RU2463546C1 - Armour-piercing bullet for small arms - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: armour-piercing bullet comprises a shell, a jacket, a hard-alloy core and a lubricant. The shell has a head cone-shaped part. The core has a sharpened top in a head part. The area between the inner surface of the head part of the shell and the external head part of the core is filled with the lubricant. In the top of the head cone-shaped part of the shell there is a through hole. The hard-alloy core is placed in the jacket, in order to observe coaxiality of the cylindrical part of the core and the hole in the top of the head part of the shell. The jacket is made from an elastic-plastic polymer material. At least 60% of the cylindrical part of the hard-alloy core is in the jacket. The length of the hard-alloy core is equal to (2.02-3.58)d, and the diameter of the cylindrical part is equal to (0.71-0.86)d. The length of the sharpened top of the head part of the core is equal to (0.58-3.70)d, and the diameter of the hole in the top of the head cone-shaped part of the shell is equal to (0.13-0.18)d, where d-diameter of bullet calibre. The weight of the hard-alloy core is equal to (0.57-0.86) of the bullet weight.

EFFECT: higher piercing capacity of an armour-piercing bullet.

1 dwg

Description

The invention relates to ammunition of small arms, namely to armor-piercing bullets having a core of hard alloy with high penetration and designed to destroy fire points in lightly armored military equipment.

A known bullet that provides penetration of a fragmentation-proof bulletproof vest 6B2, felt and boards 25 mm behind it at a distance of up to 50 m (RF patent No. 20188780).

The disadvantages of this bullet are the following: high aerodynamic drag due to the obtuse shape of the protruding part of the core in the bullet head, due to a step in the interface between the shell and the core, which leads to braking forces with the oncoming air flow during the bullet’s flight, which means and the deterioration of the accuracy of the battle and the loss of speed on the trajectory; the relatively low percentage of penetration of 6B2 vests at a distance of more than 50 m due to the blunt-shaped shape of the steel core, which, when faced with an obstacle, can lose stability and not hit the target.

A bullet for small arms cartridges is known, comprising a shell with a lead shirt and a core having a blunted head in it, while the head of the core is made with a length of at least 1.4 caliber bullets and a blunting diameter not exceeding 0.35 caliber (Patent SU 1838750).

The disadvantage of this bullet is its low efficiency in the defeat of armored vehicles and shelters.

When a bullet hits a solid barrier, the shell is destroyed and their penetrative effect is provided by the core. By tests it was found that in cores having a blunting on the head part, depending on the material of the shell in which they are placed, up to 15-20% of the kinetic energy of the bullet is spent on the destruction of the shell.

In addition, the cores, as a rule, are located in the pool shell at some distance from the top of the bullet, as a result of which, when meeting an obstacle, up to 5% of the kinetic energy is spent squeezing the top of the bullet before the destruction of the shell.

A known bullet for small arms cartridges, containing a shell with a lead shirt and a core placed in it, the top of the head of the core has a pointed height not exceeding 0.7 caliber bullets, a base diameter of not more than 0.68 caliber bullets (RF Patent 2072507) .

The disadvantage of this bullet is its low efficiency in the defeat of armored vehicles.

This is due to the fact that the shell of the bullet is made of steel, and the inner cone of the core practically coincides with the cone of the head of the core and there is no gap between the top of the core and the inner surface of the shell. Therefore, when meeting with an obstacle, the core energy primarily goes to the destruction (rupture) of the undeformed conical part of the steel shell.

A known bullet containing a shell in which a steel core is placed in a shirt, the shell is made of metal with thinning the top of its head, the shirt is made of lead, and the core is drop-shaped, the thinning of the top of the head of the shell is 0.1-0.5 the shell wall thickness, and the core from the head to the tail is made in the form of a truncated cone with a base at the head, the diameter of the core at the head is equal to the inner diameter of the cylindrical part of the shell (RF patent 21 33440).

The disadvantage of this bullet is its very low efficiency in the defeat of armored vehicles. In this case, the top of the shell is made of refined steel, but nevertheless there is a significant part of the top having a shell in full thickness.

The closest in technical solution and taken as a prototype is a bullet for a small arms cartridge containing a shell with a lead shirt and a core placed in it, the shell being made of cermet antifriction powder material, and the head cone-shaped part of the shell has a variable thickness that decreases from the base of the cone where the thickness of the conical head is equal to the thickness of the cylindrical part of the shell, up to 0.55 thickness at the top of the cylindrical part of the shell, the core head has t pointed tip and made of hard alloy, and the area between the inner surface of the head of the shell and the surface of the head of the core is filled with solid lubricant (RF patent 2413171).

The disadvantage of this technical solution is the lack of penetration, as a result of low efficiency in the defeat of armored vehicles.

Thus, it can be seen from the above analogues and prototype that the influence of the shell as a factor that reduces the kinetic energy of the core, which goes to break through the barrier, is quite large.

The objective of the invention is to increase the penetration ability of an armor-piercing bullet.

In the process of solving this problem, a technical result is achieved, consisting in increasing the kinetic energy of the bullet going to break through the armor, increasing the distance of breaking through the armor, increasing the accuracy of fire.

The technical result is achieved by the claimed armor-piercing bullet for small arms containing a shell having a head cone-shaped part, with a shirt placed therein and a carbide core having a pointed apex in the head part, and the area between the inner surface of the head part of the shell and the outer head part of the core is filled with grease, at the same time, a through hole is made at the apex of the head cone-shaped part of the shell, the carbide core is placed in a shirt in compliance with the alignment of cylines the core part and the hole at the top of the head of the shell, the shirt is made of resiliently plastic material, with at least 60% of the cylindrical part of the carbide core being in the shirt, the length of the carbide core is flat (2.02-3.5%) d, the diameter of the cylindrical part is (0.71-0.86) d, the length of the pointed top of the head of the core is equal to (0.58-3.70) d, and the diameter of the hole in the top of the head cone-shaped part of the shell is (0.13-0, 18) d, where d is the diameter of the caliber of the bullet, the mass of the carbide core is equal (0.57-0.86) the mass of the bullet.

It is known from theory that the accuracy of fire mainly depends on the location of the center of mass of the bullet. Practice has established: to improve the accuracy of firing at small arms bullets, the center of mass of the bullet should be shifted closer to the tail. The presence of lead in the tail of the shell (lead density is almost 1.5 times lower than the density of the hard alloy) certainly does not contribute to this. Thus, the replacement of a lead shirt with an elastic-plastic material makes it possible to increase the length of the cylindrical part of the core and shift the center of mass to the tail part, and therefore, increase the accuracy indicators.

It is known that the penetrative effect of a bullet when meeting solid obstacles is carried out by the core and the larger the mass of the bullet (ceteris paribus), the higher the penetrative effect. Therefore, the efficiency will be higher for the bullet, in which the ratio of the mass of the core to the total mass of the bullet will have a large value. In known designs of armor-piercing bullets, this ratio is approximately equal to 0.5, that is, the mass of the core is equal to the sum of the masses of the shirt and shell. Moreover, the weight of the lead shirt is significantly greater than the mass of the shell. A massive lead shirt not only reduces the efficiency of the bullet, but also negatively affects the ballistic characteristics of the cartridge as a whole.

Based on the foregoing, it can be concluded that a large amount of lead is used in the production of armor-piercing cartridges. Therefore, such bullets do not meet modern requirements for accuracy, punching and rational use of materials.

The kinetic energy of a bullet is determined by the speed of departure of the bullet from the barrel and its mass, as a rule, each type of weapon has its own speed and mass of the bullet. Kinetic energy of the core is essential for the damaging effect. However, not all kinetic energy of a bullet goes to the destruction of armor. Since the bullet consists of several elements, the total energy consists of its individual elements: the energy of the core, the energy of the shell and the lead shirt.

As practice shows, when a bullet encounters an obstacle at the initial moment, the top of the bullet is crushed (before the destruction of the shell) and 7-10% of the kinetic energy of the bullet is spent on this work.

In order to reduce the loss of kinetic energy that goes into the destruction of the shell by a pointed carbide core, a through hole is made at the top of the head of the shell through which a lubricant located in the head of the shell is supplied at the initial moment the core enters the barrier and the core exits the shell. Reducing the mass of the shirt made of an elastic plastic material allows increasing the mass of the carbide core to (0.57-0.86) the mass of the bullet, while maintaining the total mass of the bullet, and increase up to 25% of the kinetic energy spent on breaking through the barrier.

The performance of a pointed carbide core sharply increases the efficiency of the core upon breaking. Obviously, the sharper the head part of the core, the less energy is needed to break through the shell. The implementation of the head of the pointed part of the core cone-shaped, the length of which is equal to (0.58-3.70) d, allows in this range to obtain the maximum ability of a bullet to penetrate armor. The diameter of the cylindrical part of the carbide core is (0.71-0.86) d, this range of parameters of the cylindrical part of the core allows to reduce compression stresses when the core passes the obstacles and to reduce the stress gradient when the core leaves the armor and thereby maximize the core after breakdown. The length of the core is (2.02-3.5 8) d, a decrease in the length of the core less than 2.02 caliber reduces its mass and reduces the breakdown effect due to a decrease in the specific pressure on the barrier, an increase in the length of the core more than 3.58 caliber reduces the breakdown effect due to a decrease in its stability. The manufacture of a carbide core within the specified limits allows you to save the ballistic properties of the bullet.

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

Armor-piercing bullet for small arms contains a shell 1. The shell is made of bimetal, the shell on top is covered with copper. A through hole 2 is made at the top of the head cone-shaped part of the shell. A carbide core 3 is placed in the shell, which is located in a jacket of elastic plastic material 4. The core is made by powder metallurgy from VK8 alloy. The cavity 5, formed by the inner surface of the head of the shell and the surface of the head of the core, is filled with a solid lubricant, such as paraffin.

Comparative tests were carried out with bullets with a carbide core cartridge 7N24. As the punched material, an armor plate of 5 mm grade 2P GOST V 21967-90 was used at a distance of 200 m, 350 m, 500 m and 650 m. The percentage of penetration of the barrier material was determined.

The table shows the results of comparative tests confirming an increase in the penetration ability of the proposed bullet.

Bullet Plate breaking 200 m 350 m 500 m 650 m Bullet cartridge 7N24 one hundred% 80% 0% 0% Bullet offered one hundred% one hundred% one hundred% 80%

As can be seen from the test results, the best indicators for the percentage of penetration of a bullet according to the proposed technical solution.

Claims (1)

An armor-piercing bullet for small arms, containing a shell having a conical head part with a shirt placed therein and a carbide core having a pointed apex in the head part, and the area between the inner surface of the shell head and the outer head part of the core is filled with grease, characterized in that a through hole is made at the top of the head cone-shaped part of the shell, the carbide core is placed in the shirt in compliance with the alignment of the cylindrical part of the core and open tia at the top of the head of the shell, the shirt is made of elastic plastic material, while at least 60% of the cylindrical part of the carbide core is in the shirt, the length of the carbide core is (2.02-3.58) d, the diameter of the cylindrical part is ( 0.71-0.86) d, the length of the pointed apex of the head of the core is (0.58-3.70) d, and the diameter of the hole at the top of the head cone-shaped part of the shell is (0.13-0.18) d, where d is the diameter of the caliber of the bullet, the mass of the carbide core is 0.57-0.86 mass of the bullet.