RU172674U1 - Artillery shell for rifled weapons - Google Patents

Abstract

The proposed utility model relates to military equipment and can be used in the development and modernization of artillery shells for rifled weapons. The objective (technical result) of the proposed utility model is to increase the range of the projectiles when fired. The problem is achieved in that the known artillery shell for rifled weapons contains a steel body and a leading belt, made integrally with it, having the form of annular protrusions separated by annular grooves. The leading belt is characterized in that each of its protrusions has an even number of alternating segments with a normal width and segments with thinning, while on the adjacent protrusions the thinning belts are staggered.

Description

The proposed utility model relates to military equipment and can be used in the development and modernization of artillery shells for rifled weapons.

Known artillery shell for rifled weapons, which implements a method of manufacturing shells of ammunition, when the leading or obturating elements are made as separate parts (usually made of copper M1), having the form of a ring with several protrusions on the outer part, with their subsequent fixing on the shell of the artillery shell ( see B. A. Prokhorov “Ammunition of artillery”, M.: “Engineering”, 1973).

The disadvantages of this artillery shell for rifled weapons are the high cost of non-ferrous metals, the complexity of the installation and the difficulty of controlling the quality of attachment. In addition, when a leading or obturating element of such an artillery shell enters the channel of the gun’s barrel, the presence of high pressure in the barrel-leading or obturating element contact is characteristic; when firing rifled guns on leading or obturating elements of such artillery shells, a “fringe” is formed from the drift to the trailing edge of the leading or obturating element of a significant amount of material of these elements when they are deformed by the cut field of the gun barrel channel; in such artillery shells, it is possible to dismantle the leading or obturating element behind the muzzle of the gun barrel.

In addition, a known artillery shell for rifled weapons (patent No. 2382325, "Artillery shell for rifled weapons", RU C02, IPC F42B 14/02), which is the prototype of the proposed utility model. This device is a leading belt as part of a housing made of C60 steel in the form of annular protrusions of the same length, separated by annular grooves, and constituting a single unit with the shell of the projectile. The width of the steel lead belt is not more than the width of a similar copper lead belt, the annular protrusions in the longitudinal section are rectangular or trapezoidal with a profile angle of not more than 40 °, while the depth of the ring grooves is 1.05-2.5 more than the working height of the lead belt. The main disadvantage of this design is the dependence of the firing range on the obturating action of the leading belt, which is ensured by the magnitude of forcing, which is taken into account when creating the protrusions of the leading belts.

The objective (technical result) of the proposed utility model is to increase the flight range of an artillery shell.

The task is achieved by the fact that in the well-known artillery shell for rifled weapons, which contains a steel body and a leading belt connected to it, the leading belt has annular protrusions, each of which consists of areas with a normal width and a reduced one. In this case, the cutouts are staggered.

In FIG. 1 shows a fragment of the proposed artillery shell with a leading belt.

FIG. 2 represents a fragment of the housing in the region of the driving belt.

The projectile (Fig. 1): 1 — the shell of the projectile, 2 — the region of the leading belt, 3 — part of the annular protrusion with normal width, and 4 — part with thinning.

As shown in FIG. 2, the centering thickening has a diameter D , d1 is the diameter of the bottom of the protrusions of the belt, d2 is the outer diameter of the protrusions, h ₁ is the width of the protrusion in the thinned part, h2 is the normal width of the protrusion, l is the distance between the protrusions.

The size of the protrusions can be determined by the following formulas. The height of each protrusion is determined as follows:

where H is the height of the protrusion,

Δ is the height of the rifling,

ε is the degree of its deformation (based on the experiments, the optimum value is ε , approximately equal to 0.55-0.65, since at these values the optimum specific stress of deformation of the leading belt in the bore is provided),

δ is the value of forcing.

The diameter of the leading belt (for protrusions of maximum length) is calculated based on the following formula:

Thus, the diameter of the projectile in the grooves, taking into account (1):

The width of the protrusions is determined as follows:

where α is the depth of the cutout on the protrusion of the leading belt from each side.

The value of α is selected so that significantly less energy is expended on the collapse of the protrusion of width h ₁ than on the collapse of the protrusion of width h ₂ .

The distance between the protrusions is calculated as follows:

where l ₀ is the distance between the protrusions of the leading belt, similar to the distance in the already used structures.

The number of thinning on each annular protrusion can be arbitrary, optimally an even number (four, six or eight). The total width of the proposed model of the leading belt should not exceed the corresponding dimensions of a typical belt, based on this, the number of protrusions is selected. In addition, to ensure uniform pressure of the powder gases on the shell of the projectile on adjacent protrusions, the thinning belts are staggered.

The proposed utility model works as follows. When the projectile enters the threaded portion of the bore, the protrusions of the leading belt are deformed in accordance with the shape of the rifling of the bore, and to deform the thinned parts 4 (Fig. 1), a lower load is required in comparison with the deformation of the elements of the protrusions of normal width 3. As a result, the deformation the belt takes less pressure energy of the powder gases than to deform the belt with protrusions without thinning. This energy saved increases the kinetic energy of the projectile, thereby increasing its initial velocity when exiting the bore and, accordingly, the firing range. The material of the protrusions displaced by the rifling field is freely located in the annular grooves between the protrusions and practically does not remain in the bore.

Thus, the proposed utility model provides an increase in the flight range of an artillery shell.

Claims (1)

An artillery projectile for a rifled weapon, comprising a steel body and a lead belt made integrally with the case, having the shape of annular protrusions separated by annular grooves, characterized in that each protrusion of the lead belt has an even number of alternating segments with a normal width and segments with thinning, on adjacent protrusions, the thinning belts are staggered.

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