RU2453802C1 - Projectile for rifled fire weapon - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: projectile for a rifled weapon comprises a vessel, in which at the side of a tail part along the body axis there is a dead cavity. The cavity bottom is located in the plane stretching via a centre of gravity of the projectile or is located at the distance of not more than 0.3 L from the centre of gravity of the projectile towards the rear end, or is installed at the distance of not more than 0.1 L from the centre of gravity of the projectile towards the projectile head. The maximum diametre d of the cavity makes 0.03-0.36 D, where D is the projectile calibre, and L is the projectile length.

EFFECT: improved ballistic characteristics of a projectile.

10 cl, 1 dwg

Description

The invention relates to ammunition for rifled firearms, including bullets for small arms, small-caliber shells, etc.

Hollow lead bullets were widely used for firing smooth-bore rifles - Neisler, Mignier, "Belgian bullet" (see Fedorov V.V. Evolution of small arms. - M., 1938, part 1, p.40.). Similar lead bullets are also used today for firing from hunting smoothbore guns and from pneumatic weapons.

So, for example, a hunting bullet is known that contains a hollow body with a flat head and a leading belt (see FR 2122697, publ. 1972) or a bullet with a spherical head and a body in the form of upper and lower truncated cones, moreover, the body is made the bottom cavity in the form of a truncated cone passing into the cylinder (SU 1822492, publ. 1993). The shape of the cavities in these bullets is combined with specific forms of the head parts of the bullets, which are not universal (flat and spherical head parts, respectively).

The cavities in such known lead bullets were intended primarily to ensure stabilization of their flight due to the maximum possible displacement of the center of mass of the bullet towards the warhead. Therefore, the cavity sometimes extended almost the entire length of the bullet. The low pressure of the powder gases when using smoke powders made it possible to ensure the strength of lead bullets during a shot at a greater depth of the cavity. The wads used in cartridges for smoothbore weapons also contributed to this. When using a wad, the pressure of the powder gases in the bore affects mainly the wad itself, and not the cavity in the pool.

With the transition to rifled weapons, smokeless gunpowder and shell bullets, the conditions for the operation of bullets during firing have changed significantly and the use of such hollow bullets for rifled weapons has almost lost its meaning.

However, in modern shell bullets, a cavity is used in their tail part. For example, a domestic 7.62 mm rifle light bullet has a conical void in the tail, which provides an increase in the length of the leading part of the bullet while maintaining the mass of the bullet (Fedorov V.V. Evolution of small arms. - M., 1939, part 11, p. 154). The purpose of the void in the light pool was to improve the obturation when firing from worn trunks and to improve the accuracy of firing due to this.

The disadvantage of such bullets is the relatively small length of the cavity, which leads to uneven distribution of pressure and fit to the rifling of the barrel, which does not allow for sufficient accuracy and accuracy of fire.

Known pistol bullet containing a metal shell and a lead casing having a cavity in the rear part, and the cavity is made with a depth of 0.55-0.95 length of the healing (central) part (RU 2100769, publ. 1997). The cavity can be made in the form of a truncated cone or several truncated cones. The depth of the cavity in such bullets is limited by the strength requirements of the bullets during firing, since the pressure force of the powder gases can lead to bullet inflation and possible undesirable consequences in this regard.

A significant drawback of this bullet is that the experimental search for the most effective cavity of the corresponding diameter and length, which for different bullets depending on their type and materials used, can be limited to only a small interval (0.55-0.95 length of the masticatory part ) Given the relatively small length of the masticatory part (in different bullets, the data vary - this is approximately 1 / 5-1 / 3 of the bullet length on average), it can be argued that the range of experimental search for the most effective cavity in this case is reduced, limited, which entails the possibility of losing the most effective cavity parameters.

An analysis of possible structural solutions showed that the execution of cavities of relatively small cross sections, but extending to the middle part of the bullet and beyond, does not significantly affect the strength characteristics of bullets, however, due to the choice of the shape and size of the cavity and the radial stiffness of the bullet in the region of the cavity, the regulation of interaction forces is facilitated bullets with a barrel, that is, the management of the ballistic process. In addition, the shape of the elongated cavity contributes to a more uniform distribution of the pressure of the powder gases when the bullet moves in the barrel.

As the closest analogue in terms of the set of essential features and the achieved result, a bullet was selected containing a body in which a central cavity is made on the tail side, this cavity is in the form of a cylinder or a truncated cone, or a combination of a cylinder with a truncated cone, or a combination of cylinders of different diameters and passes into the cavity in the form of a cylinder of a smaller diameter or cone to the head of the bullet, while the cavity in the form of a cylinder or a truncated cone in the tail of the bullet passes to a distance of 0.2 ... 0, 8 from the length of the bullet, and a cavity in the form of a cylinder of small diameter or cone passes to a distance of 0.2 ... 0.9 from the length of the bullet (RU 2150667, publ. 2000).

Known bullet is characterized by:

- the creation of a sufficiently uniformly distributed pressure of the powder gases in the cavity of the bullet, which ensures increased accuracy and accuracy of the battle;

- ensuring sufficient pressure of the tail and central parts of the bullet on the rifling of the barrel in the case of a rifled weapon, that is, controlling the shape of the gas pressure curve;

- providing a higher accuracy of the battle due to the increase in the length of the leading part of the bullet, as well as due to the maximum possible increase in the length of the cavity in order to create pressure of the powder gases on the head of the bullet;

- the creation of a fairly uniform pressure of the tail and central parts of the bullet adjacent to the rifling.

The disadvantage of the closest analogue is somewhat underestimated indicators of accuracy of fire (although higher than that of analogues), as well as the low strength of the bullet body, when performing a cavity with a depth close to the length of the bullet and, especially, with a relatively large diameter. In this case, the accuracy is significantly reduced.

The technical problem to which the present invention is directed is to increase ballistic characteristics while maintaining a high striking ability and manufacturability of the projectile.

The problem is solved in that the projectile for a rifled weapon contains a housing in which a blind cavity is made on the side of the tail along the axis of the housing. The bottom of the cavity 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 from the center of gravity of the projectile towards the rear end or is 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, the maximum diameter d 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 shell may be provided with a shell in which the enclosure is enclosed, in the form of a core.

The shell can be made of metal, bimetal, plastic and others, including composite materials.

The shell can be located on part or on the entire side surface of the body and at the same time can cover part of the head region of the body (a variant of the so-called semi-shell bullet).

The projectile can be made in the form of a bullet.

The cavity in the core can be made of various axisymmetric shapes: in the form of a cylinder, cone, truncated cone, hemisphere, polyhedron, and combinations thereof.

The shell may be located on the outer surface of the core, including along its end and in the cavity of the core, 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 a cavity in the 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 core material, for example, in the form of a sleeve or a cup made of steel, can be installed in the cavity of the core, which eliminates excessive expansion of the rear of the projectile when it exits the barrel of the weapon.

The shell can be located on the outer side surface of the core and on its rear end, while in the center of the end part in the shell a hole is made that communicates with the cavity in the core, while an insert of a stronger material than the core material can be installed in the core cavity, for example, in the form of a sleeve or a cup of steel.

Preferably, the cavity in the housing can be obtained by extruding the housing material with a punch. 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. In this case, the material of the body (core) is densified, especially the peripheral region adjacent to the cavity, which also helps to exclude the expansion of the rear part of the projectile when it leaves the channel of the gun barrel.

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 cavity diameters. 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 with a maximum cavity diameter in the range of 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 of gravity of the projectile towards the head of the bullet, i.e. then, when the point of application of force on the projectile is close to the center of mass, the effect, expressed in increasing the accuracy of fire, is most significant. 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, as it were, to overcoming the limit we found for the removal of the bottom of the cavity 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 to 0.1L in 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 lead 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 decreased it’s indicators on accuracy, since for shells to rifled weapons the most effective (for improving accuracy) position of the center of gravity is the region of the projectile located approximately in the middle between its center and 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 larger diameters, 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. Consideration of such an option is beyond the scope of this application for invention.

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 (in comparison with 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 leads to high accuracy in terms of accuracy and expands the possibility of the effective use of various cavity lengths in the above range.

The specific effective cavity depth l, 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 cavity, the pressure when the projectile leaves the barrel at its end is mainly not on its very back, 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 shell, which most of all 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.

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

The projectile comprises a housing 2 enclosed in a metal shell 1, in which a blind cavity 3 is made on the rear side of the housing axis, the bottom 4 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 towards the rear end face, 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 bullet, and its maximum diameter, i.e. the diameter of the widest part of the cavity is 0.03-0.36 D, where D is the caliber of the projectile.

Lead, steel, and other suitable material are used as the body material.

In the case of a shell, the core of the projectile can be composite, i.e. consist of two, three or more parts made of one material.

It is sometimes advisable to make a composite core from a combination of different materials. Such a core device allows you to better control the position of the center of gravity of the projectile and its weight, and also depending on the purpose (armor-piercing, hunting, etc.), to select the materials of the composite core most correctly and efficiently to enhance the effectiveness of the projectile. For example, in various combinations, materials such as steel, lead, aluminum alloys, titanium, plastic, and others, including polymeric and composite materials, can be used for a composite core. The cavity in such composite cores can pass through one, two or more layers, but the main thing is that the parameters of a particular cavity and the location of the bottom of the cavity relative to the center of gravity of the projectile correspond to the above range.

Claims (10)

1. A projectile for a rifled weapon, comprising a body, in which a blind cavity is made on the side of the tail along the body axis, characterized in that the bottom of the cavity 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 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 of gravity of the projectile towards the head of the projectile, while the maximum diameter d 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. 2. The projectile according to claim 1, characterized in that it is provided with a shell in which the housing is enclosed, in the form of a core. 3. The projectile according to claim 2, characterized in that the shell is located on the outer surface of the core and in the said cavity, in contact with the surface of the core forming the specified cavity. 4. The projectile according to claim 2, characterized in that an insert of a stronger material is installed in the core cavity than the core material, for example, in the form of a sleeve or a cup. 5. The projectile according to claim 2, characterized in that the shell is located on the outer lateral surface of the core and on its rear end, while an insert of a stronger material is installed in the core cavity than the core material, for example, in the form of a sleeve or a cup. 6. The projectile according to claim 2, characterized in that the shell is located on the outer side surface of the core and on its rear end, while in the center of the end part of the shell a hole is made that communicates with the cavity in the core. 7. The projectile according to claim 2, characterized in that the shell covers the lateral and partially head part of the core with exposure of the head part of the core. 8. The projectile according to claim 2, characterized in that the core is made of two or more parts of the same material or different materials. 9. The projectile according to claim 1, characterized in that the cavity in the housing is obtained by extruding the material of the housing by the punch. 10. The projectile according to claim 1, characterized in that it is made in the form of a bullet.