RU2347176C2 - Grenade launcher round - Google Patents

Abstract

FIELD: weaponry.

SUBSTANCE: invention relates to fragmenting projectiles. The proposed round incorporates a fragmenting casing made from a tubular perform jointed with a preset tightness, via an epoxy sealant interlayer, with its self-contained base and filled with explosive material, head fuse fitted in the taper adapter hole made integral with the aforesaid casing, sleeve with perforated grinding localizer circular grooves arranged on the casing surface and forming, in lengthwise section, a saw-like profile with webs, their thickness making 0.25 to 0.45 of the casing wall thickness, leading ledges for the barrel rifling grooves and propellant charge fitted in the combustion chamber arranged on the casing base part furnished with jets holes and accommodating the central percussion cap. The combustion chamber outer surface features a gas check representing circular undercuts.

EFFECT: ease of manufacture, increased fragmentation effect.

1 dwg

Description

The invention relates to ammunition, and more particularly to fragmentation shells with a shell having grooves for uniform crushing into fragments, and can be used for rifle grenades.

The level of this technical field is characterized by an artillery small-caliber projectile with a fragmentation shell of a given crushing, which is formed by a sawtooth profile of the inner surface formed by transverse grooves with polyhedral corrugations distributed around the perimeter (see patents RU No. 2080549 and No. 2080550, F42B 12/24, 1997 .).

These shells have explosive filling, lead belt and head fuse.

The shell of the projectile is made by multi-position stamping from a bar stock, cold extrusion with inter-operation thermochemical processing. The process is characterized by high productivity and metal utilization.

The regularity of crushing the shell of the shell of 0.95 is provided by the shape of the corrugations and the optimal depth of the grooves.

The thickness of the jumpers of the sawtooth profile is selected in the range of 0.25-0.45 shell thickness.

When the thickness of the jumper is less than 0.25 of the shell thickness, the structural strength of the body during firing is not ensured, which can cause premature rupture. As a result, the field of expansion of the fragments, which are blocked into conglomerates of several fragments, is distorted, and the speed of the striking elements decreases markedly.

With a bridge thickness of more than 0.45 shell thickness, the separation of the body along the profile of a given geometry is not guaranteed, because the destructive effect of the gas wedge of explosive detonation products in fine corrugations degenerates.

The increased yield of useful fragments according to well-known technical solutions allowed to reduce the thickness of the shell and increase the mass of explosives, thereby increasing the kinetics of the damaging elements and the effectiveness of the product for its main purpose.

The body is crushed into fragments of optimal weight 0.25 g with a shape factor of less than 1.5.

However, a continuation of the advantages is the inherent disadvantages, namely the technological and instrumental complexity of manufacturing fragmentation shells in a long multi-junction process of cold extrusion, which determine the high cost of the product.

In addition, in the manufacture of fragmentation shell shells by die forging, during which multifaceted corrugations of transverse grooves are formed, the fracture locators formed may not be sufficient to guarantee crushing of the shell into damaging elements of a given mass and configuration. This is explained by the anisotropy of the mechanical properties in various directions of the casing in magnitude, so in the transverse direction they are less than in the longitudinal one due to the presence of a crystallographically oriented texture of the rolled metal bar stock.

When the stamped shells of shells are detonated, fragments of an elongated shape are predominantly obtained or conglomerates of 2-3 striking elements of a given shape are formed, which sharply reduces the effectiveness of the main action, especially small-caliber fragmentation munitions.

The noted drawbacks are eliminated in the shot for the under-barrel grenade launcher described in patent RU 2171964, F42B 12/24, 2000, in which the fragmented corrugated body is rigidly connected to the propellant propellant combustion chamber, made for the diameter of the prechamber of the gun barrel with a guaranteed minimum clearance, according the so-called "sleeveless pattern" of a compact and mobile ammunition in shooting, selected by most of the matching features as the closest analogue to the proposed one.

A well-known artillery shot for a grenade launcher contains a warhead, including a fragmentation shell, the explosive filling of which interacts with a head fuse mounted in a housing adapter equipped with a master device, and a combustion chamber in the shank of the grenade, in which a propellant powder charge is placed, closed by a diaphragm with distributed nozzle openings carrying a central igniter capsule and loaded with a leaf spring from above.

The shank, mating with the profile of the pre-chamber of the gun barrel, acts as a piston with a minimum annular clearance in the barrel (pneumatic cylinder), where powder gases are jet-thrown from the combustion chamber, which provides the necessary throwing momentum developed along the length of the shank.

The design of the shot, in which the mass of structural elements is redistributed in the direction of increasing the warhead, is characterized by increased destruction efficiency, is more technological and convenient to use, since the extraction of the sleeve is excluded, which increases the rate of fire of the weapon.

The host device is made with ready-made protrusions, mating with the rifling of the barrel of the weapon, which provides the possibility of muzzle loading of the shot manually.

A characteristic feature of the fragmentation shell of the grenade is the additional execution on the outer surface of the transverse grooves symmetrically to the recesses of the sawtooth profile of the inner surface of the chamber.

The thickness of the shell jumper formed by the transverse grooves on the outside and the recesses of the internal profile is 0.25-0.45 shell thickness, which is consistent with the recommendations of the theory of designing ammunition shells with semi-finished fragments and the practice of their effective and functionally reliable use for their intended purpose.

In the well-known ammunition, the specified crushing of the shell into damaging elements of the required mass and shape is guaranteed, because the dimensional separation of the shell into rings occurs with the symmetrical bilateral action of the transverse grooves as stress concentrators, weakening the shell of the shell and forming shear planes.

The destruction of the annular fragments in the longitudinal direction occurs as a multifaceted brittle detachment specified by the configuration of the grooves.

A disadvantage of the known shot is the high complexity of manufacturing by stamping a corrugated grenade body together with a shank of a complex profile, of a different configuration, requiring additional tools, equipment, and technological operations, which complicates the practical production in mass production.

In addition, the installation of a head fuse in the body point for an interference fit does not exclude distortions, which is the reason for the aerodynamic braking of the grenade due to the nutation occurring on the flight path of an ammunition with a relatively low rotation speed. This affects the accuracy of fire and reduces the flight range of the fragmentation ammunition.

In the well-known grenade, an additional aerodynamic fairing is used to compensate for structural flaws, which is mounted in the sunset grooves of the cylindrical body adapter carrying the head fuse.

However, placing the main fuse on the grenade body reduces fragmentation due to the physical reduction in the number of annular rows of semi-finished fragments.

The problem to which the present invention is directed, is to simplify the design and manufacturing technology of ammunition and increase the efficiency of destination indicators.

The required technical result is achieved by the fact that a well-known shot for a grenade launcher containing a head fuse, a fragmentation shell with a bottom part filled with explosives, crushing locators, ring grooves made outside the shell and forming a sawtooth profile with jumpers 0.25-0 in longitudinal section , 45 wall thicknesses of the body, leading protrusions under the rifling of the barrel and propelling charge located in a combustion chamber fixed to the bottom of the body, in which nozzle openings are made a central igniter capsule is placed, wherein an obturator in the form of annular undercuts is formed on the outer surface of the combustion chamber, according to the invention it is provided with a sleeve adjacent to the inside of the housing, and the crushing locators are perforations made in the sleeve and located along the jumpers of the external sawtooth profile of the housing, part of the casing is autonomous and connected to the casing by landing with a guaranteed interference fit through the layer of epoxy sealant located in ring grooves of the body, and the head fuse is installed in the hole of the conical adapter, made integral with the body made of a tubular workpiece, while the leading protrusions are placed in the middle of the body.

Distinctive features have simplified the technology of manufacturing ammunition by mechanical cutting from a thin-walled tubular billet with the simultaneous formation of a conical adapter having an axial threaded bore for coaxial installation of the head fuse.

In this case, the aerodynamic shape of the head of the grenade is formed, which made it possible to exclude the aerodynamic fairing, thereby freeing up space for two additional corrugation belts, which increase the number of semi-finished striking elements of the grenade by a quarter in the same weight and size parameters.

The proposed simple structural scheme for the implementation of fracture localizers eliminates multi-junction pressing of the external and internal complex profiles with an expensive die tool with interoperable thermochemical processing.

The proposed design of the localizers is simple and effective in forming gas bridge wedges body directed at weak sections, along which it is transversely crushed into belts, provided that the radial crushing of the body during filling undermining is effective by definition.

Perforations in the cardboard sleeve during detonation of the filling form gas wedges aimed at deformation of weak sections of the housing in the jumpers, the thickness of which is optimized.

The connection between the autonomously manufactured bottom part of the body and the cutting corrugated along the outer surface to fit with guaranteed interference fit, through the layer of epoxy sealant in the annular grooves on the mating surface of the bottom part of the body, forms a monolithic strong joint, which does not collapse upon explosion. The bottom of the hull is crushed into fragments when undermining.

Performing corrugations on the outer surface of a tubular workpiece by cutting is technologically simpler than from the inside by any tricks.

An oil seal formed during assembly of a grenade shell with an epoxy sealant on the surface of combining the bottom with the body hermetically seals the internal volume of the grenade and additionally strengthens the connection of the connected parts into a constructive and functional monolithic unity.

Ring grooves (trapezoidal corrugations) on the outer surface of the hull, made deeper than the prototype (by definition, crushing the casing more effectively than similar corrugations from the inside), do not exert aerodynamic braking of the grenade in flight at speeds of 75-80 m / s, since the boundary layer of the oncoming flow with a conical adapter is detached from the munition contour.

Constructive improvements of the grenade determined a change in the mass ratio of the fragmentation shell and explosive filling in the direction of increasing the latter to increase the damaging fragmentation effect of the munition. In this case, the center of mass of the grenade shifted to the warhead, which determined the central location of the host device (finished protrusions under the rifling of the barrel, located in the middle of the body), for the longitudinal stabilization of the grenade during movement in the barrel.

Performing on the outer surface of the combustion chamber annular undercuts directed towards the head part, forms a gas-dynamic shutter from overconsolidated combustion products of the propellant powder charge in the prechamber of the weapon barrel, thereby providing obturation, preventing their irrational outflow. This achieves an increase in firing range, compared with the prototype, by 12%.

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

The invention is illustrated in the drawing, which shows the proposed shot for a grenade launcher.

In the housing 1 of the grenade a standard head fuse 2 of contact action is installed, the detonator capsule 3 of which is placed inside the explosive filling 4.

The head fuse 2 is axially located in the central threaded hole of the adapter 5 of a conical shape, which is made by turning a thick-walled tubular workpiece at the same time with the body 1.

On the outer surface of the housing 1 by mechanical cutting, a longitudinal row of trapezoidal annular grooves 6 is formed, forming jumpers of weakened section with a thickness of 0.25-0.45 of the thickness of the shell of the housing 1.

In a longitudinal section of the housing 1, the grooves of grooves 6 form a variable profile of a sawtooth-shaped grenade shell for organizing directional crushing into ring belts.

A cardboard cylindrical sleeve 7 with perforations 8 located symmetrically along the annular grooves 6 is placed inside the explosive filling 4 and the body 1; Perforations 8 serve as localizers for crushing the body 1 along the jumpers under the grooves 6, forming directional gas wedges of detonation products on the stress concentrator sawtooth profile one.

In the middle part of the housing 1, leading projections 9 are made, profiled for oblique rifling of the weapon barrel.

Self-made bottom part 10 is coupled with the housing 1 for landing with a guaranteed interference fit. Moreover, on the mating surface of the bottom part 10 there are two annular grooves 11, which are filled during assembly with the housing 1 with epoxy sealant 12, previously applied with a thin layer on the mating surfaces. The annular grooves 11 with an epoxy seal 12 act as an oil seal in the connection of the bottom 10 with the housing 1.

Epoxy sealant 12 after curing contributes to the rigid fastening of the housing 1 on the bottom 10 and seals their connection.

The bottom part 10 has an annular figured flange 13 protruding beyond the envelope, onto which the open end of the combustion chamber 14 is rolled, forming a grenade tail that is inseparable on the flight path.

The bottom of the combustion chamber 14 is a diaphragm with distributed nozzle openings 15.

The configuration of the shank corresponds to the profile of the prechamber of the barrel of the weapon, while on the outer surface of the combustion chamber 14 there are undercuts 16 directed towards the head part, which perform the functions of a shutter when firing.

The combustion chamber 14 is filled with a propellant powder charge 17, closed by a sealing gasket 18, made in the form of a leaf spring, on which the flange 13 of the bottom part 10 rests, pressing the propellant powder charge 17 in service as a cap.

In the diaphragm of the combustion chamber 14, a central igniter capsule 19 is mounted, which interacts with the propellant powder charge 17.

The finished profile of the leading protrusions 6, located in the middle of the housing 1, provides the grenade self-installation by sliding along the combat faces of the inclined rifling of the barrel during muzzle loading and centering the shot when moving along the barrel of the grenade launcher when firing. The width of the protrusions 6 is made comparable with the width of the inclined rifling in the barrel, with a guaranteed clearance, since the obturation is carried out by the shank of the grenade (undercuts 16 of the combustion chamber 14) in the fore chamber.

Ammunition is installed from the muzzle end of the barrel of the weapon, based on the leading protrusions 9 in the inclined rifling of the barrel. In this case, the foreign volume of the barrel of the weapon forms a low-pressure chamber for powder gases of a burning propellant powder charge 17.

When firing, the pulse from the igniter capsule 19 sets fire to the powder charge 17, the combustion products of which through nozzle openings 15 of the diaphragm of the combustion chamber 14 flow into the prechamber of the gun barrel, where they accumulate, since a gas-dynamic shutter is formed in the annular undercuts 16 from the re-compacted gaseous products of charge combustion 17, which obturates the radial clearance between the shank of the grenade and the prechamber of the gun barrel.

Under the influence of the pressure of the powder gases in the prechamber, the grenade shaft translates with its rotation along the grooves in the barrel through the interaction of the leading protrusions 9. The grenade is accelerated and twisted (sufficient for longitudinal stabilization in flight) along the length of the shank, while the initial rotation speeds and linear reach setpoints.

When meeting an obstacle, an inertial-reaction fuse 2 is triggered, the detonation of the explosive 4 is initiated by an impulse from the detonator capsule 3.

Trapezoidal circular grooves 6 formed by cutting create stress concentrators in the housing 1 and form plastic shear planes along which transverse destruction of the housing 1 occurs when loading with shock and detonation waves from the explosion of filling 4.

Longitudinal crushing of the housing 1 along the webs of the section weakened by annular grooves 6 occurs under the action of pointed gas wedges formed by perforations 8 of the sleeve 7, crushing localizers.

Thus, a sawtooth profile of the outer surface of the casing 1, formed by rows of annular grooves 6, and symmetrical perforations 8 of the sleeve 7 adjacent to the casing 1 from the inside, form a variable thickness of the collapsible shell along the weakened sections of the directional energy of the detonation products of the explosive 4, providing specified crushing with the formation of damaging elements of the necessary mass and shape.

Tests of prototype grenades of the proposed design were carried out in accordance with GOST B 25430-82 in an armored tank with sawdust traps.

Fragmentation analysis was carried out using the initial spectra estimation technique that implements the complex: histogram construction, phase selection, mass balance approach and a new priority determination by the sum of places (arithmetic mean and probabilistic, according to the lower limit).

Comparative fragmentation tests of the proposed design and the grenade of the prototype confirmed the superiority of the grenade according to the invention.

At the same time, the separate production of elements of organized crushing of a grenade body into fragments in the form of annular grooves of the outer surface by turning from a tubular workpiece using crushing locators from the inside in the form of perforations of a cardboard sleeve significantly simplified the technology for producing ammunition while significantly reducing the cost of work and capital investment.

This is also facilitated by the autonomous manufacture by cutting the bottom of the hull and the exclusion of the head fairing.

Assembling a grenade from simple structural elements does not require special highly skilled workers.

After state tests in the prescribed manner, the proposed grenade for an under-barrel grenade launcher can be recommended for service in the troops.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the invention does not explicitly follow for an ammunition specialist, showed that it is not known, and taking into account the possibility of industrial serial production of artillery cartridges for a grenade launcher, it can be concluded that the patentability criteria are met .

Claims (1)

A shot for a grenade launcher containing a head fuse, a fragmentation shell with a bottom filled with explosive, crushing locators, ring grooves made on the outside of the shell and forming a sawtooth profile with jumpers 0.25-0.45 in thickness of the shell wall, leading protrusions under the rifling of the barrel and the propellant charge located in the combustion chamber fixed on the bottom of the housing, in which nozzle openings are made and a central igniter capsule is placed, while to the outside An obturator in the form of annular undercuts is formed on the surface of the combustion chamber, characterized in that it is equipped with a sleeve adjacent to the inside of the body, and crushing locators are perforations made in the sleeve and located along the jumpers of the external sawtooth profile of the body, and the bottom of the body is autonomous and connected with a landing housing with a guaranteed interference fit through a layer of epoxy sealant located in the annular grooves of the housing, and the head fuse is installed in the hole of the conical adapter, made integral with the housing made of a tubular workpiece, while the leading protrusions are placed in the middle of the housing.