RU2782423C1 - Cartridge for underground grenade launcher - Google Patents

Abstract

FIELD: unitary loading ammunition.

SUBSTANCE: invention relates to unitary loading ammunition, and more specifically to a caseless artillery cartridge for underbarrel grenade launchers, the fragmentation warhead of which is made of ring elements. The proposed shot for an underbarrel grenade launcher includes a head fuse placed inside a composite case containing annular elements of a given crushing made of heavy alloy resting on the protrusion of the bottom of the case, externally equipped with evenly distributed radial corrugations 2/3 of the thickness of the rings and longitudinally pressed with a threaded nut, bursting charge, a chamber of a composite case pressed into a thin-walled inset cup of a congruent shape, and a combustion chamber of a propellant charge initiated by a central igniter primer fixed in the end diaphragm, integrally connected to the bottom of the case. In this case, the radial corrugations of the ring elements have a symmetrical wedge-shaped profile with an angle of 15…45° and a rounded corner of the wedge with a radius of 0.1…0.3 of their depth. The outer cylindrical wall of the composite body and its bottom are made in the form of a monolithic cup, inside the threaded point of which a threaded nut and a rounded head fuse are simultaneously screwed.

EFFECT: increasing the efficiency of the fragmentation action and the functional reliability of the ammunition with a simpler and more technologically advanced design.

2 cl, 3 dwg

Description

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

The level of this field of technology characterizes a shot for a grenade launcher according to patent RU 2421685 C1, F42B 5/02; 5/18; 12/32, 2011, which includes a fragmentation warhead with a head fuse and a leading belt made of a monolith of the bottom of a composite case, on which a propellant charge combustion chamber is permanently fixed, which communicates with an igniter primer installed in the end diaphragm.

A feature of this shot is that a coaxial clip made of cast polymer material is additionally placed on the body, carrying equally distributed balls of heavy alloy or metal - ready-made striking elements.

The implementation of the composite body of the ammunition in the form of a fragmentation block installed between two coaxial shells increases the power of the fragmentation action, since the inner massive shell serves as a source of damaging elements during crushing from undermining blasting equipment, and the thin-walled outer shell serves as an aerodynamic fairing, minimizing the deceleration of the ammunition in flight.

The placement of balls in the volume of the carrying polymer base of the clip creates a constructive unity in the form of an autonomous assembly unit, thereby increasing the manufacturability of a serial ammunition with a given field*of expansion of ready-made submunitions.

Reinforcement of fragmentation balls in a cage made of cast polymer material eliminates backlash and gaps in the composite case. Heavy alloy balls, dense and strong, provide high range and penetration.

The disadvantage of the known shot for a grenade launcher is the loss in the initial speed of throwing spherical striking elements, which reduces the effectiveness of its action on targets, due to the premature breakthrough of the detonation products of the bursting charge through the gaps between the heavy-alloy striking elements filled with light polymer material, as well as the low filling factor of the ammunition due to the presence of an internal massive shell and ballast polymer material fragment clip.

In addition, aerodynamically shaped spherical striking elements do not penetrate well the protective plates of Kevlar personal armor.

The noted disadvantage is eliminated in the design of the shot for a grenade launcher according to patent RU 2681794 C1, F42B 5/02; 5/18; 12/28, 2019, which, in terms of 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 head fuse of explosive equipment placed inside a composite case containing a fragmentation clip of a given fragmentation resting on the protrusion of the bottom, adjacent to the conical liner and placed between the shells, the inner of which forms the chamber, and the outer one is connected with the head fuse and fixed on a monolithic the leading belt of the bottom, integrally connected with the combustion chamber of the propellant powder charge, initiated by the central primer-igniter, fixed in the end diaphragm.

A feature of the well-known shot is that the inner shell is made in the form of a thin-walled insert cup, into which explosive equipment is pressed, the fragmentation clip is made up of a set of adjacent rings sintered from heavy metal or alloy powder, which are equipped with equally distributed radial grooves on the outside and are longitudinally pressed with a threaded nut under the conical liner, screwed inside the outer shell, while the conical liner is equipped with a threaded point for the head fuse.

Another feature of the known shot is that the radial corrugations of the shrapnel clip have a depth of 2/3 of its thickness.

The execution of the inner shell of the composite body in the form of a thin-walled glass, shaping the grenade chamber, made it possible to press explosive equipment outside the assembly line directly into the glass. At the same time, the bursting charge is obtained in the form of an autonomous assembly unit that is safe for official use.

The execution of the fragmentation clip from a set of closed rings, equipped with equally distributed radial corrugations on the outside, provides a given crushing into fragments of an aerodynamic shape with sharp edges that increase the damaging effect.

Forced closure of adjacent rings by means of a threaded nut connected to the outer shell forms a quasi-solidity of the fragmentation clip, preventing the breakthrough of detonation products between them, which ensures a high expansion rate of the formed fragments of a given shape.

When the explosive load is detonated, heavy alloy clip rings are crushed along the radial corrugations, forming high-speed fragments that effectively penetrate lightly armored barriers and Kevlar.

The conical mounting sleeve, mating with the head fuse and the outer shell, provided a streamlined shape of the ammunition, thereby reducing braking on the flight to the target to increase the firing range.

A continuation of the noted advantages of the well-known shot for a grenade launcher are the inherent disadvantages:

- a decrease in the useful mass yield of fragments (damaging elements) formed during crushing of heavy alloy rings along radial grooves due to partial chipping of the material during crushing and the formation of secondary fragments of a fine fraction, due to the lack of parameters that determine the shape of the corrugation of the rings;

- the execution of the outer shell and the bottom of the composite body in the form of two threaded parts reduces the longitudinal strength and rigidity of the shot, and, consequently, its reliability;

- reducing the mass of emerging striking elements reduces their kinetic energy, thereby reducing the effectiveness of action against obstacles, including light armor and Kevlar body armor.

In addition, the presence of additional threaded connections between them increases the cost of a shot in mass production.

The technical problem to be solved by the present invention is to increase the efficiency of the fragmentation action and the functional reliability of the ammunition of a simpler and more technologically advanced design.

The required technical result is achieved by the fact that in the well-known shot for a grenade launcher, including a head fuse, placed inside a composite case containing annular elements of a given crushing from a heavy alloy resting on the protrusion of the bottom of the case, externally equipped with evenly distributed radial corrugations with a depth of 2/3 of the thickness of the rings and longitudinally pressed with a threaded nut, a bursting charge pressed into a thin-walled insert cup of a congruent shape in the chamber of the composite body, and a combustion chamber of a propellant powder charge integrally connected to the bottom of the body, initiated by a central primer-igniter fixed in the end diaphragm, according to the invention, the radial corrugations of the annular elements have symmetrical wedge-shaped profile with an angle of 15…45° and a rounded corner of the wedge with a radius of 0.1…0.3 of their depth.

Another feature of the proposed shot is that the outer cylindrical wall of the composite body and its bottom are made in the form of a monolithic glass, inside the threaded point of which a threaded nut and a rounded head fuse are simultaneously screwed.

The distinctive features of the proposed technical solution have increased the effectiveness of the damaging effect of high-velocity heavy alloy projectiles while simplifying the design and manufacturing technology of serial ammunition.

The implementation of radial corrugation of ring elements made of heavy alloy in the form of symmetrical wedges evenly distributed over the outer surface with the proposed geometric parameters is intended to form striking elements with the highest useful mass yield upon actuation of a bursting charge.

The process of ring fragmentation can be divided into three main stages: the stage of compression, the stage of destruction, and the stage of expansion of non-interacting projectiles. The compression stage begins from the moment the impact of detonation products on the inner surface of the ring begins and ends with the collapse of the corrugations on its outer surface. The stage of destruction of the ring begins after the end of compression and ends with the division of the ring into separate fragments. The stage of free expansion begins after the division of the ring and the external cylindrical wall of the body adjacent to it into separate fragments.

When performing radial corrugations on the outer surface of heavy alloy rings in the form of symmetrical wedges with an angle "α" of less than 15 °, splitting and chipping of striking elements in the area of the interface between the surface of the wedge and the outer surface of the ring take place, which leads to a decrease in the mass of the forming striking elements and, accordingly, their kinetic energy.

When making a corrugation with an angle "α" of more than 45 °, the corrugation does not completely collapse at the stage of compression of the ring, as a result of which, in the place of the resulting thinning of the ring material, the breakthrough of detonation products occurs earlier, as a result of which the expansion speed of the striking elements decreases and their effectiveness decreases. over the barriers.

At the stage of destruction of the ring, the radius of curvature "r" of symmetrical wedge corrugations less than 0.1 of their depth "h" is a strong stress concentrator and leads to the formation of shear accompanying fragments of a fine fraction and a decrease in the mass of forming striking elements.

The fulfillment of the radius of curvature "r" more than 0.3 of their depth "h" leads to an early breakthrough of detonation products at the beginning of the compression stage before the collapse of the corrugations in the place of a significant difference in thickness at the tops of the wedge corrugations, and as a result, to a decrease in the speed of expansion of striking elements and their barrier effectiveness.

In serial production, ring elements of a given crushing can be manufactured by a modern high-performance injection molding method (injection molding into a mold), which does not require subsequent mechanical refining from a heavy alloy, for example, VNZh-93. This ensures accurate repetition of the geometry and low cost of the parts obtained.

Structurally, the execution of the outer cylindrical wall of the composite body and its bottom in the form of a monolithic cup increases the longitudinal strength and rigidity of the shot. In addition, there is no need to use glue or sealant at the junction that prevents the passage of powder gases into the body when fired.

Installing a set of ring elements of a given crushing from a heavy alloy, a threaded nut, and a head fuse directly into the body simplifies the design of the shot and reduces its cost in mass production.

The implementation of the fuse rounded shape, with a radius corresponding to half the caliber of the shot, provides minimal aerodynamic resistance when flying on a trajectory at subsonic speeds, typical for shots to underbarrel grenade launchers.

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

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

The drawing shows:

in fig. 1 - proposed shot for an underbarrel grenade launcher;

in fig. 2 is a view A-A in FIG. one;

in fig. 3 is a photograph of a group of target crushing ring elements made of heavy alloy.

A shot for an underbarrel grenade launcher according to the proposed invention includes a head fuse 1, the detonator of which is placed inside an explosive charge 2, which fills a thin-walled glass 3, installed in a housing 4, which is integrally connected with the combustion chamber 5 of the propellant powder charge 6, which performs the functions of an artillery shot shell.

From the material of the body 4, a belt with ready-made rifling 7 is monolithically made, which, when fired, performs the functions of a master device included in the spiral rifling of the barrel of an underbarrel grenade launcher.

Inside the housing 4, until it stops against the protrusion 8 of the bottom of the housing, a fragmentation clip is installed, made up of tightly adjacent ring elements of a given crushing 9 of a square profile, which are made by sintering heavy metal or alloy powder, for example, grade VNZh-93.

In the threaded point 10 of the body 4, a threaded nut 11 is installed in series, with a force pressing the rings 9 and the head fuse 1 of a rounded shape.

The ring elements of the specified crushing 9 of the fragmentation clip are equipped with equally distributed radial corrugations 12 with a depth "h" 2/3 of the thickness of the rings with a symmetrical wedge-shaped profile with an angle "α" 15 ... 45 ° and a rounded corner of the wedge with a radius "r" 0.1 ... 0, 3 are their depths "h".

The internal profile of the body 4, the rings 9 of the fragmentation clip and the threaded nut 11 form the chamber of the composite body of the grenade, which adjoins a congruent glass - a thin-walled shell 3, into which explosive equipment 2 is pressed autonomously in the matrix in a separate operation.

The head fuse 1 is installed in the threaded point 10 of the body 4, the detonator of which is placed inside the explosive equipment 2.

In the end diaphragm 13 of the combustion chamber 5, which has outlet holes 14 located along the perimeter, a central igniter primer 15 is installed.

A shot is assembled in the following technological sequence.

A fragmentation clip of rings 9 is inserted inside the body 4 until it stops into the protrusion 8 of the bottom of the body. Next, the retaining ring 11 is screwed into the threaded point 10 of the body 4, pressing the rings 9 against each other with force, forming a quasi-monolith of the composite body of the grenade.

After that, a thin-walled glass 3, pre-equipped with a bursting charge 2, is placed inside the rings 9.

The combustion chamber 5 is equipped autonomously: a central igniter primer 15 is installed in the diaphragm 13, and then a propellant charge 6 is placed on the covering diaphragm 13 of the burning membrane (conditionally not shown). then crimped to form a permanent connection.

Then, a rounded head fuse 1 is installed in the threaded point 10 of the body 4, as a result of which the finally equipped shot is ready for use for its intended purpose.

The proposed shot for an underbarrel grenade launcher functions as follows.

When the striker of the grenade launcher of the igniter cap 15 is initiated by the force of the flame, a propellant powder charge 6 is ignited, the combustion of which is accompanied by the generation of gaseous products that sharply increase the pressure in the chamber 5. the closed volume of the breech of the weapon, creating a reactively directed impulse of force, as a result of which the ammunition moves rapidly along the barrel of the grenade launcher.

At the same time, the belt with ready-made rifling 7 of the body 4, being engaged with the combat edges of the spiral rifling of the barrel, twists the grenade around its longitudinal axis for gyroscopic stabilization on the flight path to the target.

The combustion chamber 5, which functions as a sleeve, is not separated from the grenade, being fired together.

When a grenade meets an obstacle, head fuse 1 is activated, the detonator of which initiates the detonation of explosive charge 2, accompanied by the propagation of a detonation wave along the explosive charge and the formation of detonation products under high pressure.

Under the action of high pressure of the detonation products of the bursting charge along the radial corrugations 12, the rings 9 are fragmented into striking elements. After the separation of the rings into separate striking elements, the detonation products breaking through between them cut through the body 4, which forms regular fragmentation fragments from it.

The organized formation and expansion of dimensional fragments of the structural elements of the composite body 3-9-4 provides an increased damaging effect, which was confirmed during stationary explosions of prototype products according to the invention, while 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.

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

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

The manufacture of a modernized shot for a grenade launcher improved according to the invention can be carried out on automatic equipment operating in mass production.

From the foregoing, it can be concluded that the invention complies with the conditions of patentability.

Claims (2)

1. A shot for an underbarrel grenade launcher, including a head fuse, placed inside a composite case containing annular elements of a given crushing made of heavy alloy resting on the protrusion of the bottom of the case, externally equipped with evenly distributed radial corrugations 2/3 of the thickness of the rings and longitudinally pressed with a threaded nut, explosive a charge pressed into a thin-walled insert cup of a congruently shaped chamber of a composite case, and a combustion chamber of a propellant charge, integrally connected to the bottom of the case, initiated by a central primer-igniter fixed in the end diaphragm, characterized in that the radial corrugations of the annular elements have a symmetrical wedge-shaped profile with an angle 15 ... 45 ° and a rounded wedge with a radius of 0.1 ... 0.3 of their depth. 2. A shot for an underbarrel grenade launcher according to claim 1, characterized in that the outer cylindrical wall of the composite body and its bottom are made in the form of a monolithic glass, inside the threaded point of which a threaded nut and a rounded head fuse are simultaneously screwed.

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