RU2651872C1 - “vartava” over-caliber particle grenade for the hand grenade launcher - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention relates to ammunition and, in particular to over-caliber particle grenades to a hand grenade launcher. Grenade contains a caliber part with a propellant charge and ignition means, over-caliber bundle warhead with an explosive charge, fragment plate and trajectory fuse. At the moment of detonation the over-caliber warhead is a flat disk arranged perpendicular to projectile axis. Warhead is divided into five parts, one central and four peripheral. Central part is made in the form of a square. It is located perpendicular to the longitudinal axis of the grenade. On this part a shaped fairing is installed. Peripheral parts are made in the form of circle parts, formed by each evenly alternating square sides one end extension to the intersection with circumference, forming the warhead. In this case, two of them are configured to change their position relative to each other from folded to unfolded, in which they together with the central part form a flat rectangle through intermediate positions in which they are located at a given angle.

EFFECT: technical result is an increase in the grenade combat effectiveness.

1 cl, 3 dwg

Description

The invention relates to ammunition, namely: to supercaliber beam grenades of hand grenade launchers.

Known over-caliber beam grenade to a hand grenade launcher, containing a caliber part with a propelling charge and an ignition means, located in front of it a high-caliber beam warhead with an explosive charge, a fragmentation plate and a trajectory fuse, while the warhead, representing at the time of detonation a flat disk located perpendicular to the axis of the projectile, consists of two sections, each of which represents half of the disk, while both sections are made with the possibility of rotation through an angle of 90 ° around the axis connecting these sections and located perpendicular to the axis of the grenade, while in official circulation and in flight until the sections are opened, they are folded with large bases so that the axis of the grenade is in the plane of their contact (RF Patent for the invention No. 2502040, application: 2012138547 from 09.09. 2012, IPC: F42B 8/18, F42B 12/32 - prototype).

The specified grenade is used as follows.

When a grenade approaches the estimated detonation point, the fuse gives a command to trigger the pyrotechnic mechanism for extracting the stoppers, after which, under the action of centrifugal forces and an incoming air flow, the sections begin to open, after turning through 90 ° the sections are set to form a warhead in the form of a flat disk. In this case, the fuse contacts the detonators of the sections, i.e. the protection stage is removed. Then the fuse gives a command to undermine both sections, as a result of which an axial flow of ready-made striking elements or explosive-formed bullets that hit the target is formed.

The main disadvantages are significant dimensions and weight, the flight of a grenade with folded sections of the disc in front of it, which leads to an off-design change in the flight path. Also, the large diameter of the warhead increases the volume of the container, reduces the number of grenades transported for the given dimensions of the transport compartment, and makes it difficult to carry grenades in the soldier’s knapsack.

The objective of the proposed technical solution is to remedy these shortcomings and create an over-caliber beam grenade with a drop-out warhead with improved mass-dimensional characteristics.

The solution to this problem is achieved by the fact that in the proposed over-caliber beam grenade to a hand grenade launcher (hereinafter referred to as the grenade) containing a caliber part with a propelling charge and an ignition means, in front of it a high-caliber beam warhead with an explosive charge, a fragmentation plate and a trajectory fuse, this warhead consists of several sections, each of which represents part of the disk, and part of the sections is made with the possibility of rotation around the axes connecting these sections m waiting for myself and located perpendicular to the axis of the grenade, while in official circulation and during flight, until the disclosure, the sections are folded along the axis of the grenade, according to the invention the warhead is divided into five parts, one central, made in the form of a square and located perpendicular to the longitudinal axis of the grenade, parts of the profiled fairing, and four peripheral, made in the form of parts of a circle formed by extending one end of each evenly alternating side of the square to the intersection with the circle that forms the warhead, while two of them are made with the possibility of changing their position relative to each other from folded, in which they are located around the central part parallel to the longitudinal axis of the grenade, until deployed, in which they together with the central part form a flat rectangle through intermediate positions in which they are located at a given angle from 0 to 90 ° to the longitudinal axis of the grenade along its flight.

The invention is illustrated by drawings: where in FIG. 1 shows a general view of a grenade in a transport position / during flight in a perspective view; FIG. 2 shows a general view of a grenade in a combat position in a perspective view, FIG. 3 - expanding warhead on an enlarged scale. In FIG. 3 on the upper part shows the position of the sections of the warhead before using the grenade, in the combat position, on the lower part - the position of the sections in the transport position. Arrows indicate the direction of disclosure of sections of the warhead.

An over-caliber beam grenade for a hand grenade launcher contains a caliber part 1 with a propelling charge and an ignition means, an over-caliber beam warhead located in front of it. The over-caliber part 2 includes a nozzle block 3, a trajectory fuse 4 with a receiver of installations 5, and an arm 6 attached to the fuse in which pivotally connected sections of the warhead 2 are suspended on the axes.

The warhead 2 is divided into five sections, four peripheral 7, made in the form of parts of a circle formed by extending one end of each evenly alternating side of the square to the intersection with the circle forming the warhead, and one central 8, made in the form of a square, and located perpendicular the longitudinal axis of the grenade, with a profiled fairing 9 installed on the central part. The peripheral sections 7 are configured to change their position relative to each other from a folded one, at which m, they are located around the central part parallel to the longitudinal axis of the grenade, until deployed, in which they, together with the central part, form a flat disk through intermediate positions in which they are located at a predetermined angle from 0 to 90 ° to the longitudinal axis of the grenade along its flight. In official circulation and during flight, up to the opening, sections 7 are folded along the axis of the grenade.

The peripheral sections 7 and the central section 8 of the warhead 2 comprise a casing 10 and a casing 11, respectively, filled with a charge of explosive (BB) 12, shrapnel plates 13 and 14 located on the surface of the charge and facing, after opening the warhead, toward the flight of the grenade and detonator 15 .

The fragmentation plate 13 or 14 is made either in the form of a plate of a given crushing, or in the form of a flat set of ready-made striking elements (GGE), or in the form of a plate with meniscus depressions extruded on it, facing the vertices to the explosive charge. The fragmentation plate may be made of steel or of heavy alloys based on tungsten or tantalum.

In official circulation and in flight before the deployment of the warhead, the position of the sections is fixed using movable stops 16 (the conditional configuration of the stops is shown). At the exit of the trajectory fuse 4, a detonator 17 with transfer charges 18 is installed.

The trajectory fuse can be either temporary or rotational, or non-contact, or command type.

Calculations for the grenade-type grenades, carried out using the ratios of external ballistics, explosion physics and the theory of combat effectiveness, showed that the maximum probability of hitting typical targets is achieved with a ratio d _bch / d _bld = 4 ... 5 (d _bld , d _bch - respectively the diameters of the barrel caliber and over-caliber parts of the grenade). For the widespread standard RPG-7 grenade launcher (d _barrel = 40 mm), the optimum diameter of the warhead of the grenade is in the range of 160 ... 200 mm.

The proposed pomegranate is used as follows.

The action of the grenade is considered when using a temporary or number-turn fuse.

The setting of the flight time before detonation is introduced before the shot through the receiver settings 5 contact or non-contact way. It should be noted an important feature of the proposed grenade - the presence of a safety mechanism that disconnects the fuse from the explosive charges of all sections of the warhead in official use. The accidental operation of the fuse during a shot or in flight at a small distance from the grenade launcher will not lead to detonation of the grenade, since there is no contact “transfer charge - section detonator” at this stage.

When approaching the grenade to the estimated point of detonation, the fuse gives a command to actuate the pyrotechnic mechanism for extracting the stoppers, after which, under the action of centrifugal forces and the incoming air flow, the opening of the movable peripheral sections begins 7. Depending on the tasks to be solved, the sections can take intermediate positions in which they are located under a predetermined angle from 0 to 90 ° to the longitudinal axis of the grenade along its flight. In this case, three GGE flows are formed - one axial, from the central section 8, one radial, from the stationary peripheral sections 7, and radial-axial, from the movable peripheral sections 7, which eliminates the mutual effect of the flows on each other and increases the efficiency of the grenade .

Also, depending on the tasks to be solved, after rotation through 90 °, the peripheral sections 7 can be installed around the central section 8 in position with the formation of the warhead in the form of a flat disk. In this case, the fuse contacts the detonators of the sections, i.e. the protection stage is removed. Then the fuse gives a command to detonate all sections, as a result of which an axial flow of ready-to-use striking elements or explosive-shaped bullets that hit the target is formed.

Using the proposed technical solution will allow you to create over-caliber beam grenade for a hand grenade launcher with improved mass-dimensional characteristics.

Claims (1)

An over-caliber beam grenade to a hand grenade launcher containing a caliber part with a propelling charge and ignition means, an over-caliber beam warhead in front of it with an explosive charge, a fragmentation plate and a trajectory fuse, while the warhead consists of several sections, each of which represents a disk part moreover, part of the sections is made with the possibility of rotation around the axis, the connection of these sections with each other and the location perpendicular to the axis of the grenade, while in the service ar During flight and before flight, the sections are folded along the axis of the grenade, characterized in that the warhead is divided into five parts, one central, made in the form of a square and located perpendicular to the longitudinal axis of the grenade, with a profiled fairing mounted on the central part and four peripheral in the form of parts of a circle formed by extending one end of each evenly alternating side of the square to the intersection with the circle forming the warhead, while two of them are made with the possibility of changes in their position relative to each other from folded, in which they are located around the central part parallel to the longitudinal axis of the grenade, to deployed, in which they, together with the central part, form a flat rectangle through intermediate positions in which they are located at a given angle from 0 up to 90 ° to the longitudinal axis of the grenade along its flight.

Images