RU2668580C1 - Armour-piercing finned projectile - Google Patents

Abstract

FIELD: weapons and ammunition.SUBSTANCE: invention relates to artillery ammunition, and in particular to armor-piercing shells for smooth-bore or rifled artillery systems of medium or large caliber of unitary, separate-cylinder or cap-loading. Device comprises a housing on which is mounted a sector drive unit and a feather stabilizer with blades. Stabilizer is located in the rear part of the body. Tail part of the body is hollow. Inside this cavity a small cumulative projectile with a bottom fuse having a retarder is installed, the deceleration time of which is determined from the analytical expression.EFFECT: increasing armor penetration without changing the speed and mass of the projectile.1 cl, 3 dwg

Description

The invention relates to artillery ammunition, in particular to armor-piercing shells for smooth-bore or rifled artillery systems of medium or large caliber unitary, separate-shell or cartridge-mounted loading.

Known feathered armor-piercing armor-piercing shells (BPS), containing an elongated sub-caliber solid shell, containing a sector master device and a feather stabilizer installed in the rear of the shell (BPS "Hope" - Wikipedia). The disadvantage is the low penetration ability of armored obstacles (less than 340 mm at right angles) at the maximum possible speed of the projectile approach to the armor. At such a speed of approach of the projectile to the semi-infinite armor, part of the shell of the projectile remains intact (approximately 40-50 mm). The lengthening of the shell of such a projectile does not give a significant increase in armor penetration.

Known feathered subcaliber projectile containing an elongated subcaliber assembly building in the form of a high-strength tubular shell, inside of which heavy alloy rods are mounted on fusible solder. The projectile also has a sector master and a feather stabilizer installed in the rear of the hull (BPS "Mango" - Wikipedia). The disadvantage is the same - low penetration ability of armored obstacles (less than 450 mm at right angles) at the maximum possible speed of approach of the projectile to the armor. This speed for the Mango BPS is 1700 m / s. Additional armor penetration in comparison with the Nadezhda BPS is ensured by advance (with respect to the shell of the projectile) movement at a certain stage of armor penetration of internal rods of a heavy alloy of small diameter (diameter about 18 mm) compared to the diameter of the main body (diameter about 36 mm) . Nevertheless, at such a speed of approach of the projectile to the semi-infinite armor, part of the shell of the projectile remains intact (approximately 35-40 mm).

In order to increase the armor-piercing action of the sub-caliber projectile, it is proposed to install a small-sized cumulative projectile in the tail of the hollow shell of the projectile after the cores of heavy alloy. In this case, at the same speed of approach of the projectile to the armor, and the penetration ability of the main body and the heavy alloy rods is exhausted, the small-sized cumulative projectile will additionally pierce another part of the armor, since an elongated metal core will be formed when the explosive charge of the cumulative projectile explodes funnels with high speed (more than 4000 m / s) and small diameter (about 4 mm). Such a projectile is capable of penetrating armor up to 5 caliber funnel thick. With a funnel gauge of 25 mm, the projectile is capable of penetrating armor with a thickness of more than 100 mm, which will be an increase of more than 30% with respect to the armored penetration of the Mango BPS. Thereby, the claimed effect is achieved - increased armor penetration without changing the velocity and mass of the projectile. It should be noted that for the effective operation of the cumulative projectile its bottom fuse should work with a slowdown. Namely, it must ensure the detonation of the explosive of a cumulative projectile after a period of time during which the main part of the combined shell of the projectile (shell and internal rods of heavy alloy) is working. The magnitude of this deceleration can be estimated from the ratio 2H / V, where H is the thickness of the obstacle pierced by a sub-caliber projectile without a cumulative projectile, V is the velocity of the projectile approach to the obstacle. The construction scheme of such a projectile (tail) is shown in FIG. one.

FIG. 1. The tail of the modernized shell "Mango": 1 - steel shell shell; 2 - fusible solder; 3 - tungsten core; 4 - stabilizer; 5 - cumulative funnel; 6 - explosive; 7 - fuse U560. FIG. 2. General view of the design of the modernized shell "Mango". FIG. 3. The results of firing shells "Mango" with an additional cumulative projectile in the rear of the armor plate with a thickness of 350 mm: No. 3 - shell without charge (V = 1326 m / s); No. 7 - a projectile with a cumulative charge (V = 1372 m / s).

The result of increasing armor penetration and the possibility of technical implementation of the claimed technical solution are verified experimentally. At the NIMI production site (Moscow), the author performed work on the modernization of the Mango BPS by introducing a small-sized cumulative projectile into its back. A slight increase in the mass of the projectile was offset by replacing the steel feather stabilizer with an aluminum alloy stabilizer. The dimensions of the design of the shell of the MPS BPS projectile made it possible to place a cumulative projectile with a height of not more than 50 mm and a cumulative funnel diameter of 24 mm in an elongated (50 mm) steel shell of the projectile. In FIG. 1 shows a diagram of the change in the tail of the projectile into which the cumulative projectile (positions 5, 6, 7) is introduced and the stabilizer 4 is changed. The fuse for the cumulative projectile was designed and manufactured by the specialists of NITI named after P.I. Snegireva. " The fuse's peculiarity is that it provides a delay in detonation by the time the projectile enters the armor crater. The design of such a projectile is shown in FIG. 2.

Firing was carried out with new shells from the standard gun of the T-72 tank. The shells worked properly. The cumulative projectile with a fuse withstood the overload of a tank gun with a standard charge. For comparison, firing was carried out with and without a small-sized shaped-charge cumulative shell. In FIG. 3 shows the data of firing of such shells at the armor plate.

Shelling was carried out on a reduced charge at a speed of approximately 1350 m / s due to the fact that armored plates with a thickness of more than 350 mm were not on the range. At the first stage of the experiments, shooting at an angle was not planned. The speed of the shell was chosen so that the shell with a new element, but without explosives, the armor plate was not broken. This condition is realized by shot No. 3. On the lower part of FIG. 3 shows data on the results of firing a projectile with an installed cumulative element. As can be seen from the above data, a new projectile with a working cumulative element of the armor plate is broken.

The experiments showed the feasibility of the proposed new design of the projectile.

A new method is proposed for increasing the power of BPS due to the combination of armor-piercing sub-caliber and cumulative shells in one projectile, which can give a new impetus to the creation of high-power ammunition.

The above information about the claimed invention, characterized in an independent claim, indicates the possibility of its implementation using the described in the application and known means and methods. Therefore, the claimed technical solution meets the condition of industrial applicability.

Claims (1)

An armor-piercing feathered sub-caliber projectile containing a housing, a sector master device mounted on the housing, a feather stabilizer with blades located in the rear of the housing, characterized in that the tail of the housing is hollow, and a cumulative shell with a bottom fuse having a moderator is strengthened inside this cavity , the deceleration time of which is determined from the ratio 2H / V, where N is the thickness of the obstacle pierced by a sub-caliber projectile without a cumulative projectile, V is the velocity of the projectile approach to the obstacle.

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