RU2681794C1 - Shot for grenade launcher - Google Patents

Abstract

FIELD: small arms.SUBSTANCE: invention relates to a sleeveless artillery cartridge for automatic grenade launchers, the combat fragment of which is made of ring elements. Shot for the grenade launcher includes a head fuse of explosive equipment placed inside the composite hull containing a fragmentation yoke of a predetermined crushing resting on the bottom lug, adjacent to the conical liner and placed between the shells, the inner of which shapes the chamber, and the outer one is connected to the head fuse and is fixed on the monolithic leading waist of the bottom, inseparably connected with the combustion chamber of the propellant powder charge, initiated by the central primer-igniter, fixed in the end aperture. According to the invention, the inner shell is made in the form of a thin-walled independent glass, into which the bursting equipment is pressed, the fragmentation yoke is composed of a set of adjacent rings, baked from powder of heavy metal or alloy, which outside are equipped with equally distributed radial grooves and longitudinally preloaded by a threaded nut under a conical liner, screwed inside the outer shell, while the conical liner is provided with a screw point for the head fuse, and the radial rifles of the fragmentation yoke have a depth of 2/3 of its thickness.EFFECT: technical result consists in increasing the effectiveness of the damaging effect of high-speed splinters with sharp cutting edges, while simplifying the design and manufacturing technology of serial ammunition.1 cl, 2 dwg

Description

The invention relates to ammunition of unitary loading, and more specifically to a sleeveless artillery cartridge for automatic grenade launchers, the fragmentation warhead of which is made of ring elements.

The level of this technical field is characterized by an artillery unitary cartridge for an automatic grenade launcher according to patent RU 2135938, F42B 5/18/1999, which includes one-piece warhead containing a head fuse and a lead belt, and a combustion chamber filled with propellant powder charge, acting as a sleeve.

The use of a cartridgeless cartridge in this cartridge makes it possible to redistribute the mass of ammunition, increasing the share of its combat fragmentation part, which increases the efficiency of its intended use or reduces the weight load on the combat crew of a grenade launcher at a given fragmentation destruction efficiency.

The exclusion of the process of decatronization during firing increases the stability of combustion of the propellant powder charge, eliminating the extraction of cartridge cases. When installing a grenade launcher in confined volumes of combat use, it is not necessary to collect hot shells for stacking them in tare boxes, the installation of special reflectors is excluded, which increases shooting mobility.

A feature of this cartridge is the implementation of the lead belt along with the grenade body, from the monolith of its bearing bottom, which increases the rigidity of the compact design of the ammunition, further reducing the consumption of scarce copper.

However, the disadvantage of the described shot for a grenade launcher is the unsatisfactory damaging effect due to arbitrary unregulated crushing of the grenade body, determined by the probabilistic nature of the formation of damaging elements that are not optimal in terms of mass and size parameters with a wide range of dispersion of speed and range.

The noted drawback is eliminated in the design of the shot for a grenade launcher according to patent RU 2421685 C1, F42B 5/02; 5/18; 12/32, 2011, which, according to the technical nature and the number of matching features, was chosen as the closest analogue to the proposed shot.

A well-known shot for a grenade launcher contains a fragmentation warhead with a head fuse and a leading belt made of a monolith of the bottom of the composite body, on which the combustion chamber of the propellant powder charge is inseparably connected to the igniter capsule installed in the end diaphragm.

A feature of the well-known ammunition is that an additional coaxial cartridge made of injection-molded polymeric material is placed on the casing, bearing equally distributed balls of heavy alloy or metal — ready-made striking elements.

The implementation of the composite grenade body in the form of a fragmentation block mounted between two coaxial shells increases the efficiency of the intended purpose, since the internal massive shell serves as a source of damaging elements when crushing from blasting blasting equipment, and the thin-walled outer shell serves as an aerodynamic streamlined coating, minimizing braking of the shot by flight.

The rigid connection of the shells at both ends directly and through the annular protrusion of the bearing bottom, on which the fragmentation clip with ready-made striking elements is mounted, creates its rigidity and quasi-monolithicity by force and geometric closure of the structural elements of the composite body with the formation of a characteristic fragmentation field when undermining.

The placement of balls in the volume of the carrier polymer base of the cage creates a constructive unity in the form of an autonomous assembly unit, thereby increasing the manufacturability of serial ammunition with a given scattering field of finished striking elements.

The reinforcement of fragmentation balls in a cage of injection molded polymeric material eliminates backlash and gaps in the composite housing.

Balls made of heavy alloy or metal, dense and durable, provide high range and penetration.

A continuation of the noted advantages of the famous shot for a grenade launcher are the inherent disadvantages:

- low load factor due to ballast polymer material of a fragmentation cage carrying ready-made damaging elements - balls, but not participating in the penetrating action of the lesion, while the speed of the balls themselves is low due to the loss of energy of propelling equipment, the gaseous detonation products of which break through the polymer array ;

- poor accuracy of firing of ammunition due to the imbalance created by a fragmentation clip arbitrarily rotating relative to the body, since the elastic insert by definition does not fix its spatial position;

- a thick-walled inner shell limits the volume of explosive equipment, reducing the ammunition filling coefficient and its power, which results in limiting the range of the striking elements and inefficient penetration of obstacles.

In addition, the aerodynamic shape of the damaging elements do not penetrate the Kevlar protective plates.

The technical problem to which the present invention is directed is to increase the efficiency of fragmentation action and functional reliability of the munition of a simpler and more technological design.

The required technical result is achieved in that in a known shot for a grenade launcher, including a head explosive fuse placed inside a composite body containing a fragmentary clip of a given crushing resting on a protrusion of the shell adjacent to the conical insert and placed between the shells, the inner of which forms a chamber, and external connected to the head fuse and mounted on a monolithic leading belt of the bottom, inextricably linked to the combustion chamber propellant powder charge and, initiated by a central igniter capsule mounted in the end diaphragm according to the invention, the inner shell is made in the form of a thin-walled insert cup, into which bursting equipment is pressed, the fragment shell is composed of a set of abutting rings sintered of heavy metal or alloy powder, which are equipped on the outside equally distributed radial grooves and longitudinally pressed by a threaded nut under the conical insert, screwed inside the outer shell, while the conical insert is provided with en ochkom threaded under the head fuse.

Another feature of the proposed shot for a grenade launcher is that the radial riffles of the fragmentation cage have a depth of 2/3 of its thickness.

Distinctive features of the proposed technical solution increased the effectiveness of the damaging effect of high-speed fragments with sharp cutting edges, while simplifying the design and manufacturing technology of serial munitions.

The execution of the inner shell of the composite case in the form of a thin-walled cup, forming the grenade chamber, made it possible to compress explosive equipment outside the assembly production directly into a glass placed in a massive congruent-shaped matrix. At the same time, an energy-saturated charge was obtained in the form of an autonomous assembly unit safe in official circulation, mounted in a grenade adjacent to the fragmentation shell and the bottom, which is simpler and cheaper.

The implementation of the fragmentation cage from a set of closed rings equipped on the outside with equally distributed radial grooves, provides the specified crushing into fragments of aerodynamic shape with sharp edges that increase the damaging effect.

The force closure of adjacent rings by means of a threaded nut associated with the outer shell forms a quasimonolithic fragmentation clip, preventing breakthrough of detonation products between them, thereby ensuring a high expansion speed of the generated fragments of a given shape.

When explosive equipment is detonated, the ring rings are crushed along the radial grooves, forming high-speed fragments that effectively penetrate lightly armored barriers and Kevlar.

The implementation of fragmentation rings equipped externally with radial grooves of sintered powder material with a large specific gravity is productive and waste-free. In this case, it is possible to form relatively small fragments of a given crushing of rectangular-shaped rings having a high speed and expansion range to increase penetration, that is, the efficiency of the fragmentation effect of a grenade is noticeably increased, compared with the standard and prototype.

Rigid threaded connection of a conical liner, mounted in an abutment, through a threaded nut, on a fragmentation cage, with a head fuse and an outer shell, which is mounted on the protrusion of the bottom, formed a single power structure of the composite body as a unity of form and function, significantly simplifying the technology of assembling a grenade.

The conical-shaped mounting sleeve, mating with the head fuse and shot body, ensured the streamlined shape of the ammunition, thereby reducing braking on the flight to the target to increase the firing range.

The implementation of a fragmentation cage from a set of finished rings, by definition, greatly facilitates its separation into fragmentation fragments, which contributes to a noticeable increase in the flight range of the fragments, and equipping them from the outside with equally distributed riffles, as voltage concentrators, when undermining the equipment, regulates the transverse separation of the rings into dimensional fragments with sharp edges, characterized by cutting and penetrating properties, which increases the effectiveness of the action on lightly armored and special (in particular from Kevlar a) shells.

The implementation of fragmentation rings by the sintering method of powder alloys and metals simplifies the technology for producing standardized prefabricated fragmentation holders for grenade cases of controlled crushing from heavy materials, thereby increasing the specific gravity of the striking elements having an increased expansion speed when undermining.

The proposed shape and structure of the composite shell of the munition allows to perform radially unloaded shells from structural light aluminum or its alloy.

The choice of the optimal radial riffle depth outside the fragmentation ring rings was worked out experimentally and amounts to 2/3 of the ring thickness, in the range (0.6-0.7) of their thickness, when the maximum speed of uniformly flying fragments of the correct aerodynamic shape with sharp edges is reached.

When performing radial riffles outside of fragmentation rings with a depth of “h” greater than 0.7 of the thickness “t” of the crushing shell, energy storage is not ensured at maximum inflation of the casing, as a result of which the speed of expansion of fragments formed during crushing of the rings decreases and the penetration of the barrier decreases.

When performing riffles with a depth of “h” less than 0.6 of the thickness “t” of the fragmentation rings of the cage, its fragmentation occurs arbitrarily, conglomerates in the form of “saber” fragments arise, which have a low expansion speed and are strongly inhibited when the aircraft is not oriented toward the target.

Therefore, each feature is necessary, and their combination in a stable relationship is sufficient to achieve a novelty of quality that is not inherent in the characteristics of disunity, that is, the technical problem posed in the invention is not solved by the sum of the effects, but by a new super-effect of the sum of the attributes.

The invention is illustrated by the drawing, which serves purely for illustration and does not limit the scope of the claims of the totality of the features of the formula.

The drawing shows:

in FIG. 1 - the proposed shot for a grenade launcher;

in FIG. 2 is a view A in FIG. one.

A shot for a grenade launcher according to the proposed invention includes a head fuse 1, the detonator of which is placed inside the explosive equipment 2, filling the thin-walled shell 3 of a congruent shape to the bottom 4, which is inseparably connected with the combustion chamber 5 of the propellant powder charge 6, which performs the functions of a shell for an artillery shot.

From the material of the bottom 4, a girdle 7 is seamlessly made, which, when fired, performs the functions of a master device, which crashes when firing into the combat faces of spiral grooves of a grenade launcher barrel.

The protrusion 8 of the bottom 4 is based on a fragmentation cage made up of tightly adjacent square-shaped rings 9, which are made by sintering a powder of a heavy metal or alloy, for example, VNZh-90.

Outside, the cage of rings 9 is closed by an outer shell 10, which is screwed onto the protrusion 8 of the bottom 4 to the stop in the belt 7 and screwed on top with the mounting sleeve 11, the conical outer surface of which forms a streamlined aerodynamic shape of the munition, thereby reducing the braking of the incoming air flow on the flight to the goal.

A locking ring 12 is located under the sleeve 11, which, when assembled with maximum effort, is screwed onto the internal thread of the shell 10, compressing the rings 9 in a force abutment and forming a fragmentary clip, which together with the outer shell 10 forms a composite grenade body.

The rings 9 of the fragmentation cage are equipped with equally distributed radial flutes 13, which have a depth “h” equal to 2/3 of the thickness “t” of the rings 9.

The internal profile of the bottom 4, the rings 9 of the fragmentation cage and the mounting sleeve 11 form the chamber of the composite grenade body, which is adjoined by a congruent glass - a thin-walled shell 3, into which the explosive equipment 2 is pressed into the matrix autonomously in a separate operation.

In the threaded point 14 of the mounting sleeve 11, a head fuse 1 is installed, the detonator of which is located inside the explosive equipment 2.

In the end diaphragm 15 of the combustion chamber 5, which has outlet openings 16 located along the perimeter, a central igniter capsule 17 is installed.

A shot is going in the following technological sequence.

The outer shell 10 is screwed onto the protrusion 8 of the bottom 4 until it stops in the girdle 7.

Then, a fragmentary ring from the rings 9 is inserted into the outer shell 10 to the stop in the protrusion 8 of the bottom. Then, the retaining ring 12 is screwed inside the shell 10, pressing the rings 9 against each other with force, forming a quasimonolite of the composite grenade body.

After that, inside the rings 9, a thin-walled shell 3 pre-equipped with a bursting charge 2 is placed, on which the mounting sleeve 11 is mounted on the free upper end.

Next, the sleeve 11 is pre-screwed to the outer shell 10, geometrically linking them into a structural unity, all the way into the threaded ring 12

The combustion chamber 5 is equipped autonomously: a central igniter capsule 17 is installed in the diaphragm 15, and then a propellant charge 6 is placed on the burning diaphragm 15 (not shown conventionally).

The combustion chamber 5 assembly on the sealant is screwed into the bottom 4, forming their one-piece connection.

Then, a head fuse 1 is installed in the threaded point 14 of the mounting sleeve 11, as a result of which the fully equipped shot is ready for use for its intended purpose.

The proposed shot for the grenade launcher functions as follows.

When the igniter capsule 17 is triggered by a pulse from a grenade launcher, a propellant charge 6 is ignited by the force of the flame, the combustion of which is accompanied by the generation of gaseous products that sharply increase the pressure in the chamber 5. The hot combustion products of the charge 6 burn through the membrane covering the outlet openings 16 of the diaphragm 15 and are jet-intensively ejected into the closed volume of the breech of the weapon, creating a reactively directed impulse of force, as a result of which the ammunition accelerates along the grenade launcher barrel.

In this case, the annular protrusion 7 of the bottom 4 cuts into the combat faces of the spiral grooves of the barrel, forming a helical pair and twisting a grenade around its longitudinal axis for gyroscopic stabilization on the flight path to the target.

Acting as the sleeve of the combustion chamber 5 is not separated from the grenade, firing together. On the flight, the center of mass of the ammunition from the burning of charge 6 is shifted forward from the center of pressure, which contributes to the longitudinal stabilization of the shot.

When a grenade encounters an obstacle, the head fuse 1 inertially fires, initiating the detonation of the blasting equipment 2, the operation of which forms shock and detonation waves propagating from the center to the periphery and along the composite body.

In this case, under the action of the shock wave, rings 9 along radial riffles 13 are destroyed, forming a field of damaging elements of a given crushing, both shells 3 and 10 are destroyed, while the latter is crushed by the formed fragments of rings 9 into effective fragmentation fragments that enhance the damaging effect.

The organized separate-sequential formation and expansion of dimensional fragments of the structural elements of the composite casing 3-9-10 provides an increased damaging effect, which was confirmed by stationary blasting of prototypes of the products of the invention, while the compact heavy fragments formed during a given crushing of rings 9 have sharp edges, providing increased penetration of obstacles at a greater distance of expansion.

A comparison of the proposed technical solution with the identified analogues of the prior art did not reveal an identical match of the totality of the essential features of the invention.

The proposed differences of the shot for the grenade launcher, which do not directly follow from the statement of the technical problem, are not obvious to specialists in artillery ammunition.

The production of the upgraded shot for the grenade launcher improved according to the invention can be carried out using automatic equipment operating in serial production.

From the foregoing, we can conclude that the invention meets the conditions of patentability.

Claims (2)

1. Shot for a grenade launcher, including a head fuse of explosive equipment placed inside a composite body containing a fragmentary clip of a given crushing resting on a protrusion of the bottom adjacent to a conical insert and placed between the shells, the inner of which forms a chamber, and the outer one is connected to the head fuse and fixed on a monolithic leading belt of the bottom, inextricably connected with the combustion chamber of the propellant powder charge initiated by the central igniter capsule, in the end diaphragm, characterized in that the inner shell is made in the form of a thin-walled insert cup, in which explosive equipment is pressed in, the fragment shell is composed of a set of adjacent rings sintered from a powder of heavy metal or alloy, which are equipped on the outside with equally distributed radial grooves and are longitudinally pressed a threaded nut under the conical insert screwed inside the outer shell, while the conical insert is equipped with a threaded point under the head fuse. 2. A shot for a grenade launcher according to claim 1, characterized in that the radial riffles of the fragmentation cage have a depth of 2/3 of its thickness.

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