RU2438096C1 - Armour-piercing bullet - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: armour-piercing bullet includes envelope, hard-alloy slug and lead jacket. Slug has head and tail parts. Head part of hard-alloy slug is pointed. Length of slug is equal to (2.21-3.48)d; at that, hard alloy of slug includes tungsten carbide - 85-96% and has HRA hardness not less than 85.0 units, as well as ultimate bending strength of not less than 2000 MPa. Head part of slug is cone-shaped, the length of which is (0.58-3.70)d. Tail part has the shape of cylinder or flattened cone, or cylinder and flattened cone connected to each other. Smaller diameter of flattened cone is (0.71-0.86)d; larger diameter of flattened cone of tail part is equal to diameter of cylinder and diameter of head part of slug and is equal to (0.72-0.86)d. Length of cylinder of the tail part is equal to (0.01-3.58)d, where d - bullet calibre diameter. Slug surface has roughness of not more than Ra 1.6, and weight of slug is equal to 34-62% of bullet weight.

EFFECT: increasing piercing power of armour-piercing bullet.

6 cl, 1 dwg

Description

The invention relates to ammunition, in particular to automatic and rifle bullets having a core made of hard alloy with high penetration.

A solution is known in which the armor-piercing bullet contains a shell with steel and lead cores placed in it, and the head part of the steel core is made of high-strength steel with HRC 60 in the form of a cone with an angle at the apex of 50-90 ° and a length of 0.2-0.8 caliber bullets (Patent RU No. 2133441).

The disadvantage of this solution is its low breakdown effect.

A solution is known in which a bullet for a small arms cartridge contains a shell with a lead shirt and core placed in it, and the top of the head of the core has a pointed height not exceeding 0.7 caliber bullets, with a base diameter of not more than 0.68 caliber bullets (Patent RU No. 2072507).

The disadvantage of this solution is its low breakdown effect.

A solution is known in which an armor-piercing bullet contains a shell, a carbide core and a lead shirt in the form of a glass, the bullet length being equal to (4.2-4.6) d, the distance from the top of the bullet head to the top of the carbide core is (0.6- 1,0) d, and the thickness of the bottom of the lead shirt is equal to (0.3-0.5) d, where d is the caliber of the bullet, while the shell is made open from the end of the tail of the bullet and has the shape of a truncated cone (Patent RU No. 2135940) .

A disadvantage of the known solution is also the lack of penetration of the core of metal armor over 5.0 mm.

A solution is known aimed at increasing the breakdown ability of the core by optimizing the geometric dimensions of the core and the properties of the material from which it is made. The core of the bullet is made of carbide material and consists of a tail part and a head part, which has an animated shape with a top. The carbide material has a compressive strength of more than 4000 MPa, the angle at the top of the head is from 90 to 120 °, and the top of the head is rounded with a radius of (0.2-0.6) mm (Patent RU No. 2254551).

The disadvantage of this technical solution is the lack of penetration of the core of metal armor over 5.0 mm.

Despite the fact that in this solution the compressive strength of the material is not less than 4000 MPa, the main type of core destruction is the cleavage of the shank and the head part. In the case when the core does not penetrate the armor plate, it gets stuck in it and the liner is destroyed, which did not come into contact with the armor plate material. The disadvantage is due to the large angle of the cone at the top of the head.

The closest in technical essence and the achieved result to the proposed armor-piercing pool is an armor-piercing bullet, which contains a shell, carbide core and a lead shirt. The head part of the carbide core is pointed. The diameter of the head of the core at a distance of (1.0-2.0) d from its base is (0.3-0.5) d, and the diameter of the tail of the core is (0.7-0.8) d, where d - bullet caliber (Patent RU No. 2150077).

The disadvantage of this technical solution is the lack of penetration of the core of metal armor over 5.0 mm.

The disadvantages of this bullet, as well as bullets selected as analogs, are caused by not the optimal ratio of the mass of the core, the geometric parameters of the core depending on the caliber of the bullet and the physico-mechanical properties of the core material.

When such a bullet hits a solid barrier, the shell is destroyed and their penetrative effect is provided by the core. It is known that up to 20% of the kinetic energy of a bullet, depending on the material of the shell and the location of the core in the shell (the presence of a gap between the tip of the head of the core and the shell RU No. 21595940) is spent on the destruction of the shell. The implementation of the pointed core sharply increases the efficiency of the core when breaking. Obviously, the sharper the head part of the core, the less energy is needed to break through the shell. Thus, the kinetic energy possessed by the bullet is spent on crushing the head of the bullet shell (if there is space between the top of the core and the shell and the more it is, the more energy is consumed), the destruction of the bullet shell, breaking through an obstacle, blocking action.

The magnitude of the kinetic energy of the bullet is the sum of the energy of the core and the energy of the shell and lead shirt. The total kinetic energy is determined by the speed of the bullet from the barrel, as a rule, it is set for each type of weapon and the total mass of the bullet. Kinetic energy of the core is essential for the damaging effect. The mass of the core should be optimal and have maximum penetration. When hitting objects hidden behind armor, it is necessary that the bullet’s core not only pierce the armor, it must also have the energy necessary to hit the object behind the obstacle, and at the same time not be destroyed by small particles.

The basis of the invention is the task of increasing the penetration ability of an armor-piercing bullet.

In the process of solving this problem, a technical result is achieved, which consists in increasing the penetration ability of a bullet, the absence of brittle fracture of the tail of the core due to an increase in pressure and temperature in the zone of contact between the core and the barrier and the destruction of the barrier by the high-temperature plastic deformation mechanism, and the core is stored with sufficient energy for lethal action.

The specified technical result is achieved by the claimed armor-piercing bullet containing a shell, a carbide core having a head and tail parts, and a lead shirt, the head part of the carbide core is pointed, while the core length is (2.21-3.48) d, while solid the core alloy contains tungsten carbide by weight of 85-96%, has a hardness of HRA of at least 85.0 units, a flexural strength of at least 2000 MPa, the head of the core is cone-shaped, the length of which is (0.58-3.70) d, tail section has the shape of a cylinder, or a truncated cone, or a cylinder and a truncated cone interconnected, and the smaller diameter of the truncated cone is (0.71-0.86) d, the larger diameter of the truncated cone of the shank is equal to the diameter of the cylinder and the diameter of the head of the core and is equal to ( 0.72-0.86) d, and the length of the shank cylinder is (0.01-3.58) d, where d is the diameter of the caliber of the bullet, the surface of the core completely or partially has a roughness not higher than Ra 1.6, and the mass of the core equal to 34-62% of the mass of the bullet. In addition, the hard alloy has a compressive strength of at least 4000 MPa, a stress intensity factor K _{1C of} at least 8 MPa m ^1/2 , the conical shape of the head of the core is formed by a straight line and / or an arc of a circle, which is the interface between the line forming the cone, and the line forming the cylindrical part of the shank, with a radius equal to (0.31-10.28) d, while the length of the part of the cone formed by an arc of a circle is (0.01-3.70) d, has a rounding radius pointed part no more than 0.3 mm, the tail of the core and / or goal The ovine has a coating made by one of the physical or chemical methods of metal deposition.

In the proposed design of the bullet, the reduction of overhead energy is achieved by optimizing the shape of the top of the head of the core, optimizing the tail of the core, mass and material of the core.

The carried out optimization of the mass of the core, geometrical parameters of the core depending on the caliber of the bullet and the physicomechanical properties of the core material, taking into account the studies of the mechanism of core destruction, analysis of existing theories of barrier destruction when objects are introduced at high speed, made it possible to create an armor-piercing bullet that significantly exceeds analogues and a prototype for the degree of penetration of the armor-piercing plate and body armor.

It is known (The Physics of Destruction in High-Speed Impact. S.I. Anisimov et al. Letters in ZhTF, vol. 39, issue 1, pp. 6-12 and Destruction of materials under the influence of intense shock loads. S.A. Novikov. Soros educational journal , No. 8, 1999, pp. 116-121), that with a high-speed impact at the moment of contact strong shock waves appear in the striker and obstacle. Shock waves have rarefaction zones following the compression zones. At the moment of contact of the core of the bullet with an obstacle in the core, damped shock waves arise, which when superimposed on each other, at a certain point in time, can lead to mechanical crushing of the core. This effect can be enhanced in the presence of concentrators on the surface of the bullet core, for example steps, or acute angles, because in these zones, the interaction of stress zones occurs. This may explain the nature of core destruction when its shank is destroyed. It should be noted that the shank at the moment of collision was not exposed to any impact from the armored plate, because not in contact with her. Shock waves are present in it.

A detailed analysis of the physical mechanism and the basic laws of the kinetics of destruction of metal surfaces under shock loading, which corresponds to the collision of the core and armor, allowed us to conclude that it is necessary to perform the head pointed part of the core at a length = (0.58-3.70) d. The conical part of the core should not have angles during the transition from the cone to the cylindrical part of the core, therefore, the cone is formed by a straight line and / or an arc of a circle, which is the conjugation arc between the line forming the cone and the line forming the cylindrical part of the shank, with a radius equal to (0 31-10.28) d. The sharpening of the head of the core allows you to create adiabatic compression at the point of contact. The thermal energy of such a process goes to increase the temperature of the contact point. As a result of an abrupt increase in temperature, plastic destruction processes are realized with local overheating of individual contact zones.

An important role in the penetration ability of the core, having an acute angle at the apex of the cone with a tip rounded with a radius of no more than 0.3 mm, with high-speed impact, plays the initial period, which is determined by the energy of the bullet. For a number of reasons, it is necessary to strive for the mass of the bullet to be within certain limits. The analysis and test firing showed that if the mass of the core is within (36-53)% of the mass of the bullet, and the material of the core has physical and mechanical properties that do not allow it to collapse when introduced into the armor, for example, VK alloys containing tungsten carbide by mass 90-94%, then a high-temperature plastic mechanism for expanding the holes in the barrier is implemented, with the core itself being preserved in integrity.

This period is characterized by a high contact load and localization of temperatures and deformations in a small volume. The temperature in the contact zone depends on both hydrostatic pressure and shear stresses. It was experimentally established that regions of strongly localized plastic deformation appear at the point of contact, called adiabatic shear planes (PAS), in the vicinity of which heat is concentrated. Rapid deformation of the metal leads to localized heating of the contact and catastrophic destruction. Increasing the angle of the cone and the radius of curvature, we increase the localization zone and thereby reduce the temperature in it by increasing the rate of heat removal, which ultimately does not lead to the formation of PAS. (Zeldovich Ya.B. Physics of shock waves and high-temperature hydrodynamic phenomena. M: Nauka, 1966, 686 p.)

With the further introduction of the core into the barrier, the known mechanism of plastic expansion of the hole in the barrier is realized. Reducing the angle of the cone here also favorably increases the breakdown ability of the core. In this case, more high-temperature mechanisms of plastic deformation of the barrier are realized. Since the cone with a smaller angle at the apex has a greater height, it is in contact with the armor for more time when the plastic deformation process is underway and much more heat is released. Part of the heat goes into the armor, and part is transferred to the shank. As a result of heating the shank, its fracture toughness rises, thus, its fracture does not occur from the action of shock waves. The execution of the shank in the form of a connected cylinder and a truncated cone, the smaller diameter of the cone is (0.71-0.86) d, the larger diameter of the cone of the shank is equal to the diameter of the cylinder and the diameter of the head of the core and is equal to (0.72-0.86) d, and the length of the shank cylinder is (0.01-3.58) d, and the core surface, in whole or in part, with a roughness not higher than Ra 1.6, can significantly reduce the load on the tail of the core when it passes through the hole. An undefeated core has significant energy after passing through a barrier.

An important role in the mechanisms of destruction is played by surface defects that appear during the core manufacturing process. Elimination of the defective core layer, bringing its surface to a roughness of Ra 1.6 and below will significantly increase its resistance to nucleation and development of surface microcracks.

The drawing shows the design of the inventive armor-piercing bullet.

An armor-piercing bullet consists of a carbide core 1 having a head 1.1 and a tail 1.2 parts, a lead shirt 2 and a sheath 3, the head part of the carbide core is pointed. The head part 1.1 consists of a cone 1.1.1 formed by a straight line and a conical part 1.1.2 formed by a part of a circle. The tail part 1.2 consists of either a cylinder 1.2.1, or a truncated cone 1.2.2, or a cylinder 1.2.1 and a truncated cone 1.2.2, interconnected. The ratio of the design parameters of the bullet is determined depending on the caliber. The length l _{0 of} core 1 is l ₀ = (2.21-3.48) d, the length of the head part l _{1 of} core 1.1 is l ₁ = (0.58-3.70) d, l ₂ is the length of the core part 1.1. 1 formed by a circle radius R ₁ equal to R ₁ = (0.31-10.28) d, length l ₂ is equal to l ₂ (0.01-3.70) d, length of the cylindrical part l _{3 of the} tail core 1.2.1 is l ₃ = (0.01-3.58) d. The larger diameter D _{1 of the} truncated cone of the shank is equal to the diameter of the cylinder and the diameter of the head of the core and is equal to D ₁ = (0.72-0.86) d, the smaller diameter D _{2 of the} truncated cone is D ₁ = (0.71-0.86) d. The pointed part of the core has a radius of curvature R _{2 of} not more than R ₂ <0.3 mm. The core surfaces in whole or in part, either the head part or the tail part, are additionally ground to a roughness not higher than Ra 1.6. The tail part of the core and / or the head part has a coating made by one of the physical or chemical methods of metal deposition.

The core was made from tungsten-cobalt powders with a tungsten carbide content of 92% by weight and cobalt 8% by weight. The density after pressing the workpieces was 8.4 + 0.05 g / cm ² . Sintering was carried out in two stages: preliminary — to remove the plasticizer in a hydrogen atmosphere and final vacuum-compression in a VKPgr 50/90/50 furnace by Degussa.

Comparative tests were carried out with 7H24 cartridges having a bullet with a carbide core, the core has a pad in the head of the core, and 7N24M having a bullet with a carbide core with a cone-shaped head. As the punched material, an armor plate of 10 mm of GOST V 21967-90 grade 2P was used at a distance of 100 m, firing was carried out from a 5.45 mm RPK74 light machine gun, 5 mm of state standard specification V 21967-90 armor plate was 5 mm at a distance of 550 m, shooting was fired from 5 , A 45-mm AK74M assault rifle equipped with an optical sight, a section of body armor 6BR23-1 at a distance of 100 m, firing was carried out from a RPK74 light machine gun and an AK74 assault rifle. The percentage of penetration of the obstacle was determined.

The table shows the results of comparative tests confirming an increase in the breakdown ability of the proposed cartridge

Cartridge The percentage of breaking through the plate 2P at a distance of 100 m, RPK74 The percentage of breaking through the plate 2P at a distance of 550 m AK74M Section of body armor 6BR23-1 at a distance of 100 m RPK74 Bulletproof vest section 6BR23-1 at a distance of 100 m AK 74 Cartridge 7N24 10 0 thirty 0 Cartridge 7N24M 40 0 40 0 Cartridge with armor-piercing bullet one hundred one hundred one hundred one hundred

Thus, the totality of all the ratios of the design parameters of the armor-piercing bullet indicated in the formula ensures the creation of a cartridge that has higher penetration performance. These ratios and the obtained data on the mechanism of destruction of metal armor can be used to create cartridges of various calibers.

Claims (6)

1. An armor-piercing bullet containing a shell, a carbide core having a head and a tail, and a lead shirt, the head of the carbide core is pointed, characterized in that the core length is (2.21-3.48) d, while the hard alloy the core contains tungsten carbide by weight of 85-96%, has a hardness of HRA of at least 85.0 units, a flexural strength of at least 2000 MPa, the head of the core is cone-shaped, the length of which is (0.58-3.70) d, tail the part is in the form of a cylinder, or a truncated cone, or interconnected cylinder and a truncated cone, and the smaller diameter of the truncated cone is (0.71-0.86) d, the larger diameter of the truncated cone of the shank is equal to the diameter of the cylinder and the diameter of the head of the core and is equal to (0.72-0.86) d, and the length of the shank cylinder is (0.01-3.58) d, where d is the diameter of the bullet’s caliber, the core surface has a roughness in whole or in part not higher than Ra 1.6, and the mass of the core is 34-62% of the bullet mass. 2. Armor-piercing bullet according to claim 1, characterized in that the hard alloy has a compressive strength of at least 4000 MPa, 3. Armor-piercing bullet according to claim 1, characterized in that the hard alloy has a stress intensity factor K _{1C of} at least 8 MPa ∙ m ^1/2 . 4. Armor-piercing bullet according to claim 1, characterized in that the conical shape of the head of the core is formed by a straight line and / or an arc of a circle with a radius equal to (0.31-10.28) d, which is the conjugation arc between the line forming the cone, and a line forming the cylindrical part of the shank, while the length of the part of the cone formed by an arc of a circle is (0.01-3.70) d. 5. Armor-piercing bullet according to claim 1, characterized in that the conical shape of the head of the core has a radius of curvature of the pointed part of not more than 0.3 mm. 6. Armor-piercing bullet according to claim 1, characterized in that the tail of the core and / or head has a coating made by one of the physical or chemical methods of metal deposition.