that rotates around its longitudinal axis in flight. The ammunition 9 consists of a capsule 12 filled with a fuel-air mixture 13, a fuse 14, a dispersing (ignition-explosive) charge 15, and initiation charges 16 (Fig. 1).

In addition, this ammunition provides for the versatility of its application, for which the on-board computer 18 (Fig. 2) is additionally included in the on-board equipment of the aircraft (AC), and if available, additional programs for executing commands for the use of the proposed ammunition, depending on the method of use. The technical result of the proposed invention is to improve the effectiveness of the volume-detonating ammunition hitting targets located over large areas. The proposed method makes it possible to increase the effectiveness of the destruction of the volume-detonating ammunition targets located over large areas, due to a more uniform distribution of the places where the ammunition falls and the spread of the air-fuel mixture in the airspace.

The invention is illustrated: FIG. 1 - cluster munition, FIG. 2 - the departure of the inner cylindrical cup with ammunition from the outer one and the actuation of propelling charges, FIG. 3 - the departure of the ammunition from the inner cylindrical cup and the opening of the plumage, FIG. 4 is a diagram of the control of the high-speed rail system when using cluster munitions, FIG. 5 - the use of cluster munitions from a helicopter mining system.

FIG. 1 shows: 1 - cluster munition; 2, 3 - outer and inner cylindrical nozzles, respectively; 4, 5 - lids of the outer and inner cylindrical nozzles, respectively; 6, 7 - expelling charges; 8 - electrocapsule of the outer cylindrical glass; 9 - ammunition; 10 - impact mechanism located inside the inner glass; 11 - lanyard; 12 - ammunition capsule; 13 - air-fuel mixture; 14 - fuse; 15 - dispersing (ignition-explosive) charge; 16 - initiating charges; 17 - control panel for the high-speed rail system; 18 - on-board computer; 19 - aircraft sensors, 20 - right group of containers, 21 - left group of containers.

The claimed cluster munition operates as follows. After applying an electrical impulse to trigger the electric capsule 8 of the outer cylindrical glass 2, which ignites the expelling charge 6.

Under the influence of the propellant gases of the expelling charge 6 of the outer cylindrical cup 2, the inner cylindrical cup 3 is shot off with the ammunition 9 fixed in it and the cover of the outer cylindrical cup 4 is dropped (Fig. 2). At the same time, the time of action of the powder gases is chosen so that the housings are separated cluster munition 1 with an inner cylindrical glass 3, followed by its separation from the ammunition 9 located in it and their dispersion in air space occurred at the required distance and height above the target. In this case, the inner cylindrical cup 3, moving along the cassette 1, pulls the lanyard 11 and at the time of undocking from the case of the cluster munition 1, the fuse (not shown) is pulled out of the percussion mechanism 10 and it ignites the expelling charge 7 located in the upper part of the inner cylindrical cup and closed a cover (not shown) separating the ammunition 9 from the expelling charge 7. The propellant gases resulting from the combustion of the expelling charge penetrate through the holes in the cover and disperse the ammunition 9 along the container by the pressure of gases entering the space. Part of the gases enters the gap between the shell of the ammunition and the walls of the inner cylindrical cup, balancing the pressure of the ammunition equipment on the walls of the shell that arises during firing. The front cover of the inner cylindrical cup 5 is thrown off by the air pressure compressed between the shell and the cover, freeing the way for the release of the ammunition 9. In this case, the ammunition 9 receives a high initial velocity, obtained as a result of the initial acceleration of the first cluster munition 1, which includes the inner cylindrical cup 3 with ammunition 9, relative to the container, and then the ammunition 9 itself relative to the inner cylindrical cup 3. Then, when the ammunition 9 moves, the bodies of the inner cylindrical cup 3 and the ammunition 9 are disconnected and scattered in the air (Fig. 2). When the ammunition 9 moves in the air, the capsule of the ammunition 12 in flight, due to the plumage, acquires a rotational movement around its axis. The resulting high initial velocity ensures the accuracy of the ammunition hitting the target (Fig. 3).

When the ammunition 9 approaches the target, the fuse 14 is triggered, then the (dispersing ignition-explosive) charge 16, the air-fuel mixture 15 spreads in the air. After a time interval provided by 8, the initiating charges 16 are triggered and the fuel-air mixture 15 is detonated.

In flight, when equipped with cluster (volume-detonating, incendiary, smoke) munitions of containers of helicopter mining systems (HCM). During the flight, the operator, at the command of the helicopter commander, turns on the console and sets the control panel of the VSM 17 (Fig. 4) to manual or automatic mode, depending on the type of work performed and the types of ammunition used for this. In the automatic mode, data is received from sensors 19 (Fig. 4) of the aircraft onboard equipment about the speed, altitude, state of the atmosphere, etc. into the on-board computer 18. Based on these data, the on-board computer 18 calculates the sequence and time of supply of electrical impulses to cluster munitions. When approaching the target, the helicopter commander turns on the cluster munition discharge system. Computer 18 delivers electrical impulses at time intervals according to the calculated data.

In manual mode, the operator works with the control panel, the role of which is the helicopter flight technician. The operator, in accordance with the received task, sets the initial data on the control panel. Depending on the flight speed and the type of cluster munitions used, the intervals between the current pulses are provided. The intervals are set by the operator (flight technician). The control panel displays the number of installed cluster munitions, in addition, it provides control of the number of specified pulses and issued. Control of the left and right groups of containers 20 (Fig. 5) is separate, which makes it possible to place cluster munitions of various types in groups of containers and a different step for dropping cluster munitions.

Helicopter commander:

- brings the helicopter to the combat course and maintains the given altitude and flight speed,

- gives the command to the operator "Turn on the power of the ammunition dump control panel",

- upon reaching the start point of the ammunition discharge, he presses the button on his control stick and informs the crew “Start of ammunition discharge”. At this command, the navigator fixes the coordinates of the start of the discharge, the operator monitors the release of ammunition. When the kit is used up, informs the crew of the “End of the discharge” and gives the command to turn off the control panel.

Considering that when approaching the target, the cluster munition has a forward momentum provided by the aircraft movement and downward movement, the resulting direction of movement will determine the total momentum of these movements. Therefore, an increase in the speed of the downward movement of the ammunition and the use of feathered ammunition will provide a more accurate target hit, and the use of an on-board computer 18 will provide a more uniform distribution of cluster munitions over the target, taking into account the detonation of the fuse and the detonation of the initiating charge (Fig. 5).

The proposed method allows for a more uniform and extensive distribution of the required amount of the fuel-air mixture in the air space, intended for its subsequent detonation.

Claims (1)

The cluster munition consists of two cylindrical cups inserted one into the other with lids with expelling charges, an electric capsule of an outer cylindrical cup and an ammunition fixed in an inner cylindrical cup coaxially with it, an expelling charge with a percussion mechanism is located inside the inner cup, a lanyard in the space between two cylindrical cups fixed at one end to the outer cylindrical glass, and the other to the percussion mechanism of the expelling charge of the inner cylindrical glass, while the ammunition is a feathered artillery projectile rotating around the longitudinal axis in flight, consisting of a capsule filled with a fuel-air, smoke, incendiary mixture, a fuse, dispersing igniter-bursting charge, initiating charges.

Images