RU77675U1 - ARTILLERY SHOT - Google Patents

Abstract

The utility model relates to ammunition for anti-personnel automatic grenade launchers and can be used in the manufacture of artillery rounds of unitary loading of small caliber, having an increased range and accuracy of fire. An artillery shot contains a head fuse, a fragmentation projectile with a conical shank and leading protrusions of body material filled with explosive, and a sleeve mounted on the shell end of the projectile, including a powder propellant charge and an axial igniter capsule. What is new is that the leading protrusions are made in the form of ring grooves of a trapezoidal profile, the bases of which are located in the transverse groove of the housing, and the grooves on the shell of the shell under the roll barrel roll are connected by longitudinal channels with the surface of the conical understatement of the shank diameter rearward, while the transverse groove under the leading protrusions the shell body is made with a depth determined from the ratio d / d = 1.04-1.05, where d is the diameter of the caliber of the shell, d is the diameter of the groove, while the riffles are spaced apart from each other and from the edges of the groove yanii of 0.8-1.2 base width riffle. The proposed technical solution ensured the achievement of increased targets for the artillery firing in terms of flight range and accuracy of the projectile’s flight to the target due to more efficient obturation of gunpowder gases generated during the propellant’s combustion and additional longitudinal stabilization of the projectile along the flight path.

Description

The utility model relates to ammunition for anti-personnel automatic grenade launchers and can be used in the manufacture of small-caliber unitary artillery rounds with increased range and accuracy of fire.

The level of this technical field is characterized by the construction of a small-caliber artillery cartridge according to the patent RU 2087837, F42В 5/02, 1997, which includes a grenade containing a head fuse, explosive filling of a fragmentation shell equipped with crushing concentrators, a copper lead belt and a rectangular shaped shank with longitudinal through channels for air outlet from the barrel of the cartridge case when installing the grenade by press fit on the mating sleeve ledge.

An igniter capsule, a propellant propellant charge and a diaphragm with 0.05 mm thick burning foil gaskets are mounted in the sleeve. The diaphragm has calibrated outlet openings for the release of propellant gases of a propellant charge into the receiver, formed between the end face of the grenade and the diaphragm of the sleeve.

The diaphragm is rigidly connected to the sleeve by means of a geometric closure of the material of the annular notch of the support ledge in the sleeve of the sleeve. In this case, the diaphragm presses and fixes the propellant charge in the sleeve through the lower gasket.

The upper gasket on the diaphragm during cartridge assembly prevents the transfer of compressed air pressure to the propellant powder charge, which is removed from the receiver through the longitudinal channels of the grenade shaft.

The grenade with the sleeve is connected by crimping the barrel muzzle into the sunset grooves of the shank, forming the constructive unity of the unitary shot to the grenade launcher.

The disadvantage of the described ammunition is the implementation of the host device in the form of a pressed copper belt and a rectangular shape of the shank of the grenade.

Separately manufactured copper rings and the press operation of their fastening on the shell of the projectile into a profiled groove complicates the technology. But the biggest problem at the same time is the possible breakdown of the leading copper belt in the bore when firing with the ensuing consequences.

In the bottom of the grenade, which has a rectangular shape of the shank, turbulent turbulent airborne cross-flow flows arise, which aerodynamically slow down the flight speed and reduce the firing range.

The noted shortcomings were eliminated in artillery shots at

patents RU 2168696, F42В 14/00, 2001 and 2125226, F42В 5/02, 1999, the shells of which are equipped with a master device in the form of ready-made protrusions from the body material (steel), profiled under the spiral channels of the barrel of the weapon.

The shank of the projectile according to the first patent is made in the form of a truncated cone, tapering rearward, to reduce aerodynamic drag from the reduction of back-pressure rarefaction by eliminating the turbulence of the incoming flow on the flight path.

As the closest analogue in terms of the number of matching features, the cartridge (shot) for a grenade launcher according to patent RU 2125226, F42B 5/02, 1999, the artillery shell of which containing a head fuse, carries a propellant powder charge combustion chamber on the tail, which serves as a cartridge case, was selected .

The fragmentation shell of the projectile filled with explosive is equipped with crushing locators in the form of sawtooth grooves and ready-made leading protrusions from the body material (steel), profiled to interact with spiral grooves of the barrel of the weapon.

The combustion chamber is closed by an end diaphragm carrying a central igniter capsule.

The well-known artillery shell is characterized by increased efficiency of the main fragmentation action and manufacturability.

A feature of this projectile is the presence of ready-made protrusions on the body for guiding along the spiral cuts of the barrel, as a result of which the projectile is axially rotated during firing to stabilize along the flight path.

However, a continuation of the advantages is the inherent disadvantages, in particular: the gaseous products of the combustion of the propellant charge break through the relatively large gaps between the spiral rifling of the barrel and the finished leading protrusions of the projectile body, which reduces its initial velocity and also unevenly presses on the side surface of the projectile body, which significantly affects uncontrolled vibrational disturbances of the projectile, worsening the accuracy of the battle.

In addition, the configuration of the known shot is not aerodynamically optimized, which causes the occurrence of backward turbulence of airborne cross-border flows that inhibit the ammunition on the flight path, thereby significantly reducing the firing range.

The task, which the real utility model is aimed at, is to improve the design of the artillery shot to increase targets, basic technical characteristics.

The required technical result is achieved by the fact that in a well-known artillery shot containing a head fuse, a fragmentation shell with a conical shank and leading protrusions from the body material,

filled with explosive material, and a sleeve mounted on the shank of the projectile, including a propellant propellant charge and an axial igniter capsule, at the suggestion of the authors, the leading protrusions are made in the form of at least two ring grooves with a trapezoidal profile, the bases of which are located in the transverse groove of the body, and the grooves on the shell of the shell under the roll of the dulse, the sleeves are communicated by longitudinal channels with a surface of a conical understatement of the shank diameter to the rear, with a transverse groove for the leading protrusions of the housing series made depth, determined from the ratio d / d ₁ = 1,04-1,05 where d - diameter of the projectile caliber, d ₁ - diameter of the groove, the riffles are spaced from each other and the edges of the groove at a distance of 0.8 -1.2 width of the base of the grooves, and the angle of inclination behind the generatrix of the conical surface of the shank is 15-20 °.

Distinctive features ensured the achievement of increased targets for the artillery firing in range and accuracy of flight to the target due to more efficient obturation in the barrel bore of gunpowder gases generated during propellant combustion provided by the new shape and geometry of the host device, as well as by optimizing the aerodynamic shape of the munition and the proposed constructive relationship of the liner with the shank of the projectile.

The implementation of the protrusions of the host device from the material of the shell body in the form of ring riffles ensures their gapless adjacency to the spiral cuts of the barrel when firing due to extrusion of the working grooves across the riffles directly by the configuration of the barrel channel, which virtually eliminates the breakthrough of powder gases. This ensures the complete conversion of the energy of the pressure of the powder gases into the projectile into a propelling impulse, creating an increment in its initial velocity.

The presence of at least two annular flutes of the projectile’s lead device, which allow to distribute the dynamic loading of the insertion, is necessary to create a gas-dynamic shutter between them of re-compressed gaseous products of combustion of the propellant charge, which prevents the breakthrough of gases along the barrel behind the projectile, that is, a reliable obturation is automatically carried out.

Placing ring corrugations in the transverse groove of the casing allows the projections to be made in the dimensions of the projectile by redistributing the metal of the casing when rolling a given profile with a roller, providing sufficient strength and the necessary plasticity of the corrugations.

Due to the exclusion of the breakthrough of powder gases through the minimum clearance clearance between adjacent leading ledges and the barrel, the disturbing vibrations of the projectile during movement along the barrel decreased, which, as a result, increased the accuracy of the battle and the firing range.

The trapezoidal profile of the riffles ensures their smooth implementation in the rifling of the barrel during firing, which reduces the thickness of the deformable

parts of the corrugations and reduce the load on the combat faces of the spiral rifling of the trunk, the stability of which increases.

A wider base of the riffles provides the necessary bearing strength, and a narrower top of the riffles allows you to reduce the friction force when cutting along the combat faces of spiral rifling of the barrel, the wear of which is reduced.

The placement of the trapezoidal profile grooves in the transverse groove of the projectile body, below its calibrating diameter, is dictated by the operating conditions of the host device: on the one hand, the need to preserve the structural bearing strength during the dynamic formation of a screw pair element from the grooves, and on the other hand, to provide elastic ductility of the impact deformation of the material when implantation into spiral rifles of the barrel of a weapon.

The squeezed metal of the riffles, when they are inserted into the spiral rifling of the barrel, does not fall into the gap between the centering bulge of the projectile and the surface of the barrel channel, but is placed in the transverse groove of the body, behind the riffles, and carried out, which prevents unproductive abrasive wear of the weapon.

The possible formation of riffles by cutting by means of a profile comb is characterized by a large waste of allowance of the body metal in the chips and, most importantly, requires additional local chemical-thermal treatment of the formed protrusions to give them the necessary plasticity, which is associated with costs and the organization of auxiliary labor-intensive production.

The depth of the transverse groove of the shell of the shell under its leading ring flutes was calculated according to the mathematical model of the planning of the experiment, and testing by firing prototypes of artillery shells with a trapezoidal shape with leading corrugations of metal of the shell, optimized geometric parameters, confirmed the correctness of the selected diameter ratio d / d ₁ = 1, 04-1,05, caliber (centering thickening) and grooves respectively.

When the ratio of said diameters d / d ₁ 1.04 less loss grows propellant pulse infeed riffle not provided obturation sleeve propellant powder charge gases have been widely riffle height sufficient for functioning as intended. In addition, in the shallow groove the "fragments" of the metal of the riffles formed during their introduction into the rifling of the trunk are not completely placed, which is unacceptable in principle.

When the ratio d / d _{1 is} more than 1.05, the mechanical strength of relatively high flutes is unsatisfactory, which, when dynamically inserted, bend and do not provide obturation.

The equality of the gaps between the flutes and the edges of the transverse groove in which they are located is determined by the manufacturing technology of the master device by rolling due to the redistribution of the metal of the body.

In the gap between the riffles, the volume of which serves as a receiver for

gunpowder gases of the propellant charge of the shell with the throttling of the latter in the travel slots between the master and the barrel, a gas-dynamic shutter is formed, which locks the protrusion of the projectile like a cuff, thereby eliminating gas leakage.

When the size of the mentioned gaps is more than 1.2 of the width of the base of the riffles, the re-compaction of powder gases does not occur and therefore a gas-dynamic shutter is not formed, which is the reason for reducing the firing range.

The width of the gaps less than 0.8 of the width of the base of the corrugations does not provide the physical volume to accommodate the cut metal of the annular leading corrugations when they are introduced during the shot into the spiral grooves of the barrel. At the same time, no gas-dynamic shutter is formed, which prevents the propellant gases from breaking through the propellant charge behind the projectile.

As a result of the almost gapless (in landing approach) relationship of the formed profile of the riffles, when directly introduced during firing into the spiral rifling of the barrel, radial beats and nutation of the projectile while moving in the barrel channel are minimized, which inevitably increases the accuracy of the battle.

The execution on the projectile shank of the longitudinal channels of communication of the sleeve for the roll of the barrel of the barrel with the conical surface of lowering the diameter of the shaft of the rear is necessary for the technological exit of compressible air from the barrel of the barrel during the assembly of the shot, and also additionally provides longitudinal stabilization of the projectile along the flight path.

In the longitudinal channels, the incoming flow forms compressed air jets that shift the center of pressure beyond the center of mass and serve as an aerodynamic stabilizer in flight.

The angle of inclination of the back of the generatrix of the conical surface of the shank of the projectile in the range of 15-20 ° is optimal to prevent backwater turbulence of cross-border flows at subsonic flight speeds.

Therefore, each essential 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 stated technical problem is solved not by the sum of the effects, but by a new super-effect of the sum of the attributes.

The essence of the utility model is illustrated by the drawing, which shows;

figure 1 - General view of the artillery shot;

figure 2 is a view of figure 1;

figure 3 is a view along arrow B in figure 2.

An artillery shell 1 has a head fuse 2 mounted in a housing 4 filled with explosive 3, which is made of a sawtooth profile for the chamber

the formation of a grid of semi-finished fragments during crushing.

Shell 1 shank mounted on the ledge 5 of the sleeve 6 and secured by crimping its dulza 7 into the sunset grooves 8 of the housing 4.

In the transverse groove 9 (FIG. 2) of the shell 4 of the projectile 1, at least two annular leading protrusions 10 (trapezoidal grooves) are formed from its material.

The depth of the transverse groove 9 relative to the centering thickening (caliber) of the projectile 1 is determined from the ratio: d / d ₁ = 1.04-1.05, where d is the diameter of the caliber, ad ₁ is the diameter of the groove 9.

In this case, the flutes 10 are separated from each other and from the edges of the groove 9 at a distance selected in the range of 0.8-1.2 of the width of the annular protrusions 10 formed from the metal of the housing 4.

The butt end of the projectile 1 is made conical with an inclination angle of the generatrix rearwardly β = 15-20 ° in order to prevent breakdowns of the border layer of the incoming flow on the flight and the accompanying turbulence in the backside, which create aerodynamic drag of the projectile 1. That is, the implementation of the projectile 1 conical with an optimized tilt to the rear helps to increase the firing range.

Moreover, on the conical surface of the shank of the projectile 1, longitudinal channels 11 of communication with the sunset grooves 8 of the housing 4 are made (FIGS. 2 and 3), which in flight additionally provides longitudinal stabilization of the projectile 1 due to the formation of longitudinal air jets in them that serve as gas rudders for aerodynamic stabilization of the projectile 1 in flight.

In the longitudinal channels 11 during the assembly of the projectile 1 with the sleeve 6, the expelled air is removed from the latter. It is known from practice that without the described channels 11, the compressed air in the sleeve 6 during storage of the shot gradually displaces the projectile 1 from the barrel 6 of the sleeve 6 by 1-2 mm, which makes the shot unsuitable for shooting, since it does not fit in the bolt.

In the sleeve 6 there is placed a central igniter capsule 12 and a powder propellant charge 13, closed by a diaphragm 14, which is geometrically closed and pressed by rolling the material of the notch of its ledge 5. At the same time, a receiver 15 is formed between the diaphragm 14 and the end face of the projectile 1, into which combustion products enter propellant charge 13.

The proposed shot functions as follows. Upon initiation of the igniter capsule 12, a powder propellant charge 13 is ignited by the force of the flame, during combustion of which gaseous products are actively generated, which enter the receiver 15, where they are mixed and accumulated.

The increased pressure of the powder gases in the receiver 15, the projectile 1 is removed from the barrel 7 of the sleeve 6 and is dynamically longitudinally fed into the barrel of the weapon, where the ring riffles 10 sequentially interact with the combat faces of its spiral cuts.

Steel ring flutes 10 are embedded in spiral grooves

trunk, through which leading grooves are cut. Metal chips from the grooves formed in the flutes 10 are extruded into the gaps between the flutes 10 and between the second flute 10 along the edge and the edge of the groove 9.

The formed crest-like profile of the riffles 10 adjoins the surface of the spiral grooves of the barrel and then performs the functions of leading and obturating protrusions of the shell 4 of the projectile 1, which carry out the kinematic connection of the formed screw pair: as a lead screw, the projectile 1 with its leading profiled protrusions 10 interacting with the fixed nut - spiral rifling of the trunk. When moving along the trunk, under the influence of increasing pressure of the powder gases of the burning propellant charge 13, the projectile 1 receives axial rotation, which provides its gyroscopic longitudinal stabilization on the flight path to the target.

Experienced firing of artillery shells at a utility model showed an actual increase in range and accuracy of the battle within 5-7%. At the same time, the complexity of manufacturing a projectile on existing equipment was reduced by 18%.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the utility model does not explicitly follow for the specialist in artillery ammunition, showed that it is not known, and taking into account the possibility of industrial serial production of artillery shots in existing production, we can conclude eligibility criteria.

Claims (3)

1. An artillery shot containing a head fuse, a fragmentation shell with a conical shank and leading protrusions made of a shell material filled with explosive, and a sleeve fixed to the shank of the shell, including a powder propellant charge and an axial igniter capsule, characterized in that the leading protrusions are made in at least two ring grooves of a trapezoidal profile, the bases of which are located in the transverse groove of the body, and the grooves on the shell of the shell for the roll of the barrel of the shell are communicated about Aulnay channels with tapered surface understating posterior diameter of the shank. 2. An artillery shot according to claim 1, characterized in that the groove for the leading protrusions of the projectile body is made with a depth determined from the ratio d / d ₁ = 1.04-1.05, where d is the diameter of the caliber of the projectile, d ₁ is the diameter of the groove , while the riffles are separated from each other and from the edges of the grooves at a distance equal to 0.8-1.2 of the width of the base of the riffles. 3. An artillery shot according to claim 1, characterized in that the angle of inclination to the rear of the generatrix of the conical surface of the shank is 15-20 °.