RU2744227C1 - Grenade launcher ammunition against unmanned aerial vehicles - Google Patents

Abstract

FIELD: military equipment.SUBSTANCE: invention relates namely to ammunition for grenade launchers. Ammunition for a grenade launcher against unmanned aerial vehicles contains a propelling and warhead, a combustion chamber housing, the outer surface of the tail of which is made under the barrel prechamber with a guaranteed minimum clearance, a leading belt, an annular groove, a propelling powder charge, a primer-igniter. A cartridge case with a propelling powder charge and a primer-igniter is attached to the rear wall of the shell of the ammunition, which has holes on both sides for the outlet of powder gases and ignition of the powder charge in the combustion chamber, separated from the warhead of the ammunition by an annular gasket. An adjustable diaphragm is located coaxially with the rear wall openings on the warhead side, structurally connected with a mechanical distance switch located in an annular groove outside the ammunition housing. The warhead of the ammunition is made of separate striking elements located inside the body of the ammunition and striking segments, which are fastened together by means of flexible elements that form a network. To ensure safety, compact placement and directional deployment of the net after firing, a protective metal cylindrical container is coaxially placed inside the shell of the ammunition. The front end of the container abuts against the striking segments of the warhead, and the other end against the rear wall of the ammunition body.EFFECT: increased effectiveness of hitting targets.2 cl, 4 dwg

Description

The invention relates to the military field, to ammunition for grenade launchers, under-barrel grenade launchers used as independent means of destruction, as well as machine guns fixed under the barrel (for example, Kalashnikov - AK, AK-74, etc.), is intended for remote destruction of UAVs, and can be used to solve problems of countering low-flying targets at low speed.

A unitary artillery cartridge is known, which contains a warhead, a leading belt, a combustion chamber body, the outer surface of the tail section of which is made under the barrel prechamber with a guaranteed minimum clearance, a propellant powder charge and a primer-igniter placed in the combustion chamber, characterized in that the warhead grenades and the combustion chamber housing are made of individual modules, and the front end of the combustion chamber housing is fastened to the bottom of the warhead, for example, with an adhesive composition with the possibility of separation when fired, while the side surface of the combustion chamber housing is made with a diameter equal to the diameter of the warhead housing and on its side surface an annular groove is made for a spring-loaded barrel lock, the combustion chamber is cylindrical with a taper at the front end, it contains a cylindrical metal rod with a diameter equal to the diameter of the taper, the front end of which rests against the bottom of the warhead, and a blank cartridge containing holding a liner, a primer-igniter and a propelling powder charge, between the propelling powder charge and a cylindrical metal rod there is a wad-piston with an obturating side surface and a recess on the side of the propelling powder charge, and in the tail part of the combustion chamber housing there is a cover with an external profile under the barrel prechamber , and at the bottom of which there is a transitional firing pin (RU No. 30964, MPK7 F42В 5/00, 10.07.2003, Bull. No. 19).

The disadvantages of the unitary artillery cartridge are:

- the implementation of the explosion of a grenade only after meeting with an obstacle or on a timer;

- the impossibility of delivering submunitions directly to the target during horizontal firing;

- defeat ground targets, enemy manpower, lack of ammunition to counter low-flying targets at low speed;

The basis of the invention is the task of improving the design of a unitary artillery cartridge and creating a unified ammunition to counteract low-flying targets at low speed with the delivery of striking segments and flexible elements forming a network directly to the target at a specified distance, protecting the elements of destruction from combustion products when fired.

The problem is solved by the fact that in the ammunition for the grenade launcher against unmanned aerial vehicles, containing the propellant and warhead, the combustion chamber body, the outer surface of the tail part of which is made under the barrel prechamber with a guaranteed minimum clearance, the leading belt, the annular groove, the propellant powder charge, the capsule - igniter, a cartridge case with a propelling powder charge and a primer-igniter is attached to the rear wall of the ammunition body, having holes on both sides for the release of powder gases and ignition of the powder charge in the combustion chamber, separated from the warhead of the ammunition by an annular gasket, and coaxially with the holes in the rear wall on the side of the warhead, an adjustable diaphragm is located, structurally connected with a mechanical distance switch located in an annular groove outside the shell of the ammunition, while the warhead of the ammunition is made of separate striking elements located inside the shell ammunition and striking segments, which are fastened together by means of flexible elements that form a network, and to ensure safety, compact placement and directional deployment of the network after a shot, a protective metal cylindrical container is coaxially placed inside the shell of the ammunition, while the front end of the container rests against the striking segments of the combat parts, and the other end into the rear wall of the ammunition body, while the ammunition may contain at least three striking segments and at least two rows of at least four striking elements to ensure the destruction of one or a group of unmanned aerial vehicles when fired from a grenade launcher.

Since a cartridge case with a propelling powder charge and a primer-igniter is attached to the rear wall of the ammunition body, which has holes on both sides for the outlet of powder gases and ignition of the powder charge in the combustion chamber, separated from the warhead of the ammunition by an annular gasket, and coaxially with the holes in the rear wall from the side the warhead is an adjustable diaphragm, structurally connected with a mechanical distance switch located in an annular groove outside the ammunition body, while the ammunition warhead is made of separate striking elements located inside the ammunition body and striking segments that are fastened together by means of flexible elements forming net, moreover, to ensure safety, compact placement and directional deployment of the net after firing, a protective metal cylindrical container is coaxially placed inside the shell of the ammunition, while the front end of the container rests against the destructive e segments of the warhead, and the other end into the rear wall of the ammunition body, and the ammunition may contain at least three striking segments and at least two rows of at least four striking elements to ensure the destruction of one or a group of unmanned aerial vehicles when fired from a grenade launcher, counteraction to low-flying targets at low speed with the delivery of striking segments and flexible elements that form a network, directly to the target at a specified distance, protecting the elements of destruction from combustion products when fired.

Figure 1 shows a structural diagram of an ammunition for a grenade launcher (General view - from the side); figure 2 shows the ammunition (sectional view - side) with the arrangement of structural elements; figure 3 schematically shows the process of triggering the ammunition to hit the target (sectional view - side); figure 4 - striking segments, which are fastened together by means of flexible elements that form a network in various versions.

Structurally, the ammunition consists (Fig. 1) of two components: the warhead 1 and the body of the ammunition 2. On the outer side surface of the body of the ammunition 2, the leading belt 3 and the annular groove 4 are made, in which the mechanical distance switch 5 is located structurally connected with the adjustable diaphragm 6 The body of ammunition 2 consists (figure 2) of a combustion chamber 7, the inner side surface of which is made with a diameter equal to the diameter of the body of the warhead 1 and the sleeve 13. The sleeve 13 itself contains holes 9 for the outlet of powder gases and a propelling powder charge 11. Combustion chamber 7 is formed by the space between the rear wall 8 of the ammunition body 2, the adjustable diaphragm 6 and the annular gasket 17, the propellant charge of the warhead 12 is placed in the chamber. The combustion chamber 7 communicates with the sleeve 13 with holes 10 for igniting the propellant charge 12 of the combustion chamber of the warhead. In the tail section of the ammunition, in the rear wall 8 of the ammunition body 2, there is a sleeve 13 with an external profile under the barrel prechamber with a guaranteed minimum clearance, and at the bottom of which there is a primer-igniter 14, and when the powder charge 12 is triggered, the annular gasket 17 provides the expulsion of the combat part 1, the exhaust of gases is carried out through the holes 10 to ignite the powder charge of the combustion chamber of the warhead. Inside the combustion chamber 7, a protective metal cylindrical container 15 is located inside which flexible elements 16 are located, forming a network, while the front end of the container abuts against the striking segments 19 of the warhead. The annular gasket 17 separates the powder charge 12 of the warhead 1 with individual striking elements 18, is made with an obturating, tight-fitting, lateral surface. The annular gasket is made with a central hole in which a protective metal container is located, while the gasket is installed with the ability to slide along the surface of the cylindrical container to push out the warhead 1.

To bring the ammunition into the firing position, it is necessary to set the mechanical distance switch 5 (Fig. 1) to the required position of the appropriate height from 50 to 100 meters (having previously estimated the distance to one or more unmanned aerial vehicles. Next, the ammunition is installed from the muzzle end of the barrel and an under-barrel grenade launcher, based on the protrusions of the leading band 3 in the inclined grooves of the barrel and is fixed with a retainer in the breech of the barrel by means of an annular groove 4.

The operation of the ammunition is illustrated in figure 3 when one or more unmanned aerial vehicles are damaged. When fired, the drummer of the grenade launcher interacts with the primer-igniter 14. The impulse from the primer-igniter 14 ignites the propellant charge 11. Subsequently, thanks to the protrusions of the leading belt 3, the ammunition accelerates and swirls. The propellant gases exit through the holes 9. The ammunition receives a translational and rotational movement in the barrel of the weapon, and then, when it leaves it, it moves along a given trajectory.

Subsequently, the propelling powder charge 11, which is connected to the combustion chamber 7, ignites the powder charge 12 of the warhead through the holes 10 to ignite the powder charge of the combustion chamber of the warhead, while the annular gasket 17 is pushed out, which slides over the surface of the cylindrical container and pushes out individual striking elements 18, as well as striking segments 19, which, by untwisting and fastening together by means of flexible elements 16, form a network (Fig. 4). Execution of ammunition with at least three striking segments 19 and with at least two rows of at least four striking elements 18 after firing ensures their significant expansion in area, the formation of a network and the defeat of one or more unmanned aerial vehicles.

Thus, the proposed ammunition for a grenade launcher, in comparison with the prototype and other technical solutions of a similar purpose, allows solving the problem of countering low-flying targets (50-100 meters) at low speed, hitting or immobilizing them with individual striking elements, as well as striking segments with flexible elements forming network.

This design solution based on the above provides the following advantages:

- unification for VOG-25 ammunition allows you to reduce the cost of deployment in the troops, due to adaptation to the use of standard weapons;

- lack of analogs of ammunition used to counter low-flying targets at low speed;

- the effect of the accuracy of hitting the target is achieved by twisting the ammunition by means of the leading belt;

- remote destruction of unmanned aerial vehicles is carried out not only by a deployable network with striking segments fixed on it, but also by individual striking elements;

- remote destruction of unmanned aerial vehicles is carried out at a specified distance, due to the difference in the opening of the diaphragm, which allows directly delivering elements and segments of the defeat to the target;

- Structurally, the mesh is protected from combustion products by means of a protective metal cylindrical container;

- additional training is not required for firing ammunition.

Claims (2)

1. Ammunition for a grenade launcher against unmanned aerial vehicles, containing a propellant and warhead, a combustion chamber body, the outer surface of the tail section of which is made under the barrel prechamber with a guaranteed minimum clearance, a leading belt, an annular groove, a propelling powder charge, a primer-igniter, characterized by that a cartridge case with a propelling powder charge and a primer-igniter is attached to the rear wall of the ammunition housing, having holes on both sides for the outlet of powder gases and ignition of the powder charge in the combustion chamber separated from the warhead of the ammunition by an annular gasket, and coaxially with the holes in the rear wall with the side of the warhead is an adjustable diaphragm, structurally connected with a mechanical distance switch located in an annular groove outside the ammunition body, while the warhead of the ammunition is made of separate striking elements located inside the ammunition body and the time pressing segments, which are fastened together by means of flexible elements that form a network, and to ensure safety, compact placement and directional deployment of the network after a shot, a protective metal cylindrical container is coaxially placed inside the ammunition body, while the front end of the container rests on the striking segments of the warhead, and the other end is in the rear wall of the ammunition housing. 2. Ammunition according to claim 1, characterized in that it contains at least three striking segments and at least two rows of at least four striking elements to ensure the destruction of one or a group of unmanned aerial vehicles when fired from a grenade launcher.

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