RU2772649C1 - Shot for an automatic grenade launcher - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention relates to shots with high-explosive fragmentation grenades for firing automatic grenade launchers. The shot comprises a head fuze and a fragmentation body with a leading band, equipped with crushing localisers distributed equally along the height of the chamber, in the form of annular corrugations with a wedge-shaped section with a depth of 0.25 to 0.5 wall thickness on the side of the chamber filled with explosives. The body is connected with a cartridge carrying a propellant powder charge initiated by a bottom igniter primer. The annular corrugations have a rounded wedge angle with a radius of 0.4 to 0.5 of the depth. The first annular corrugation from the side of the bottom of the chamber is distanced at a step between the corrugations from the groove for the leading band, made of copper. The mouth of the cartridge is connected with the body by rolling into the ammunition groove. The angle of wedge-shaped corrugation is selected in the range of 45 to 90°.

EFFECT: increase in the effectiveness of impact of the munition, increase in the safety when equipping the explosive and when firing.

3 cl, 1 dwg

Description

The invention relates to shots with high-explosive fragmentation grenades intended for firing from automatic grenade launchers, the grenade shell has grooves of a given shape, providing optimal crushing into a given number of fragments.

The level of this field of technology is characterized by a shot with controlled crushing of the grenade shell described in patent RU 2342625 C1, F42B 12/24, 2008. outer surface. The bottom part (tail) of the hull is made autonomously and is connected to the hull in an interference fit.

In the shank of the grenade there is a propellant charge with exit holes along the end of the grenade and a central igniter primer.

The disadvantage of this design is the presence of annular grooves on the outer surface of the body, which worsens the aerodynamics of the grenade, worsens the firing distance, and the time to reach the target.

This disadvantage is eliminated in the shot for an automatic grenade launcher according to patent RU 2684651 C1, F42B 12/24, 2019, which, by the number of matches and the achieved technical result, was chosen as the analogue of the closest proposed shot. The marked shot for a grenade launcher contains a head fuse, a fragmentation body with a leading belt, equipped with a fragmentation localizer in the form of distributed flutes on the side of the chamber filled with explosive, and a shank carrying a propellant charge adjacent to the central igniter primer and a nozzle hole at the end. Wedge profile corrugations are made in the form of transverse grooves with a depth of a quarter-half of the thickness of the body wall to separate it during detonation into parallel rings with a height equal to the pitch between the grooves, while the formed rings are provided with the possibility of transverse fragmentation into striking elements, and the bottom of the body is equipped with a skirt mating with shank groove, which are connected by means of an anaerobic sealant.

The disadvantage of this design is the lack of parameters that determine the shape of the grooves, which makes it possible to ensure safe equipment with explosives and when firing, as well as optimal crushing when separating the shell of the body and is of limited use due to the presence of a shank at the bottom.

The main task to be solved by the present invention is to increase the efficiency of the fragmentation action of a shot to an automatic grenade launcher for its intended purpose, that is, an increase in the number of fragments during controlled crushing of the body into striking elements within the specified weight and size parameters, as well as ensuring safety when equipped with an explosive.

A shot that makes it possible to obtain the desired result consists of a fragmentation grenade, including an instantaneous head contact fuse, a steel fragmentation body with an explosive charge pressed into it and a leading device. A fragmentation grenade is installed in an extractable cartridge case by rolling the neck of the cartridge case into the cartridge groove.

On the inner surface of the wall of the steel fragmentation body crushing localizers are applied in the form of annular grooves of a triangular profile with rounded tops.

In this case, the distance between the driving device and the nearest groove, between the conical transition of the threaded part of the body into the cylindrical one and the nearest (upper in the figure) groove correspond to the step between the grooves.

The depth of the grooves is 0.25-0.50 of the body wall thickness. The angle between the walls of the grooves is 45°-90° with a radius of rounding of the tops of 0.25-0.50 of the depth of the groove.

When the angle between the walls of the groove is less than 45°, the filling of the groove with the explosive composition when equipped (pressing into the body) is not ensured. Air cavities are formed, which can lead to detonation of the explosive composition when fired. At an angle of more than 90°, the annular grooves do not provide complete axial separation of the body into fragments, due to the absence of a local increase in the pressure of detonation products during the collision of shock waves reflected from the walls of the grooves.

In the absence of a rounding radius of the tops of the grooves or its value is less than 0.25 of the depth, the grooves work well for separating the body during detonation of the charge, however, they are a source of increased stresses during firing, which reduces safety. At radii greater than 0.50 depth, the stress concentration during detonation of the charge is insufficient for stable division of the body into fragments.

Performing an equal distance between the grooves, the leading device and the lower groove, the conical transition and the upper groove allows you to get n + 1 identical rings when separating the body, where n is the number of grooves. In the design of the prototype, the number of identical rings is n-1.

Taking into account the constancy of the transverse fragmentation of rings into fragments, the proposed design scheme makes it possible to increase the yield of homogeneous fragments of a given mass (useful fragments) by k=(n+1)/(n-1) times.

When the number of annular grooves is 8 pieces, which is optimal for this design, the increase in the yield of homogeneous fragments of a given mass will be 28%.

The essence of the invention is illustrated by the drawing, which has a purely illustrative purpose.

The drawing shows a fragmentation shot for an automatic grenade launcher.

The shot consists of a fragmentation grenade, including an instant head contact fuse 1, a steel fragmentation body 2 with an explosive charge 3 pressed into it and a leading device 4. The fragmentation grenade is installed in an extractable sleeve 6 by rolling the mouth of the sleeve into the cartridge groove 5.

On the inner surface of the wall of the steel fragmentation body crushing localizers are applied in the form of annular grooves of a triangular profile with rounded tops in the amount of 8 pcs.

In this case, the distance between the driving device 4 and the nearest (lower in the figure) groove, between the conical transition of the threaded part of the body into the cylindrical one and the nearest (upper in the figure) groove corresponds to the step between the grooves.

The depth of the grooves is 0.25-0.50 of the body wall thickness. The angle between the walls of the grooves is 45°-90° with a radius of rounding of the tops of 0.25-0.50 of the depth of the groove.

When the angle between the walls of the groove is less than 45°, the filling of the groove with the explosive composition when equipped (pressing into the body) is not ensured. Air cavities are formed, which can lead to detonation of the explosive composition when fired. At an angle of more than 90°, the annular grooves do not provide complete axial separation of the body into fragments, due to the absence of a local increase in the pressure of detonation products during the collision of shock waves reflected from the walls of the grooves.

In the absence of a rounding radius of the tops of the grooves or its value is less than 0.25 of the depth, the grooves work well for separating the body during detonation of the charge, however, they are a source of increased stresses during firing, which reduces safety. At radii greater than 0.50 depth, the stress concentration during detonation of the charge is insufficient for stable division of the body into fragments.

The implementation of an equal distance δ between the grooves, the leading device 4 and the lower groove, the conical transition and the upper groove allows you to get n + 1 identical rings when separating the body, where n is the number of grooves. In the design of the prototype, the number of identical rings is n-1.

Taking into account the constancy of the transverse fragmentation of rings into fragments, the proposed design scheme makes it possible to increase the yield of homogeneous fragments of a given mass (useful fragments) by k=(n+1)/(n-1) times.

With the number of annular grooves 8 pcs. which is optimal for this design, the increase in the yield of homogeneous fragments of a given mass will be 28%.

The proposed shot works as follows.

After a shot is fired into the chamber, an igniter primer ignites from the impact of the grenade launcher striker, which ignites the propellant charge.

Under the action of the pressure of powder gases, the translational and rotational movement of the grenade begins.

On the flight path, at a distance of ten to sixty meters from the muzzle of the grenade launcher, the fuse is cocked.

When meeting with an obstacle, the head fuse is triggered, the detonator cap of which undermines the warhead of the grenade. The pulse from the detonator primer initiates the explosive. The gaseous detonation products of the equipment form a stress in the grooves, which leads to a plastic shear with subsequent destruction of the shell of the body into rings and division across into striking elements of the required size and mass.

Prototypes of grenades of the proposed design were tested by detonation in an armored pit with catching and collecting fragments. The work was carried out in accordance with GOST B 24430-82.

Evaluation of prototypes of the proposed design according to analytical and calculation methods for fragmentation in comparison with the prototype showed an increase of 28% in the formation of specified striking elements in terms of functioning, which makes it possible to recommend it for mass production and supply.

The manufacture of the proposed shot can be carried out in the current serial production.

It follows from the foregoing that the present invention meets the conditions of patentability.

Claims (3)

1. A shot for an automatic grenade launcher, containing a head fuse and a fragmentation body with a leading belt, equipped with crushing localizers equally distributed along the height of the chamber in the form of an annular corrugation of a wedge-shaped profile with a depth of 0.25-0.5 wall thickness from the side of the chamber filled with explosive equipment, while the body is connected to a sleeve carrying a propellant powder charge initiated by a bottom igniter primer, characterized in that the annular corrugations have a rounded corner of the wedge with a radius of 0.4-0.5 of their depth, and the first annular corrugation from the bottom of the chamber is one step apart between the corrugations from the groove for the leading belt, made of copper. 2. Shot according to claim 1, characterized in that the muzzle of the cartridge case is connected to the body by rolling into the cartridge groove. 3. Shot according to any one of paragraphs. 1 or 2, characterized in that the angle of the wedge corrugation is selected in the range of 45-90°.

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