RU2469259C2 - Projectile for rifled gun - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: projectile comprises shell to house two cores, one arranged nearby projectile head and made from harder material and another made from heavier material and provided with blind cavity. First core side surface stays in contact with shell inner surface. Second core adjoins directly the first core. Blind cavity features variable diameter. One its portion on projectile tail side has larger diameter changing into smaller-diameter part in steps. Cavity bottom is located in plane crossing center of gravity of projectile, or at distance not exceeding 0.3 L to said center of gravity, or at distance not exceeding 0.1 L beyond center of gravity. Transition from one cavity part into another is located, at least, 0.3 L to center of gravity. Larger part maximum diameter makes 0.36-0.85 D while smaller part maximum diameter makes 0.03-0.36 D, where D is projectile caliber and L is its length.

EFFECT: higher hitting capacity.

6 cl, 1 dwg

Description

The invention relates to ammunition for firearms, namely to shells for rifled weapons, made, including in the form of bullets.

Known bullet for a hunting cartridge for rifled weapons, containing a shell in which two cores are sequentially placed, the first of which, located closer to the bullet head, is made of lead, and the second is made of plastic. The selection of certain weight and size ratios of the cores solved the problem of ensuring the mass and position of the center of mass of the bullet corresponding to the same parameters as the standard bullet cartridge of the 1943 model, so that the indicated bullet could be used for firing from regular carbines without finalizing the sights (see RU 2003033 , publ. 1993).

As the closest analogue in terms of the set of essential features and the achieved result, an armor-piercing bullet containing a metal shell more durable than lead is placed, in which a steel core is placed, fixed with the back on a gasket made of solid material, on the other side of which there is a lead filling, which occupies the whole the back and partially central region of the shell before laying. From the side of the rear end surface of the filling, a cavity is made that extends to a distance from a strip of solid material. The cavity in the lead filling is made in the form of one or more cylinders, cones, truncated cones, or a combination thereof (see RU 2169898, publ. 2001).

The disadvantages of the closest analogue are low rates of accuracy and armor penetration, due to the following factors:

- due to the weak friction between the steel core and the useful filling, the mobility of the lead core increases, which can lead to premature exit of the steel core from the shell and expose the back of the shell, resulting in a displacement of the center of gravity of the bullet and increase the likelihood of rupture of the back of the bullet;

- due to the possible misalignment of the gasket due to the uneven distribution of pressure on its edges from the lead filling, and in the case of a cavity passing in the lead core to the gasket, the likelihood of premature exit of the steel core from the shell increases, since the pressure acts directly on the gasket;

- due to the possibility of deformation of the bullet when exiting the barrel due to the uncertain parameters of the bottom cavity.

The technical problem to which the present invention is directed is to increase the effectiveness of the damaging effect of the projectile and increase the stability of ballistic characteristics.

The problem is solved in that the projectile for a rifled weapon contains a shell in which two cores are sequentially placed, the first of which, located closer to the head of the projectile, is made of harder material, and the second is made of heavier material, the second core being made blind cavity. The first core is in contact with the inner surface of the shell over its entire lateral surface, the second core is directly adjacent to the first, the blind cavity is made of variable diameter, so that the part of the cavity on the side of the tail of the projectile has a larger diameter and steps into another part of the cavity with a smaller diameter, the bottom of the cavity being located in a plane passing through the center of gravity of the projectile, or located at a distance of not more than 0.3 L, not reaching the center of gravity from the rear end tin plate, or located at a distance of not more than 0.1 L, passing from the rear end to the center of gravity of the projectile, and the place of transition of one part of the cavity to another is located at a distance of at least 0.3 L, not reaching from the rear end to the center the severity of the projectile, while the maximum diameter of most of the cavity is 0.36-0.85 D, and the maximum diameter of the smaller part of the cavity is 0.03-0.36 D, where D is the caliber of the projectile, and L is the length of the projectile.

The projectile can be made in the form of a bullet, and the said cavity can pass into the first core, i.e. its bottom will lie in the first core.

The shell is located on the outer surface of the cores, including the end of the second core and in its cavity, in contact with its surface, forming the specified cavity. Thus, the shell is “closed” and is located around the entire perimeter of the bullet, including the cavity in the second core, which is not limited to the core material, but to the outer surface of the shell.

An insert made of a stronger material than the material of the second core can be installed in the cavity of the second core, for example, in the form of a sleeve or a cup of steel, which eliminates the expansion of the back of the projectile when it leaves the channel of the gun barrel.

The shell can be located on the outer side surface of the cores and on the rear end of the second core, while an insert of a stronger material is installed in the cavity of the second core than the material of the second core, for example, in the form of a sleeve or a cup.

Preferably, the cavity in the second core can be obtained by extruding the core material with a punch, for example, on rotary transfer lines. The experiments showed that such a design is more technological, productive and allows you to get a cavity with minimal deviations in geometric dimensions (almost the same cavity) compared with the implementation of the cavities by drilling. This compaction of the material of the second core, especially the peripheral region adjacent to the cavity, which also helps to exclude the expansion of the rear of the projectile when it leaves the bore of the weapon.

The cavity in the second core could be made of various axisymmetric shapes, preferably in the form of a cylinder or a truncated cone, and combinations thereof.

The technical result obtained by the implementation of the present invention is to increase the accuracy of fire due to the application of part of the force acting on the bullet in the region of the center of mass of the projectile, namely in the region where the bottom of the cavity is located at the above diameters of the cavity, as well as at the transition point of one part cavity into another (per step). In addition, such a cavity slightly softens the shell of the projectile, as a result of which the deformation and the probability of a shell rupturing when leaving the barrel of a weapon are reduced, which also increases the accuracy of fire. This projectile is also technologically advanced to manufacture.

It was found that when the diameter of the smaller part of the cavity is 0.03-0.36 D, if its bottom is located at a distance of not more than 0.3 L from the center of gravity of the projectile towards the rear end or located at a distance of not more than 0.1 L from the center the severity of the projectile towards the head of the projectile, i.e. then, when the point of application of force to the bottom of the projectile is slightly offset from the center of mass, and also with a diameter of most of the cavity 0.36-0.85 D, if the place of transition of one part of the cavity to another is located in the plane at a distance of 0.3 equal to 0.3 L or more from the center of gravity of the projectile towards the rear end, i.e. then, when the point of application of force to the step formed by the said cavities is displaced from the center of mass towards the tail of the projectile, the effect manifested in an increase in the accuracy of fire is manifested to a large extent.

Going beyond the specified cavity length for a given range of cavity diameters leads to a significant deterioration in accuracy indicators. And this is primarily due to overcoming the limit we found for removing the bottom of the cavity and the step of the transition of the cavity of a larger diameter into the cavity of a smaller diameter from the center of gravity of the projectile, which is permissible for a given range of diameters without deterioration in accuracy. This is confirmed experimentally. And theoretically it’s quite understandable, since the pressure force of the powder gases acting on the center of gravity of the projectile or on a point located on the axis of the projectile and close to the center of gravity, most of all gives the projectile the correct direction, reducing any deviation of the projectile from the desired path even with and permissible defects and imperfections of the gun barrel. The experimentally obtained cavity length limits for a given range of diameters, i.e. limiting distances from the center of gravity are also quite explainable. For example, the permissible displacement of the bottom of the cavity from the center of gravity of the projectile towards its rear end to the limit of 0.3 L compared with 0.1 L of the case of displacement towards the head of the projectile is explained by the fact that the displacement of the bottom of the cavity from the center of gravity of the projectile to the rear end does not leads to a displacement of the center of gravity to the front or middle part of the projectile, while a displacement of the bottom of the cavity to the head of the projectile beyond the specified limits (more than 0.1 L from the center of gravity) will lead to a displacement of the center of gravity of the projectile to its middle or front part, which sharply lower indicators of accuracy, since the projectile for rifled weapons most effective (to improve accuracy) position of the center of gravity of the projectile is a region located approximately in the middle between its center and the end. Thus, the effectiveness of the proposed version of the cavities is confirmed not only experimentally, but also completely substantiated theoretically.

If you go beyond the range of the diameters of the cavity under consideration, i.e. when using diameters of a larger or smaller size, it is possible to achieve acceptable accuracy in terms of accuracy only by going beyond the cavity lengths proposed above, but the range of cavity lengths in this case is significantly narrowed to obtain an acceptable result.

From the point of view of a significant improvement in the accuracy of the cavity, it is necessary to take into account the ratio of the length, diameter of the cavity and the distance from the bottom of the cavity of the corresponding diameter to the center of gravity of the projectile. The use of cavities of a relatively small diameter, i.e. 0.03-0.36 D allows, as it were, more accurately (compared to large diameters) to act on the center of gravity or on the longitudinal axis of the projectile near the center of gravity of the projectile, which results in high accuracy in terms of accuracy and expands the ability to effectively use different cavity lengths in the above range.

The specific effective cavity depth 1, i.e. the distance from the rear end of the projectile to the bottom of the cavity, at which the bottom is located in the plane of the center of gravity of the projectile or near it, depends on its specific diameter and the material of the shell of the projectile, which is determined experimentally by calculation.

In addition to the above advantages, this cavity provides an extension of the rear part of the projectile in diameter from the pressure of the powder gases, and therefore, a more snug fit of the rear part to the barrel channel and its cutting, which also increases the speed of the bullet from the gun barrel, improves the rotational effect and accuracy of the battle.

In addition, thanks to the aforementioned cavity, the pressure at the exit of the projectile from the barrel at its end is mainly not on the very rear part, as usual, but on its approximately middle part and, most importantly, on the bottom of the cavity close to the center of gravity of the projectile, which most of all, it increases the stability of the projectile when exiting the barrel, reduces its deviation from the desired trajectory and, accordingly, increases accuracy. In this case, the pressure “pulls” the projectile out of the barrel, rather than pushing it, as in most known shells, and as if “pulls” the center of gravity of the projectile, which is especially important when the projectile leaves the barrel of the weapon.

Also, the achievement of this result is associated with the exclusion of free space in the front of the projectile due to the implementation of the first core, so that it completely occupies the volume under the shell, as well as the exclusion of the gasket from the projectile due to the direct adjacency of the second core to the first.

The invention is illustrated by the figure, which shows the cross section of the projectile.

The projectile contains two cores 2 enclosed in a metal shell 1, in one of which a blind cavity of variable diameter is made on the side of the tail part, so that part 3 of the cavity on the side of the tail part of the shell has a larger diameter and stepwise passes to another part 4 of the cavity having a smaller diameter, the bottom of which is located in a plane passing through the center of gravity of the projectile, or is located at a distance of not more than 0.3 L, not reaching from the rear end to the center of gravity of the projectile, or is located at a distance and not more than 0.1 L, passing from the rear end to the center of gravity of the projectile, while the place of transition of one part of the cavity to another is located in a plane at a distance of 1 equal to at least 0.3 L from plane 5 passing through the center of gravity of the projectile .

Claims (6)

1. A shell for a rifled weapon, comprising a shell in which two cores are sequentially placed, the first of which is located closer to the head of the shell, made of harder material, and the second of heavier material, with a blind cavity in the second core, characterized in that the first core is in contact with the inner surface of the shell over its entire lateral surface, the second core is directly adjacent to the first, the blind cavity is made of variable diameter, so that part of the cavity from the side of the tail of the projectile has a larger diameter and stepwise passes into another part of the cavity with a smaller diameter, the bottom of the cavity being located in a plane passing through the center of gravity of the projectile, or located at a distance of not more than 0.3 L from the center of gravity of the projectile side of the rear end, or located at a distance of not more than 0.1 L from the center of gravity of the projectile towards the head of the projectile, and the place of transition of one part of the cavity to another is located at a distance of 0.3 L or more from the center of gravity of the projectile adnego end, the maximum diameter of the cavity is greater 0,36-0,85 D, and the maximum diameter of the cavity is at 0,03-0,36 D, where D - a projectile caliber, and L - the length of the projectile. 2. The projectile according to claim 1, characterized in that it is made in the form of a bullet. 3. The projectile according to claim 1, characterized in that the shell is located on the outer lateral surface of the cores and in the cavity, in contact with the surface of the core forming the specified cavity. 4. The projectile according to claim 1, characterized in that an insert of a stronger material is installed in said cavity than the material of the second core, for example, in the form of a sleeve or a cup. 5. The projectile according to claim 1, characterized in that the shell is located on the outer lateral surface of the cores and on the rear end of the second core, while an insert of a stronger material is installed in the cavity of the second core than the material of the second core, for example, in the form of a sleeve or a cup. 6. The projectile according to claim 1, characterized in that the cavity in the core is obtained by extruding the core material with a punch.