RU139931U1 - Artillery shell - Google Patents

Abstract

1. An artillery shell containing a steel body with centering thickenings and a leading belt made integrally with the body and of its material, in the form of a set of annular grooves separated by annular protrusions, the volume of these annular protrusions being above the level of the centering bulges is less than the volume of the annular grooves below the level of the centering bulges, characterized in that on the surface of the vertices of the annular protrusions of the leading belt formed alternating perforation recesses or annular anavki.2. An artillery shell according to claim 1, characterized in that an antifriction coating is applied to the surface of the vertices of the annular protrusions of the driving belt. An artillery shell according to claim 2, characterized in that the alternating perforation recesses or annular grooves located on the surface of the vertices of the annular protrusions of the driving belt are filled with an antifriction composition. An artillery shell according to claim 3, characterized in that the annular grooves of the driving belt, located between the annular protrusions of this belt, are filled with an antifriction compound.

Description

The utility model relates to military equipment and can be used in the development and modernization of ammunition of artillery and small arms.

A known design of an artillery shell containing a body with centering thickenings and a solid copper lead belt (see EK Larman "Design and manufacture of artillery systems", 4.1, Military publishing house, M, 1949, p. 258, Fig. 97).

The disadvantage of this artillery shell is the presence of high pressure in the contact "leading belt of the projectile - the barrel of the gun" and the formation of "fringe" from the drift to the trailing edge of the leading belt of a significant amount of material from the deformation of the leading belt by the rifled field of the gun barrel while the leading belt enters into the rifled barrel channel guns.

Also known is the design of an artillery shell containing a body with centering thickenings and a copper lead belt with grooves (ring grooves) (see ibid. P. 260, Fig. 99), the bottom of which is located above the centering thickenings of the shell of the shell, i.e. the depth of the grooves of the driving belt is less than the depth of the cut of the channel of the gun barrel. When entering the grooves of the channel of the gun’s barrel, the material of the driving belt, the specified artillery shell, deformed by the groove field, is placed in the grooves, thereby preventing the formation of a “fringe”.

However, even in this artillery shell, the lead belt begins to interact with the rifle field along its entire width even before the end of the process of cutting the belt into the rifling of the gun barrel channel, which causes high pressure in the contact "lead belt of the projectile - gun barrel".

Closest to the proposed artillery shell is the adopted for the prototype artillery shell for rifled weapons (see patent RU 2382325 C2, F42B 14/02, F42B 30/08, 01/21/2008), containing a body, the cylindrical part of which performs the function of centering thickenings , with a leading girdle made of body material in the form of a sequence of annular projections (ridges) aligned with it, separated by annular grooves, the depth of the annular grooves is not less than the working height of the leading girdle, and the volume of each groove is selected from the condition of free displacements of the material of protrusions displaced in them during a shot during the formation of the leading protrusions, which leads to the absence of a “fringe”. To further reduce barrel wear, an antifriction coating is applied to the surface of the protrusions of the steel drive belt. This design of the artillery shell completely eliminates the dismantling of the leading belt behind the muzzle of the gun. The use of the material of the shell of the shell (steel 20) as the material of the leading belt increased the loading ability of the leading protrusions and, as a result, led to an increase in the range and accuracy of fire. The exclusion from the design of the lead belt of copper and operations associated with the manufacture, control and installation of the lead belt as a separate element, reduced the complexity of manufacturing the shell of the shell by 7-10%.

However, for the indicated artillery shell, the problem of reducing the pressure in the contact between the leading shell of the projectile and the barrel of the gun remains relevant, despite the fact that the formation of combat protrusions on the leading belt of this artillery shell has reduced the volume of the material of the annular protrusions deformed by the rifling fields, free, without jamming the flow of this material into the annular grooves, an antifriction coating is applied to the surface of the annular protrusions of the driving girdle. The presence of high pressure in the contact "leading belt of the projectile - the barrel of the gun" is due to the fact that the mechanical characteristics of the steel, the material of which the ring protrusions of the leading belt of this artillery shell are formed, is much higher compared to copper, the material of the standard leading belts, which is the reason the presence of a fairly high pressure in the contact "leading belt of the projectile - the barrel of the gun" when plunging, increased wear of the inlet part of the bore and significant resistance to the movement of the projectile along the bore.

The problem solved by the proposed utility model is to reduce the pressure in the contact "leading belt of the projectile - the barrel of the gun" when the leading belt of the artillery shell enters the grooves of the barrel and reducing the resistance to movement of the projectile along the barrel.

The problem is achieved in that in the proposed artillery shell containing a body with centering thickenings and a leading belt made integrally with the body and of its material, in the form of a set of annular grooves separated by annular protrusions, the volume of these annular protrusions being above the level of the centering thickenings , less than the volume of the annular grooves below the level of the centering thickenings, alternating perforations are formed on the surface of the vertices of the annular protrusions of the driving girdle recesses or circumferential grooves.

The problem is also achieved by the fact that in the proposed artillery shell containing a body with centering thickenings and a leading belt made integrally with the body and of its material, in the form of a set of annular grooves separated by annular protrusions, the volume of these annular protrusions being above the level of the centering thickenings , less than the volume of the annular grooves below the level of the centering bulges, on the surface of the vertices of the annular protrusions of the leading girdle, on which alternating perforations are formed recesses or annular grooves, anti-friction coating.

The problem is also achieved by the fact that in the proposed artillery shell containing a body with centering thickenings and a leading belt made integrally with the body and of its material, in the form of a set of annular grooves separated by annular protrusions, the volume of these annular protrusions being above the level of the centering thickenings , less than the volume of annular grooves below the level of centering bulges, alternating perforations or annular grooves located on the surface of the vertices of the annular The protrusions of the leading belt are filled with an antifriction compound.

The problem is also achieved by the fact that in the proposed artillery shell containing a body with centering thickenings and a leading belt made integrally with the body and of its material, in the form of a set of annular grooves separated by annular protrusions, the volume of these annular protrusions being above the level of the centering thickenings less than the volume of the annular grooves below the level of the centering bulges, the annular grooves of the driving girdle located between the annular protrusions of this girdle, on the surface of the top on which alternating perforations or annular grooves are formed, are filled with an antifriction compound.

The essence of the utility model is illustrated by drawings, where in FIG. 1 shows the design of the proposed artillery shell; in view A of FIG. 1 is a fragment of the shell of an artillery shell with a centering thickening and a leading belt made integrally with the shell and of its material and consisting of annular grooves separated by annular protrusions, on the surface of the vertices of which alternating annular grooves are formed; in FIG. 2 - a fragment of the annular protrusion of the leading belt with alternating perforations in the apex; in FIG. 3 - a fragment of the annular protrusion of the leading belt with alternating annular grooves at the top and an anti-friction coating applied to it; in FIG. 4 is a fragment of the annular protrusion of the leading belt, on the top of which an antifriction coating is applied and alternating annular grooves are formed on it, which are filled with antifriction composition; in FIG. 5 is a fragment of the body of the proposed artillery shell with a centering thickening and a leading belt made integrally with the body and of its material and consisting of annular grooves separated by annular protrusions, on the tops of which alternating annular grooves are formed, with an annular groove between the annular protrusions of the driving belt, filled anti-friction compound; in FIG. 6, 7, 8 — stage-by-stage diagrams of the interaction of the leading belt of the proposed artillery shell with the channel of the gun barrel during the shot (during the formation of the depression between the military protrusions on the leading belt).

The proposed artillery shell (Fig. 1) has a housing 1 with a leading belt 2 and centering thickenings 3; centering thickenings 3 (type A of Fig. 1) located on the housing 1 have a diameter d (projectile caliber), the leading belt 2, consists of a set of annular grooves 4, separated by annular protrusions 5, which are made integrally with the housing 1 and from its material , the volume V _{K of the} annular grooves 4 of the driving girdle 2 located below the level of the centering bulges 3 (below the diameter d) exceeds the volume V _{B of the} material of the annular protrusions 5 of the driving girdle 2 located above the level of the centering bulges 3 (above the diameter d) (V _K > V _B ), on the surface of the peaks 6 protrusions 5 alternating annular grooves 7 are formed; on the surface of the peaks 6 (Fig. 2) of the protrusions 5 alternating perforation recesses 8 are formed; on the surface of the peaks 6 (Fig. 3) of the annular protrusions 5 with alternating annular grooves 7 applied antifriction coating 9; antifriction coating 9 is applied to the surface of the peaks 6 (Fig. 4) of the annular protrusions 5, and the alternating annular grooves 7 located on this surface are filled with an antifriction composition 10; an annular groove 4 (Fig. 5) between the annular protrusions 5, on the surface of the peaks 6 of which alternating annular grooves 7 are formed, of the driving belt 2 located on the housing 1 of the proposed artillery shell, is filled with antifriction composition 11; case 1 (Fig. 6) of the proposed artillery shell supported by centering thickenings 3 on the grooves field 12 is placed in the channel of the gun barrel 13, the first in the direction of movement of the annular protrusion 5 with alternating annular grooves 7 on the top surface 6 locks the barrel 13 in the inlet cone 14 guns; the second in the direction of the movement of the annular protrusion 5 (Fig. 7) with alternating annular grooves 7 on the top surface 6 abuts against the inlet cone 14 of the channel of the gun barrel 13, in the annular groove 4 between the annular protrusions 5 and the surface of the inlet cone 14 a closed cavity 15 was formed, the first in the direction of movement, the annular protrusion 5 is deformed by a conical slope 16 of the rifling field 12, the material of this protrusion 5, located below the conical slope 16 of the rifling field 12, entered the annular grooves 4; due to advancing along the bore 13 (Fig. 8), the annular protrusions 5 are deformed by a conical slope 16 of the rifling field 12 of the gun bore 13 of the gun, the volume of the closed cavity 15 formed in the annular groove 4 and bounded by the annular protrusions 5 and the surface of the bore 13 decreased due to the entry into it of the material of the annular protrusions 5, located above the level of the rifling field 12 of the channel of the gun barrel 12, and the rifling field 12 itself.

The proposed artillery shell operates as follows:

- artillery shell (Fig. 1), containing the housing 1 with centering thickenings 3 and the leading belt 2, consisting of a set of annular grooves 4 (type A of Fig. 1) separated by annular protrusions 5, which are made together with the housing 1 and from its material, with support centering thickenings 3 on the field of the grooves 12 (Fig. 6) is placed in the bore 13, an annular protrusion 5 with alternating annular grooves 7 or perforation recesses 8 (Fig. 2) on its apex surface 6, locks the inlet cone 14 of the bore 13 guns, providing poro obturation gas gases; when fired, the hull 1 (Fig. 7) of the proposed artillery shell starts moving along the bore 13 of the gun, the second annular protrusion 5 on the surface of the peaks 6 of which alternating annular grooves 7 are made, abuts against the inlet cone 14 of the channel of the gun 13, forming a closed cavity 15 in the annular groove 4, bounded by annular protrusions 5 and the surface of the inlet cone 14 of the channel of the gun barrel 13, the material of the first in the direction of the annular protrusion 5, deformable by the inlet cone 14, and subsequently conical with them, slopes 16 of the rifling fields 12, moves into alternating annular grooves 7 on the surface of the peaks 7, then, as the alternating annular grooves fill on the surface of the top 6 of the annular protrusion 5, the conical slopes of the 16 rifling fields 12 begin to deform the middle part of this annular protrusion 5, forming depressions between the military protrusions on the leading belt, the material of the annular protrusion 5, deformable by conical slopes 16 of the rifling fields 12, freely, without jamming, because the volume V _{K of the} annular grooves 4 of the driving girdle 2 located below the level of the centering bulbs 3 exceeds the volume V _{B of the} material of the annular protrusions 5 of the driving girdle 2 located above the level of the centering bulges 3 (V _K > V _B ), moves into the annular grooves 4 (FIG. 8), the deformation of the second and subsequent annular protrusions 5 of the leading belt 2 occur similarly to that described above;

- applying an antifriction coating 9 (Fig. 3) to the surface of the peaks 6 of the annular protrusions 5 of the leading belt 2 of the proposed artillery shell (Fig. 1), on which alternating annular grooves 7 or perforation recesses 8 (Fig. 2) are formed, improves the process of forming a cavity between the protrusions on the leading belt (Fig. 6, 7 and 8) when inserted, improves the flow of material of the annular protrusions 5 of the leading belt, deformable by the entry cone 14, and subsequently by the conical slopes 16 of the rifling fields 12, into the annular grooves 4, reduces friction in contact "leading belt of the projectile - gun barrel";

- filling with an antifriction compound 11 (Fig. 4) of alternating annular grooves 7 or perforation recesses 8 (Fig. 2) formed on the surface of the peaks 6 of the annular protrusions 5 of the leading belt 2 of the proposed artillery shell (Fig. 1) leads to the fact that, when cutting in the process of forming a depression between the military protrusions on the leading belt (Fig. 6, 7 and 8) in the contact zone of the leading belt of the projectile with the gun barrel microcavities are formed with antifriction composition 10 under high pressure, from which this composition comes to the contacting surfaces of the barrel and the leading belt, forming a separation-lubricating medium, which improves the formation of a depression between the combat protrusions on the leading belt, improves the material flow of the annular protrusions 6 of the leading belt into the annular grooves 4 when they are deformed in the entry cone 14, and subsequently conical slopes 16 fields of rifling 12, relieves contact surfaces, reduces friction between them;

- filling the annular groove 4 located between the annular protrusions 5 with alternating annular grooves 7 or perforation recesses 8 (Fig. 2) at their peaks 6, the leading belt 2 of the proposed artillery shell (Fig. 1) with an antifriction compound 11 (Fig. 5) leads to the fact that in the process of forming a depression between the military protrusions on the leading belt (Fig. 6, 7 and 8) when cutting the antifriction composition 11 is locked in a closed cavity 15 formed in the annular groove 4, limited by the annular protrusions 5 of the leading belt and beyond a traveling cone 14 of the channel 13 of the gun, further advancement of the hull 1 of the proposed artillery shell along the channel of the gun 13 reduces the volume of this cavity 15, where the antifriction composition 11 is locked (due to the entry of the material of the annular protrusions 5, deformable by the rifling fields and the rifling fields 12 themselves ), which causes an increase in pressure in this cavity and the displacement of the antifriction composition 11 to the contacting surfaces of the barrel and the leading belt, forming a separation-lubricating medium that significantly improves the process The hollow between the protrusions on the driving belt improves the material flow of the annular projections 5 of the driving belt into the annular grooves 4, relieves the contacting surfaces and reduces friction between them.

Thus, the proposed artillery shell containing a housing with centering thickenings and a leading belt made integrally with the housing and from its material, in the form of a set of annular grooves separated by annular protrusions, and the volume of these annular protrusions, which is above the level of the centering thickenings, is less than the volume of the annular grooves below the centering bulge by forming alternating perforations or ring grooves on the surface of the vertices of the annular protrusions of the driving girdle wok, reducing the volume of deformable material at the annular projections forming lugs on them during insertion, provides a lower level of contact pressure "leading projectile girdle - gun barrel" because this pressure is directly proportional to the volume of the material being deformed, and a decrease in contact pressure leads to a decrease in resistance to the movement of the projectile along the barrel, because resistance to movement is directly proportional to contact pressure. The use of an antifriction coating on the surface of the vertices of the annular protrusions of the leading belt leads to an improvement in the process of forming a depression between the fighting protrusions on the leading belt, improves the material flow of the annular protrusions of the leading belt into the annular grooves, and reduces friction in the contact of the "leading belt of the projectile - gun barrel", which also helps to pressure in the contact "leading belt of the projectile - gun barrel" and resistance to the movement of the projectile along the channel of the gun barrel. The use of antifriction compounds to fill alternating perforations or annular grooves on the apex surface of the annular protrusions of the drive belt, as well as to fill the annular grooves between the ring projections of the drive belt, contributes to the formation of a self-regulating friction-adapted pair in the contact zone of the “projectile shell - gun barrel” that significantly reduces friction in the contact "leading belt of the projectile - the barrel of the gun" and also helps to reduce the pressure in the contact of the leading belt with aryada - barrel of the weapon "and resistance to movement of the projectile through the channel of the gun barrel.

In addition, the design of the proposed artillery shell allows:

- increase the firing range due to the increase in the initial velocity of the projectile, obtained by reducing the resistance to the movement of the projectile along the channel of the gun barrel during the shot;

- to reduce the overall wear of the barrel of the gun and the combat protrusions of the leading belt of the artillery shell, since the anti-friction composition under high pressure enters the contact zone "leading belt of the shell

- gun barrel ”and forcibly lubricates these contacting surfaces during the shot.

Claims (4)

1. An artillery shell containing a steel body with centering thickenings and a leading belt made integrally with the body and of its material, in the form of a set of annular grooves separated by annular protrusions, the volume of these annular protrusions being above the level of the centering bulges is less than the volume of the annular grooves below the level of the centering bulges, characterized in that on the surface of the vertices of the annular protrusions of the leading belt formed alternating perforation recesses or annular anavki. 2. An artillery shell according to claim 1, characterized in that an antifriction coating is applied to the surface of the vertices of the annular protrusions of the driving belt. 3. An artillery shell according to claim 2, characterized in that the alternating perforation recesses or annular grooves located on the surface of the vertices of the annular protrusions of the driving belt are filled with an antifriction composition. 4. An artillery shell according to claim 3, characterized in that the annular grooves of the driving belt located between the ring protrusions of this belt are filled with an antifriction compound.

Images