RU2688654C2 - Grenade to hand grenade launcher - Google Patents

Abstract

FIELD: weapons.SUBSTANCE: invention relates to ammunition and, in particular, to fragmentation grenades of hand grenade launchers and can be used in creation of ammunition. Grenade comprises cassette warhead with fragmentation subprojectiles. Grenade rear end accommodates solid-propellant rocket engine. It includes cylindrical housing with charge of solid fuel and nozzle. Trajectory fuse is installed in the middle part. In front part there is a combat part in the form of a set of fragmentation subprojectiles or propellant units. Each of them contains detonating fuse. Pyrotechnical separation charge is arranged between trajectory fuse and set of subshells. Set of subprojectiles is located in the cylindrical casing with the nose fairing. Said housing is detachable from rocket engine to discharge subprojectiles under action of independent blow-out powder charges. Subshells feature spherical shape. At that, the combat part is made over-caliber or caliber. Subprojectiles cylindrical housing is configured to eject subprojectiles along grenade longitudinal axis into both sides, wherein head fairing is hingedly connected to said housing, is configured to turn about its axis of rotation through angle of 180°, fixation in the specified position and undocking with the cylindrical body at approach of the grenade to the design point; at that, the grenade itself at its translational movement is provided with possibility of rotary movement.EFFECT: technical result is higher effectiveness of grenade combat due to increased area of damage.8 cl, 3 dwg

Description

The invention relates to ammunition, namely: to frag grenades of hand grenade launchers and can be used to create ammunition.

A full-time OG-7 fragmentation grenade with a shock fuse to an RPG-7 anti-tank grenade launcher is known. With a rupture on the surface of the earth, most of the fragments go into the ground and the upper hemisphere, moreover, the grenade is not capable of hitting targets in the trenches. [A.A. Catch, V.V. Korenkov, V.M. Bazilevich, V.V. Korablin. Domestic anti-tank grenade launchers. Infantry weapon of Russia, 2001].

Known cassette frag-beam nadkalibernaya grenade "Tverperiska" with submunitions air gap, creating an elongated field of destruction, compensating for the error of the break point in range. The grenade contains a cluster warhead with fragmentation submunitions, a jet engine in the rear part of the grenade, an axially located warhead in the form of a set of fragmentation submunitions (throwing blocks) in the front part of the grenade made in the form of low cylinders, each of which contains a decelerating fuse, located between the engine and a set of submunitions, a trajectory fuse in the middle part of the grenade and a pyrotechnic separation charge between an interdirector fuse and a set of submunitions (RF Patent No. 2362962, IPC: F42 B 12/02, F42B 12/32, F42B 12/58, F42B 12/62).

Among the disadvantages of this grenade, in the first place, is the non-optimal form of submunitions that does not provide an isotropic fragmentation field. When fragments fly apart, dead zones will form between the axial flows of the finished destructive elements (GGE) and the circular fields of the shell fragments and, in general, ensuring a stable flight of submunitions in the form of flat disks is associated with serious difficulties. All this makes it difficult to obtain a stable configuration of the affected area on the ground.

Known grenade to a hand-held grenade launcher containing a cluster warhead with fragmentation submunitions, a jet engine mounted in the rear of the grenade, in the middle part a trajectory fuse, in the front part a warhead in the form of a set of fragmentation submunitions (missile blocks), each of which contains a fuse with a delay, while between the trajectory fuse and a set of submunitions a pyrotechnic separation charge is located, while the set of submunitions is located in a cylindrical body, the body is made separate From the jet engine with the possibility of successive ejection of submunitions from the hull back (against the direction of movement of the grenade) under the action of autonomous expelling powder charges, submarines have a spherical shape, the warhead can be made both above-caliber and caliber (RF Patent No. 2510484, Application No. 2012158045 12/28/2012, IPC: F42B 12/02, F42B 12/32, F42B 12/58, F42B 12/62 - prototype).

The main disadvantage is not sufficiently high efficiency of action, due to the axial expansion of the submunitions from the calculated point of the trajectory of the undermining of the grenade.

The objective of the invention is to eliminate these disadvantages and the creation of a grenade with the expansion of submunitions in different directions from the calculated point of the trajectory of the undermining of a grenade in order to increase the area of destruction.

The solution of this task is achieved by the fact that in the proposed grenade to a hand-held grenade launcher containing a cluster warhead with fragmentation submunitions, a solid-fuel rocket engine installed in the rear of the grenade, including a body with a solid fuel charge and a nozzle, in the middle part is a trajectory fuse, the front part - the warhead in the form of a set of fragmentation submunitions / propelling blocks, each of which contains a decelerating fuse, with pi being located between the trajectory fuse and the set of submunitions. an otehnical separation charge, with a set of submunitions located in a cylindrical body with a head fairing, and the said body is detachable from the rocket engine with the ability to eject submunitions under the action of autonomous expelling powder charges, and the subunits have a spherical shape, while the warhead can be made as over-caliber , and caliber, according to the invention, the said cylindrical body of submunitions made with the possibility of ejection of submunitions along the longitudinal axis of the body g wound in both directions, with the head fairing pivotally connected to the specified body and made with the possibility of turning around its axis of rotation through an angle of 180 ° and fixing in a predetermined position.

The invention is illustrated by the drawings, where in FIG. 1 shows a general view of a grenade; in fig. 2 is a longitudinal section of the front of the grenade; FIG. 3 - execution of sub equipment.

The grenade contains a rocket engine of solid fuel 1 with stabilizer feathers 2 fixed on it, a trajectory fuse 3 and a cluster warhead 4 attached to it, filled with sub-shells 5.

The trajectory fuse 3 contains a powder charge 6 of the warhead compartment and a contactless receiver of the installations 7. A cylindrical body 9 of the cassette warhead is attached to the fuse using thread 8. The body contains a set of spherical sub-shells 5, separated by diaphragms 10. The body of the warhead, the diaphragms and the bottom are made of high-strength carbon plastic. In the annular grooves of the diaphragms are placed autonomous powder charges 11 for shooting submunitions with autonomous igniter blocks 12. The igniter block contains an inertial launch sensor, a retarder with a different deceleration time for each subarm and an igniter. The bottom 13 adjoins the set of submunitions. The front part of the body is made in the form of a head fairing 14. The head fairing 14 is pivotally connected to the specified body 9 and is made with the possibility of turning around its axis of rotation through an angle of 180 ° and fixing in a predetermined position.

The submunition consists of a fragmentation body 15 placed in it of an explosive charge (EX) 16 and a fuse 17. The fuse contains an inertial trigger sensor, a moderator, a safety mechanism and a detonator. Submarine is equipped with a latch, providing its specified position in the body of the warhead (not marked).

Shells and HPE can be made of both steel and heavy alloys based on tungsten, tantalum, etc.

The proposed grenade is used as follows.

The case of shooting at a flat trajectory by a grenade with a temporary fuse is considered. The shooter is equipped with a laser rangefinder and a ballistic computer. A device for contactless insertion of a temporary installation into a fuse is mounted on a grenade launcher barrel made of a non-metallic material, for example, fiberglass.

Before a shot, the range to the target, the distance to the point of ejection of the warhead, and the flight time to this point, which is introduced into the trajectory fuse in a contactless manner through the radio-transparent wall of the barrel, are determined. When fired, the trajectory fuse time countdown device is started and the first stage of cocking of the subarmifiers is activated.

When fired, the rocket engine of solid fuel 1 is activated and gives the grenade a predetermined trajectory and duration of the flight.

When approaching a grenade to the design point, on command, uncoupling the head fairing 14 with the cylindrical body 9, followed by turning the head fairing 14 around its own axis of rotation and fixing in a predetermined position.

Due to a sharp asymmetric change in the aerodynamic resistance of a grenade, a radial component is added to the axial velocity component, and the grenade, in addition to translational motion, acquires a rotational one.

At the same time, or with some delay, the solid propellant rocket engine 1 is disconnected from the housing 9 using a powder charge 6 with thread cutting 8. The housing 9 is open on both sides for the departure of the submunitions 5 under the action of the autonomous powder charges 11 shooting off the subarms and centrifugal forces account of a sharp asymmetrical change in the aerodynamic drag of a grenade.

Submunitions 5 fly out of the housing 9 to both sides under the action of gases of autonomous powder charges 11, while, due to the rotation of the housing 9, they acquire the tangential velocity component, which allows them to significantly increase their spread in different directions from the calculated point of the trajectory, and, accordingly, increase the area of the lesion.

At the moment of release of submunition 5, the inertial sensor of its fuse 17 starts the retarder, which, after a predetermined period of time, gives out an impulse to explode subunit 5. As a result, a chain of gaps is formed above the target, compensating for the total error of the trajectory undermining of grenades.

The proposed design can be used both in grenades with an over-caliber warhead, in RPG-7 grenade launchers, and in grenades with a caliber warhead: RPG-18 “Fly” grenade launchers, RPG-22 “Netto”, RPG-26 “Aglen”, RPG-27 Tavolga, RPG-29 Vampire.

The use of the proposed technical solution will significantly improve the effectiveness of a grenade by increasing the area of damage.

Claims (8)

1. A grenade to a hand-held grenade launcher containing a cluster warhead with fragmentation submunitions, a solid-fuel rocket engine installed in the rear of the grenade, including a body with a charge of solid fuel and a nozzle, in the middle part a trajectory fuse, in the front part a warhead in the form of a set fragmentation submunitions or projectiles, each of which contains a decelerating fuse, a pyrotechnic separation charge is located between the trajectory fuse and a set of submunitions, a set of subunits is located in a cylindrical body with a head fairing, said body is made detachable from a rocket engine with the possibility of ejecting sub-shells under the action of autonomous expelling powder charges, sub-shells have a spherical shape, while the warhead is made with gauge or caliber, characterized in that said cylindrical body of sub-shells is designed with ejection submunitions along the longitudinal axis of the grenade in both directions, with the head fairing pivotally connected to the specified body, made with the possibility Turning around its axis of rotation at an angle of 180 °, fixing in a predetermined position and disconnecting with the cylindrical body when the grenade arrives at the calculated point, while the grenade itself during its forward movement is provided with the possibility of rotational movement. 2. Grenade according to claim. 1, characterized in that the trajectory fuse is made of a temporary or non-contact, or command type. 3. The grenade according to claim 1, characterized in that between the spherical sub-shells in the case there are diaphragms, in the annular grooves of which the autonomous gunpowder shooting charges of the sub-shells with autonomous igniter blocks are placed. 4. The grenade according to claim 1, characterized in that the igniter unit contains an inertial launch sensor, a retarder with a different deceleration time for each subarm and an igniter. 5. The grenade according to claim 1, characterized in that the body of the warhead, the diaphragm and the bottom are made of high strength lightweight material - carbon fiber. 6. The grenade according to claim 1, characterized in that the spherical sub-equipment consists of a fragmentation case, an explosive charge and a fuse located in it, and the fuse contains an inertial trigger sensor, a moderator, a safety mechanism and a detonator. 7. Grenade according to claim. 6, characterized in that the fragmentation of the body is made in the form of a solid hollow sphere or in the form of a composite structure of two hemispheres connected by thread. 8. The grenade according to claim 6, characterized in that the fragmentation case is made with either natural, or with predetermined crushing, or with ready striking elements, while the case and ready striking elements are made of both steel and heavy tungsten-based alloys. or tantalum.

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