RU2413173C1 - Bullet for small arms cartridge - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: bullet includes slug and cover. Bullet is also equipped with bimetallic bushing enveloping the slug and representing the element interacting with the surface of the barrel channel. Slug has pointed shape. Cover is made from thermoplastic polymer material and envelopes slug without formation of cavities. Bushing on inner surface has slots throughout its length, and outer surface is made flush with outer surface of the cover.

EFFECT: improving bullet hitting efficiency.

1 tbl, 1 dwg

Description

The invention relates to ammunition of small arms, and in particular to bullets designed to destroy firing points in lightly armored military equipment.

A well-known bullet that provides penetration of fragmentation-proof bulletproof vest 6B2, felt and boards 25 mm behind it at a distance of up to 50 m (RF patent No. 20178780).

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 No. 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 the piercing effect is provided by the core. Tests established 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 in which a lead shirt and a core are placed, wherein the top of the head of the core has a tapering height not exceeding 0.7 caliber bullets, a base diameter of not more than 0.68 caliber bullets (RF Patent No. 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 energy of the core primarily goes to the destruction (rupture) of the still not deformed conical part of the steel shell, which significantly reduces the breakdown capabilities of the core. The shell of steel accounts for almost half of the moment of inertia of the bullet relative to the main axis. Therefore, a significant part of the energy of the explosion of the powder charge is spent on giving the necessary rotational speed of the bullet when it leaves the barrel. With a decrease in the mass of the shell and an increase in the mass of the core due to this, to give rotational movement to the bullet, less energy will be required, which means that most of the energy of the explosion of gunpowder will be used to increase the linear velocity of the bullet when leaving the barrel and, as a result, increase the breakdown ability of the bullet.

Thus, it can be noted that the influence of the steel shell as a factor sharply reducing the kinetic energy of the core, necessary for breaking through the barrier, is quite large.

The objective of the invention is to increase the effectiveness of the defeat of a protected target at a greater distance.

In the process of solving this problem, a technical result is achieved, which consists in increasing the kinetic energy of the core, which goes to break through the barrier by reducing the loss of kinetic energy of the core, which goes to destroy its own shell, increase the speed of the bullet from the barrel and increase the gyroscopic effect.

The specified technical result is achieved by the claimed bullet for small arms cartridges containing a core and a shell, due to the fact that it is additionally equipped with at least one sleeve enclosing the core and being an element interacting with the surface of the barrel channel, the core is made of hard alloy, has a pointed shape, and the shell is made of thermoplastic polymeric material, the sleeve on the inner surface has grooves along the entire length, the outer surface of the sleeve is flush with the outside the casing surface, the casing covers the core without the formation of voids.

The increase in kinetic energy will occur due to an increase in the mass of the core, while maintaining all the aerodynamic characteristics of the bullet. The increase in mass will occur due to the fact that the mass of the shell made of plastic is much lighter than the shell made of steel, and the mass of the shirt made of lead can be attached to the core.

Reducing the loss of kinetic energy for the destruction of plastic is much less than that of metal and bimetal. This is due to the fact that practically no energy is required to break through plastic with a pointed core. Cores, as a rule, are located in the shell at some distance from the top of the bullet. This arrangement of the core in the shell is due to the fact that the head of the shell is made optimal from the position of obtaining the optimal aerodynamic shape from metal or bimetal, and the head of the core is based on the position of obtaining the maximum breakdown ability of the core. Since these forms do not coincide, it is necessary to shift the core from the top of the shell. In order to reduce the loss of kinetic energy, which goes to the destruction of the shell, it is proposed to make the shell of a thermoplastic polymer material. At the initial moment of the core entering the barrier and the core leaving the shell, the shell will collapse, and its part, which will be involved in the punched hole, will serve as a solid lubricant.

While maintaining all the aerodynamic characteristics of the proposed bullet, the entire mass will be practically concentrated in the cylindrical part of the core. An increase in mass by 50% will lead to an increase in the geometric dimensions of the core by only 3%. When a bullet exits the barrel, in addition to translational motion, it acquires a rotational one around its axis. The energy of the explosion of the powder charge is spent on giving the bullet translational and rotational motion and to overcome the friction forces. Assuming that the friction force decreases when the shell is made of plastic, the moment of inertia of the bullet relative to the central axis also decreases due to the concentration of almost the entire mass of the bullet in the core, then when it leaves the barrel, the linear velocity of the bullet and its rotation speed around its axis will increase, which will favorably affect the stability of the ballistic route and, as a consequence, the accuracy of target destruction.

The drawing shows a General view of the bullet.

The bullet contains a shell 1, a core 2 and a sleeve 3. The shell is made of impact-resistant plastic (ABC plastic) by injection molding. In the process of pressing, the orientation of the core in the mold was carried out on the outer surface of the sleeve 3, covering the core 2. In the process of pressing, the grooves 4 on the inner surface of the sleeve were filled with plastic. The core is made by powder metallurgy from VK8 alloy. The core 2 has a spiky shape.

Comparative tests with bullets with carbide core cartridge 7H24. The shell is made of steel and coated with copper, the bullet is made of VK8 alloy, has a pointed warhead. As punched material, bulletproof vest 6B12 and plates made of steel grade 3, GOST 14637-89 of various thicknesses at a distance of 100 m were used. The percentage of penetration of the barrier was determined.

The table shows the results of experiments confirming an increase in the breakdown ability of the proposed bullet.

Shape and properties of core material Penetration of a plate made of steel grade 3 GOST 14637-89 thick at a distance of 100 m Penetration of body armor at a range of 350 m. 16 mm 18 mm 20 mm 24 mm Cartridge 7N24 one hundred% one hundred% twenty% 0% one hundred% The proposed bullet. one hundred% one hundred% one hundred% fifty% one hundred%

As can be seen from the test results, the best indicators of the percentage of destruction of the punched material of the bullet, the shell of which is made of plastic, is additionally equipped with at least one sleeve covering the core, and which is an element that interacts with the surface of the bore, the core is made of hard alloy, has a pointed shape.

An increase in the efficiency of penetrating a thicker plate, which is equivalent to an increase in the damage to the protected target at a further distance, occurs due to a decrease in the loss of kinetic energy spent by the core when it leaves the shell, and destruction of the shell at the moment of a bullet hitting the plate, increasing the speed of the bullet.

Claims (1)

A bullet for a cartridge for small arms, containing a core and a shell, characterized in that it is additionally equipped with at least one bimetallic sleeve covering the core and which is an element that interacts with the surface of the barrel bore, the core has a pointed shape, and the shell is made of thermoplastic polymer material and covers the core without the formation of voids, the sleeve on the inner surface has grooves along the entire length, and the outer surface is flush with the outer surface of the shell ki.