HU223259B1 - Armour-piercing bullet and a method for the production of it - Google Patents

Abstract

BACKGROUND OF THE INVENTION The present invention relates to an anti-bullet bullet and a method for making it. The housing (1) consists of a head (A), a nose (B) and an end (C). The core (3) protruding from the housing (1) is fixed to the inner surface (C) of the end portion (1) of the housing (1). The ratio of the core (3) to the average section length of the projectile is 0.3-0.4, their weight ratio is at least 0.45, and the ratio of the thickness (C) of the shell (1) to the end (0.1) 0.2. In the method according to the invention, the core (3) is inserted into the housing (1) by pressing fit with the jacket (2) and the head (A) of the housing (1) is flanged inwards. Simultaneously with the flanging of the head portion (A) of the housing (1), the end portion (C) of the housing (1) is also incised around the core (3). ŕ

Description

BACKGROUND OF THE INVENTION The present invention relates to an anti-bullet projectile and a method for making it. The anti-bullet projectile of the present invention is a handgun designed to defeat an enemy with individual armor defenses.

The pistol bullet known from Russian patent application RU 2018780 (1994) consists of a cup-shaped shell, jacket and core, the head of which protrudes from the face of the housing. The diameter of the core is 0.66 to 0.85 of the caliber of the projectile.

Another anti-tank projectile known from Russian Patent Application RU 2077021 (1997) consists of a casing with a stepped inner surface having a head, a nose and an end. The sheath and the anti-armor core are secured to the housing so that they protrude from the head. The core is secured to the inner surface of the central portion and the end portion of the housing. The outer surface of the casing is stepped and has a protruding front surface and an anti-armor center part between the nose and the end. The central part of the casing is 2-5 times thicker than the nose. In the embodiments of the projectiles known from the Russian patent applications RU 2018780 (1994) and RU 2077021 (1997), the armor is pierced by a solid core having a diameter of 0.66-0.85 part of the caliber of the projectile (mid core and projectile). prevalent intersection ratio 0.43-0.74). At the same time, the specific energy of the core was found to be the most important determinant of the projectile's anti-armor capability, since the sheath and the sheath are practically not involved in penetrating the barrier. The disadvantage of known projectiles is the low armor penetration efficiency, which is determined by the ratio of the projectile parameters.

U.S. Pat. No. 3,069,748 (1962) discloses a method for producing anti-armor projectiles, wherein the core is inserted into the housing by a press fit and the inside of the housing is flared. In the process known from Russian Patent Application RU 2082942 (1997) for producing anti-armor projectiles, wherein the anti-armor core predominantly protrudes from the housing, the core is embossed with the jacket and the shell head is flushed inwardly with the head at the same time, one side of the casing is wrapped around the groove fitting to the core to provide a smooth transition at the outer surface of the casing and core.

In both of the processes for producing anti-shell projectile projectiles, known from U.S. Patent No. 3,069,748 (1962) and Russian Patent Application No. RU 2082942 (1997), the anchorage surface of the core is formed directly in the housing. The core with the jacket is then inserted into the housing by a press fit and then the bullet head is flanged. During the process, the presence of an air cushion may cause a gap to be formed between the core face and the bottom of the casing, which causes deformation of the casing during shooting. Due to the gap between the jacket and the jacket, the jacket may have a wall difference after the bullet has been calibrated. These deficiencies can cause a large variation in ballistic characteristics and a decrease in the in-flight stability of the projectile, which ultimately reduces the projectile's permeability.

SUMMARY OF THE INVENTION The present invention is directed to a high-impact anti-bullet projectile having a size and a reciprocal pulse similar to that of the same type of ammunition, and to a method for producing the projectile.

According to the present invention, this object is achieved with respect to the anti-tank projectile by:

the anti-armor projectile includes a stepped casing consisting of a head portion, a nose portion and an end portion, an anti-armor core disposed so as to protrude from the casing and secured to the inner surface of the casing end portion, and the casing;

- the ratio of core to projectile section in the middle length is 0.3-0.4;

- a core to projectile weight ratio of at least 0.45;

- the ratio of the casing thickness measured at the end portion to the core diameter is 0.1-0.2.

The object of the present invention in terms of the process is achieved by inserting the core into the casing by pressing with the jacket and flattening the casing head in such a way that, at the same time as the casing head is flanged, the end portion is also flared inward.

The invention will now be described in more detail with reference to the accompanying drawings, in which:

Figure 1 is a semi-sectional side view of a projectile of the invention, a

Figure 2 shows the position of the projectile components in the sticker and stamp prior to the flange operation,

Figure 3 is a view of the projectile after flipping the housing head around the core, a

Figure 4 shows the thickness of the punched steel plate as a function of the range of the shot

Figure 5: Volume of temporary pulsating cavity formed in gelatin block as a function of range.

The projectile according to the invention, shown in Figure 1, consists of a housing 1, a jacket 2 and a core 3. The stepped casing 1 comprises a head part A, a nose part B and an end part C. The end portion C of the housing 1 has an inner cavity formed along its surface to secure the core 3. After inserting the sheath 2 and the core 3 into the rectangular cup 1, the components are placed in the die 4 as shown in Figure 2. By pushing the bullet through the stamp 5, the head A of the cover 1 is flattened in the die 4 until the cover 1 closes on the core 3. The opening D of the stamp 5 is equal to the sum of the diameter of the core 3 and twice the thickness of the cladding wall. By further advancing the stamp 5, a curved version occurs in the head portion A of the housing 1 and further deformation of the housing 1 occurs by flanging the housing 1 around the end portion C of the core 3. As a result, the casing 1 is tightly coupled to the

EN 223 259 B1 at core A and end C and the sheath as shown in Figure 3.

The aforementioned essential features, the ratio of the mass and size characteristics of the projectile, are interrelated, and any change in the projectile will result in the deterioration of the projectile's anti-tank properties.

The center-to-section ratio of the core 3 and the projectile is 0.3-0.4 and their weight ratio is at least 0.45. If the ratio of the core 3 to the average section length of the projectile falls below 0.3, due to ballistic constraints on the projectile length, the relative mass of the core 3 decreases and the specific energy of the core 3 decreases, i.e., the armor penetration is reduced.

The ratio of the thickness of the casing 1 at the end portion C to the diameter of the core is 0.1-0.2. The most important determinant of the anti-bullet capability of the projectile in question is the specific energy of the 3 cores. The sheath 1 and the sheath 2 are practically not involved in penetrating the obstacle because they are more ductile than the obstacle and the core 3 and therefore compressed upon impact, thereby utilizing their kinetic energy. Therefore, in the area where the core 3 is joined, the thickness of the sheath 1 must be determined from the strength of the projectile that it has at the time of the shot. Corresponding to the above, the ratio of the thickness of the casing 1 to the diameter of the core 3 is 0.1 to 0.2. Further increasing the thickness of the casing 1 causes an increase in the passive mass of the projectile and a reduction in the projectile disintegration at the moment of the shot.

All of the features of the described embodiment, without departing from the scope of the invention, in combination with the proposed method of producing a projectile, provide superior armor-piercing properties that are superior to those of any known pistol projectile.

The projectiles of the invention are designed for Makarov pistol (PM) ammunition. They were tested by firing on steel plates and 80x80x140 mm gelatin blocks. The thickness "t" of the perforated steel plate as a function of the range "L" is shown in Figure 4.

In this case, standard ammunition will not penetrate a 2.4 mm thick plate, even when directly fired. The "V" volume of the temporary pulsating cavity (TPC) formed in the gelatin block as a function of the range "L" is shown in Figure 5. The diagram shows that the TPC volume of the E projectile according to the invention is far greater than the TPC volume of the conventional F projectile. In this way, the permeability and damage to the Makarov pistol ammunition recommended by the present invention goes far beyond conventional ammunition.

The projectile of the present invention can be used in virtually all types of ammunition for rifled barrels, but is most effective in ammunition used to attack short and medium range targets. The projectile production method of the invention, from small-scale production to mass production on automatic production lines, is applicable to all types of production, while allowing the maintenance of tooling sets and manufacturing operations.

Claims (5)

An armor-piercing projectile comprising a stepped casing (1) consisting of a head portion (A), a nose portion (B) and an end portion (C), and an anti-armor core (3) positioned therein, protruding therefrom, which is fixed to the inner surface (C) of the end portion (C) of the casing (1) and the casing (2), characterized in that the ratio of the center (3) to the projectile is 0.3-0.4 having a weight ratio of at least 0.45 and a ratio of the thickness (C) of the casing (1) to the core (3) of 0.1-0.2. Method for producing an anti-tank projectile according to claim 1, characterized in that the core (3) is inserted into the housing (1) by pressing fit with the jacket (2), and the head (A) of the housing (1) is flattened inwards, at the same time as flanging the head part (A) of the housing (1), the end portion (C) of the housing (1) is also flared inwardly around the core (3). HU 223 259 Bl Int Cl ⁷ : F 42 B 12/06 Figure 1 HU 223 259 ΒΙ Int. Cl. ’: F 42 B 12/06 Figure 2 HU 223 259 Bl Int CP: F 42 B 12/06 Figure 3 HU 223 259 ΒΙ Int Cl ⁷ : F 42 Β 12/06 Figure 4 HU 223 259 ΒΙ Int Cl ⁷ : F 42 B 12/06 Figure 5