RU223456U1 - CARTRIDGE - Google Patents

Abstract

The utility model relates to cartridges. The technical result is to increase the stability of the firing accuracy characteristics. The cartridge contains an encapsulated cartridge case, a powder charge, and a bullet. The bullet contains a hard alloy core, equipped with a lead jacket and jacket. The core has a mass deviation from the nominal value Mn.s. within the tolerance range equal to ±(0.011÷0.0585) Mn.s., where Mn.s. - nominal core mass. The mass of the bullet has the value Mn.p.±(0.0124÷0.0120)Mn.p., where Mn.p. - nominal bullet weight. The force of extracting a bullet from the cartridge case has the value Mn.s.±(0.167÷0.125) Mn.s., where Mn.s. - the nominal value of the force to extract the bullet from the cartridge case. 1 ill.

Description

The utility model relates to small arms ammunition, namely, to cartridges designed to destroy firing points in lightly armored military vehicles.

A small arms cartridge is known, consisting of a primed cartridge case with a powder charge and a bullet mounted in it, consisting of a lead jacket core and a shell, while the ratio of the lengths of the head and guide parts of the bullet is made equal to 1/1 to 5/1, the bullet is mounted in the case with coverage and crimping of the cartridge case neck along the perimeter of the guide and along the perimeter of the head surface of the bullet, while the height of the annular surface of contact of the crimped cartridge case neck with the surfaces of the head and guide parts of the bullet is made equal to 0.5...1.2 calibers, on the outer surface of the barrel, crimped along around the perimeter of the bullet head, there is an annular sealing groove with a width equal to 0.1-0.2 calibers, the head and guide parts of the bullet are made in the form of a combination of a conical or conical convex surface with a cylindrical one.

(Patent RU2 502 939).

The disadvantage of this technical solution is that the cartridge does not control the force of removing the bullet from the cartridge case. A large spread in the values of the extraction force of the bullet from the cartridge case has a significant impact on the accuracy of the cartridge. This is due to the fact that the force of removing a bullet from the barrel is determined by the compression force of the barrel and the contact area of the barrel surface and the surface of the bullet. The presence of an annular sealing groove along the width and the design of the bullet guide part, made in the form of a combination of a conical or conical convex surface with a cylindrical one, will lead to a large variation in the force of extracting the bullet from the barrel. This will lead to a dispersion in the speed at which the bullet leaves the barrel of the weapon and, as a consequence, to a decrease in the accuracy of the battle.

There are known technical solutions for cartridges developed by the authors (RF Patents 199760, 199549). Cartridges for small arms with a hard alloy core, contain a steel sleeve with an igniter primer, a propellant powder charge, a bullet having a shell, a lead jacket, a hard alloy core, the deviation of the core mass from the nominal value (Mn.) is within the tolerance range equal to (0.011÷0.0585)Mn., where Mn. - nominal core mass. (Patent 199549 taken as a prototype).

Bullets with carbide cores are significantly superior in penetration to bullets with hardened steel cores and are mostly used for sniper weapons. The disadvantage of these technical solutions is the lack of combat accuracy. This is due to the fact that there is no control parameter, the effort to extract the bullet from the barrel of the cartridge case, which largely determines the accuracy of the battle. Another parameter that affects the accuracy of shooting is the spread of bullet weight in one batch of cartridges. This parameter is also absent in these technical solutions, which reduces the accuracy of fire with these cartridges.

The problem that this technical solution is aimed at is the creation of a cartridge with high tactical and technical characteristics.

The technical result achieved in the process of solving the problem is to increase the stability of the characteristics of the accuracy of fire.

The technical result is achieved by a cartridge containing an encapsulated cartridge case, a powder charge, a bullet containing a hard alloy core having a deviation of the core mass from the nominal value (Mn) within a tolerance field equal to (0.011÷0.0585) Mn., where Mn. - the nominal mass of the core, equipped with a lead jacket and shell, characterized in that the bullet has a mass within the tolerance range equal to (0.0124÷0.0120) Mn.p., where Mn.p. the nominal mass of the bullet in one batch of bullets and the force of removing the bullet from the cartridge case within the limits of (0.167÷0.125) Mn.s., where Mn.s. - the nominal value of the force to extract the bullet from the cartridge case.

The kinetic energy of a bullet is determined by the speed at which the bullet leaves the barrel and its mass. The smaller the spread of parameters in terms of speed and weight, the higher the accuracy of the cartridge. Since the cartridge consists of several elements, the energy of the powder charge is spent on interaction with these elements. Energy is spent on obtaining kinetic energy by the core (giving speed to the core), obtaining kinetic energy of the shell and lead jacket, obtaining the energy necessary to eject the bullet from the case (removing the bullet from the case), obtaining energy to overcome friction as the bullet passes through the barrel. In this technical solution, it is proposed to use cartridges equipped with bullets, the mass of which is within the tolerance range equal to (0.0124÷0.0120) Mn.p., in addition, the bullet must be compressed in the cartridge case so that the force for removing the bullet from the cartridge case is within (0.167÷0.125)Mn. Fulfillment of these conditions will lead to a more stable kinetic energy of the bullet when fired, and as a result to improved accuracy.

In fig. Figure 1 shows the design of the proposed cartridge, where L is the length of the bullet, which is equal to L=(3.52-4.60)d, where d is the caliber of the bullet, 1 is the bullet, 2-steel sleeve, 3-propellant powder charge, 4- igniter primer, 5 - bullet connection in the cartridge case.

Implementation of the proposed technical solution.

A pilot batch of cartridges with cores made of hard tungsten-cobalt alloy was produced. VK6. The cartridges were loaded at FUP Vympel. The bullet contained a steel jacket and a lead jacket. Sorting of bullets by mass was carried out on laboratory scales. For testing, bullets were used that were within the tolerance range (0.0124÷0.0120) Mn.p. The loading of the core into the bullet casing was carried out on automatic machines. The parameter “effort to extract a bullet from a cartridge case” was controlled by preliminary settings of the automatic machine.

Comparative tests were carried out with 7N24M cartridges having a bullet with a carbide core. The percentage of the core hitting a circle with a diameter of 32 mm, out of 10 shots, was determined. Shooting was carried out from a 5.45 mm AK74M assault rifle equipped with an optical sight at a target distant at 100 and 550 m.

The table shows the results of comparative tests.

Cartridge Distance 100 m
Distance 550 m
Cartridge 7N24 100 70 Cartridge according to the proposed
technical solution 100 100

As can be seen from the test results, the cartridge according to the proposed technical solution has the best performance in terms of firing accuracy.

Thus, the totality of all the relationships between the design parameters of the cartridge indicated in the formula ensures the creation of a cartridge that has higher characteristics in terms of firing accuracy. These ratios can be used to create cartridges of various calibers.

Claims (1)

A cartridge containing an encapsulated cartridge case, a powder charge, a bullet containing a hard alloy core, equipped with a lead jacket and shell, having a deviation of the core mass from the nominal value of the Mn.s. within a tolerance field equal to ±(0.011÷0.0585) Mn.s, where Mn.s is the nominal mass of the core, characterized in that the mass of the bullet in one batch of bullets will have the value Mn.p. ±(0.0124÷0.0120)Mn.p., where Mn.p. - the nominal mass of the bullet, and the force of extracting the bullet from the barrel of the cartridge case, in one batch of bullets, will have the value Mn.u. ±(0.167÷0.125)M.s., where M.s. - the nominal value of the force to extract the bullet from the cartridge case.