RU190660U1 - CARTRIDGE FOR SHOOTING WEAPONS WITH A SOLID ALLOY CORE - Google Patents

Abstract

The utility model relates to ammunition, in particular to automatic and rifle cartridges, with bullets having a hard-alloy core with a high density, having a high penetrating ability and accuracy of combat. The objective of the proposed technical solution is to increase the damaging ability of the cartridge. In the process of solving the task, the technical result is achieved, in increasing the armor penetration and accuracy of the battle when shooting, reducing the cost of manufacturing the cartridge. This technical result is achieved by the claimed cartridge for small arms with a core of solid alloy containing a bullet having a shell, lead shirt, a core consisting of the head and tail parts, a steel sleeve with a primer-igniter and a propellant powder charge, the length of the bullet is (3, 52-4.60) d, the length of the core is equal to (2.36-3.48) d, the head of the core is tapered, the diameter of the base of the cone of the head of the core is (0.70-0.86) d, the tail of the core made in the shape of a cylinder whose diameter is equal to the diameter of the base of the cone, has a chamfer on the end, the surface of the tail part of the core is ground to a roughness of not more than Ra 1.6, the offset of the back end of the core from the back end of the shell is (0.1 ÷ 0.4) d, the nominal mass of the core is equal to (34 ÷ 62)% of the mass of the bullet, while the head of the core has a length equal to (0.58 ÷ 1.65) d, where d is the bullet caliber, the head of the cone has a vertex in the form of a hemisphere with a diameter of not more than 0.9 mm ., the surface of the top of the head, the head and the chamfer on the end of the tail of the core obtained pressing, sintering and tumbling, chamfer on the butt end of the tail part of the core is (0.15 ÷ 0.40) mm, the hard alloy of the core contains tungsten carbide by weight (88-98)%, the rest is cobalt and has a flexural strength of at least 1475 MPa, the deviation of the mass of the core from the nominal value (Mn) is within the tolerance field equal to (0,011-0,08585) Mn, where Mn is the nominal mass of the core. 2 Il.

Description

The utility model relates to ammunition, in particular to automatic and rifle cartridges, with bullets having a hard-alloy core with high density, possessing high penetration ability and accuracy of combat.

Known cartridge increased penetrability, containing a bullet having a shell, a core consisting of the head and tail, lead shirt, steel sleeve with primer-igniter and propellant powder charge, the length of the bullet is equal to (3.52-4.60) d, the length of the core bullets equal to (2.36-3.48) d, while the core is made of a hard alloy with a tungsten carbide content by weight of 85-96%, the head part of the core is made cone-shaped, the length of which is (0.52-2.41) d, the tail part has the shape of a cylinder, the length of the cylinder of the shank is (0.01-3.58) d, g e d is the diameter of the bullet caliber, the core surface has a roughness of no more than or not less than Ra 1.6, and the core mass is equal to (0.34-0.62) the mass of the bullet, the conical shape of the core head portion is formed by a straight line and the radius of curvature of the pointed part is not more than 0.3 mm (Patent RU 2438092 according to the application 2010128439 dated 09/07/2010 MKI F42B 51/02).

A disadvantage of the known technical solution is not the manufacturability of the core. The entire surface of the core, in whole or in part, in order to obtain a roughness of not more than Ra 1.6, must be machined (ground). This requires significant additional costs for equipment, tools, organization of production. The tail part of the core has a small taper, which is also obtained by grinding. The head of the cone has a radius of the peaked part of not more than 0.3 mm. Such a performance of the head part reduces the penetrating ability of the core. The core material is defined as an alloy with a tungsten carbide content by weight (85-96)%, which excludes the use of alloys with a higher tungsten carbide content. The mass tolerances in the manufacture of the core are not determined, which does not allow to guarantee high accuracy when shooting.

The closest technical solution is an armor-piercing cartridge containing a bullet having a shell, a core consisting of a head and tail, a lead shirt, a steel sleeve with a primer-igniter and a propellant powder charge, the length of the bullet is (3.52-4.60) d , the bullet core length is equal to (2.36-3.48) d, while the core is made of a hard alloy with a tungsten carbide content by weight of 85-96%, having a hardness of HRA not less than 85.0 units, flexural strength not less than 2000 MPa , the head of the core is made cone-shaped, d and in which it is equal to (0.52-2.41) d, the tail part has the shape of a cylinder, the diameter is equal to the diameter of the cone of the head part of the core and is equal to (0.70-0.86) d, where d is the diameter of the bullet caliber, the surface of the core fully or partially has a roughness of not more than Ra 1.6, and the mass of the core is equal to (0.34-0.62) of the mass of the bullet, while the head of the cone-shaped core has a contact pad, whose diameter is equal to (0.018-0.25) d where d is the bullet caliber; the conical shape of the head part of the core is formed by a straight line; the tail part of the core has a chamfer or is glad The curve of curvature is up to 0.15d, (Patent RU No. 126449 upon application 2012147316 dated November 7, 2012, MKI F42B 30/02).

The disadvantages of the known technical solution is:

Not enough armor penetration. The head of the cone of the core has a diameter of (0,018 ÷ 0,25) d, where d is the diameter of the caliber. Such a performance of the head part reduces the penetrating ability of the core. The core material is defined as a hard alloy with a tungsten carbide content by weight (85-96)%, which limits the scope of the use of hard alloys with a higher tungsten carbide content.

The mass tolerances in the manufacture of the core are not determined, which does not allow to guarantee high accuracy when shooting.

The objective of the proposed technical solution to increase the damaging ability of the cartridge.

In the process of solving the task, the technical result is achieved, in increasing the armor penetration and accuracy of the battle when shooting, reducing the cost of manufacturing the cartridge.

This technical result is achieved by the claimed cartridge for small arms with a core of solid alloy containing a bullet having a shell, lead shirt, a core consisting of head and tail parts, a steel sleeve with a primer-igniter and a propellant powder charge, the length of the bullet is (3, 52-4.60) d, the length of the core is equal to (2.36-3.48) d, the head of the core is tapered, the diameter of the base of the cone of the head of the core is (0.70-0.86) d, the tail of the core made in the shape of a cylinder, di the meter of which is equal to the diameter of the base of the cone, has a chamfer on the end face, the surface of the tail part of the core is ground to a roughness of no more than Ra 1.6, the displacement of the back end of the core from the back end of the shell is (0.1 ÷ 0.4) d, the nominal mass of the core is equal to (34 ÷ 62)% of the mass of the bullet, while the head of the core has a length equal to (0.58 ÷ 1.65) d, where d is the bullet caliber, the head of the cone has a vertex in the form of a hemisphere with a diameter of not more than 0.9 mm ., the surface of the top of the head, the head and the chamfer on the end of the tail of the core obtained pr sessing, sintering and tumbling, chamfer on the butt end of the tail section of the core is (0.15 ÷ 0.40) mm, the hard alloy of the core contains tungsten carbide by weight (88-98)%, the rest is cobalt and has a flexural strength of at least 1475 MPa, the deviation of the mass of the core from the nominal value (Mn) is within the tolerance field equal to (0,011-0,0585) Mn, where Mn is the nominal mass of the core.

Changes in the ratio of the design parameters of the cartridge of the above limits will significantly affect its tactical and technical characteristics.

Reducing the length of the bullet less than 3.52 caliber leads to a decrease in the mass of the bullet and the core and, consequently, to a decrease in the breakdown effect and a significant change in the ballistic characteristics of the cartridge. Increasing the bullet length of more than 4.60 caliber leads to an increase in the mass of the bullet and, therefore, the recoil momentum of the cartridge. This increases the pressure of the powder gases and the speed of the moving parts of the weapon, which leads to its more rapid wear. There is a difficulty in stabilizing the bullet in the trajectory and the accuracy of shooting deteriorates.

Reducing the length of the core less than 2.36 caliber reduces its weight and reduces the breakdown effect due to the reduction of the specific pressure on the barrier. Increasing the length of the core more than 3,48 caliber reduces the breakdown effect due to the decrease in its stability.

Optimization of geometrical parameters of the head part of the core, its execution in the form of a cone with a base diameter (0.72-0.86) d, and a length equal to (0.58 ÷ 1.65) d, where d is the bullet caliber, making the core from more Heavy alloys with a high content of tungsten carbide allowed to increase the armor penetrability of the core. The hard alloy of the core contains tungsten carbide by weight (88-98)%, the rest is cobalt and has a flexural strength of at least 1475 MPa. The increase in penetration is achieved by increasing the specific impact energy per unit area in the initial period of contact of the core with an armor barrier.

The core with the apex of the conical part made in the form of a hemisphere, the diameter of which is not more than 0.9 mm, destroys the metal armor by the mixed mechanism of penetration (destruction). In the place of contact there are areas with highly localized plastic deformation, called the planes of the adiabatic shear (PAS), in the vicinity of which heat is concentrated. Rapid deformation of the metal leads to localized heating of the contact and catastrophic destruction of armor in the form of melting. Performing the top of the conical part of the core in the form of a hemisphere, whose diameter is not more than 0.9 mm, we get stable results on armor penetration, as each time the same mechanism of penetration with the formation of PAS in the first stage of armor penetration and brittle destruction of the back side armored plates in the second stage of breaking the plate. With the implementation of such a mechanism of penetration, the brittle destruction of the core does not occur, it retains its shape a, the implementation of the less energy-intensive, brittle destruction of the back side of the armored plate, retains its kinetic energy, and consequently, the obstacle damaging effect. Thanks to optimization of the geometry of the head part of the core (making the apex of the tapered part in the form of a hemisphere), unlike the prototype, having a contact pad in the head part that implements a very energy-intensive mechanism at the first stage of armor penetration, wasting the kinetic energy of the core with the formation of PASS, while leaving much less energy for the implementation of the second stage, the fragile destruction of the back side of the armor plate, at the first stage of introducing the core into the armor, the puncture penetration mechanism is implemented m with the molten metal and less loss of kinetic energy, with a margin for the second phase, when the core comes out of the armor, namely brittle fracture rear side armor plates, thereby increasing zapregradnoe lethality.

Obtaining the surface of the top of the head, head and chamfer along the butt of the tail of the core with a pressing tool at the stage of pressing and tumbling after sintering, significantly reduced the cost of manufacturing the bullet. The execution of the tail part of the core in the form of a cylinder simplified its manufacturing technology. Grinding a cylindrical surface to a roughness of Ra not higher than Ra 1.6 and the presence of a chamfer on the end face of the tail portion of the core equal to (0.15 ÷ 0.40) mm. Allows you to increase the reliability of the process, eliminate the core falling out of the lead shirt during bullet assembly and reduce costs of making bullets. The deviation of the core mass from the nominal value (Mn) within the tolerance field equal to (0.011-0.0585) Mn, where Mn is the nominal mass, allows to receive lots of cores with a minimum variation in the mass of the core and increase the accuracy of fire, by reducing the mass dispersion cores intended for one batch of manufacturing cartridges.

FIG. 1 shows the design of the proposed cartridge, where L is the bullet length, which is equal to L = (3.52-4.60) d, 1 is a bullet, steel sleeve 2, propellant powder charge 3 and primer-igniter 4 with non-rust composition 5.

FIG. 2 shows a bullet 1 consisting of a bimetallic shell 6, a lead shirt 7 and a carbide core 8. Core 8 consists of a cone-shaped head part 8.1 and a tail part 8.2. The top of a cone head part 8.1 of the core is made in the form of a hemisphere 8.1.1. diameter D ₁ not more than 0.9 mm. The tail part 8.2 has the shape of a cylinder, the diameter of which is equal to the diameter of the cone of the head part 8.1 and equal to D ₂ = (0.7-0.86), has a chamfer 8.2.1 at the end of the tail part of the core 8. The length l _{0 of the} core 8 is equal to l ₀ = (2.36-3.48) d, the length l _{1 of the} head part 8.1 of the core 8 is equal to l ₁ = (0.58-1.65) d, the offset of the rear end of the core 8 from the rear end of the shell 6 is equal to l ₂ = ( 0.1 ÷ 0.4) d.

Comparative tests of cartridges manufactured according to the parameters of the prototype and the proposed technical solution were carried out.

Carbide cores of bullets were made of tungsten-cobalt powders with a tungsten carbide content of 92% and 97% by weight and a cobalt content of 8% and 3%, respectively. Sintering was carried out in two stages: preliminary - in order to remove the plasticizer in a hydrogen atmosphere and the final vacuum-compression furnace VKPgr 50/90/50 from Degussa. After sintering, the core density was 14.8 g / cm ² and 15.2 g / cm ² for a core with a cobalt content of 8% and 3%, respectively. The assembly of bullets and ammunition was carried out at the FKP APZ "Vympel"

The penetration ability of bullets filled with cores made according to the prototype and the proposed technical solution when firing the RPK74 machine gun at OST V3-300-75, at the 2P grade armor 10 mm thick, installed vertically at an angle of 90 ° to the firing direction at a distance of 100 m was carried out comparative costs for the manufacture of bullets manufactured by the proposed technical solution and the technical solution of the prototype. The percentage of penetration of a bullet with a core having prototype parameters was 98%. The percentage of penetration of a bullet with a core having the parameters of the proposed technical solution was 100%. The lack of grinding operations on the surface of the head part, the head part and the chamfer along the end of the tail part of the core allowed reducing the cost of manufacturing the core to (4-5)%, and grinding the cylindrical surface of the tail part of the core to a roughness of Ra is not higher than Ra 1.6, and the presence of a chamfer at the end of the tail part of the core equal to (0.15 ÷ 0.40) mm. improve the build quality of the cartridge.

The results of comparative tests confirmed the high penetrating ability of the proposed cartridge and reduced manufacturing costs compared with the prototype while maintaining high accuracy of the battle.

Claims (1)

Small-arms cartridge with a solid alloy core containing a bullet having a shell, a lead shirt, a core consisting of head and tail parts, a steel sleeve with a primer-igniter and a propellant powder charge, the length of the bullet is (3.52-4.60 ) d, the length of the core is equal to (2.36-3.48) d, the head of the core is tapered, the diameter of the base of the cone of the head of the core is (0.70-0.86) d, the tail of the core is in the shape of a cylinder, the diameter of which is equal to the diameter of the base of the cone has a chamfer on the end face, the surface of the tail part of the core is ground to a roughness of no more than Ra 1.6, the displacement of the back end of the core from the back end of the shell is (0.1 ÷ 0.4) d, the nominal mass of the core is (34 ÷ 62)% of the mass of the bullet, characterized in that the head part of the core has a length equal to (0.58 ÷ 1.65) d, where d is the bullet caliber, the head part of the cone has a vertex in the form of a hemisphere with a diameter of not more than 0.9 mm, the top surface of the head part, the head part and chamfer on the end of the tail part of the core are obtained by pressing, sintering and tumbling, chamfer on tor The tail of the core is equal (0.15 ÷ 0.40) mm, the hard alloy of the core contains tungsten carbide by weight (88-98)%, the rest is cobalt and has a flexural strength of at least 1475 MPa, the deviation of the core mass from the nominal value (Mn) is within the tolerance field equal to (0.011-0.0585) Mn, where Mn is the nominal mass of the core.

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