FI130317B - Projectile - Google Patents

Abstract

The invention relates to a projectile (1) with a jacket (2), a core (3) and a stabilizer part (6), which stabilizer part (6) consists of a shaft (8) and of a wing part (7) attached to the shaft (8) ) in the first end (20) of the stabilizer part (6), whereby in the core (3) of the projectile (1) there is a cylindrical cavity (5) which is at least partially closed by a closing part (25), which closing part (25) is provided with an opening (26) for the shaft (8) of the stabilizer part (6), whereby at the other end (30) of the shaft (8) of the stabilizer part (6) is attached a piston (9) which is placed in the cavity (5) to create a space (11) in front of the piston (9), and whereby a channel (12) runs to the space (11) through the shaft (8) of the stabilizer part (6).

Description

PROJECTILE

The object of the invention is a projectile according to the independent claim. The ammo is suitable for use especially, but not only, in heavy weapons, where it offers improved hit accuracy compared to traditional ammo.

Cartridges suitable for weapons typically consist of projectiles, which is a general term that includes all projectiles that can be fired. The main types of ammunition are bullets, grenades and special ammunition. Ammunition can be read as e.g. — sharp arrows, blunt sledgehammers, slingshots, cannonballs, shrapnel, and catapult-fired rocks. A cartridge, on the other hand, refers to a combination of ammunition, in which the projectile with possible detonator, case, powder charge and ball are connected into one entity.

The cartridge as a whole contains all the elements needed to set the projectile in motion. Almost all small-caliber firearms are cartridge-firing weapons.

In a cartridge shot, the projectile and propellant charge are loaded into the gun separately. This type of shot is used especially in large-caliber (over 100 mm) cannons, where the use of a cartridge shot is not meaningful for technical reasons: the physical size and weight of the cartridge would become too large. In this case, a projectile is loaded into the charge chamber first, and then a cartridge containing the propellant — which can be in a brass sleeve containing the detonator, or in a textile or cardboard package, in which case the separate detonator is inserted last before closing the lock.

Textile-packed gunpowder bags are popular, especially in very large-caliber ship cannons,

S so that the amount of driving charge can be easily adjusted in relation to the shooting distance.

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S 25 —Bullet usually refers to the non-explosive part of a small-caliber weapon, usually less than 20 mm

S from the projectile, i.e. the part of the cartridge that is fired at the target. Bullets for hunting guns consist of

E: usually of brass alloy jacket and lead core. The sheath can also be made of soft 5 steel and the core of a metal other than lead. Bullets can also be made entirely of lead

O or made of other metal. Nowadays, it is also used for big game hunting

S 30 — all-copper bullets due to the appropriate softness of the material (does not damage the barrel of the gun) and toughness (changes its shape on impact but does not fragment).

Rihla (groove, scratch) in everyday language most commonly means a gently rotating groove on the inner surface of a firearm's barrel, a groove, the purpose of which is to make a bullet or other projectile rotate during its flight around its longitudinal axis in order to improve accuracy. Today, rifled barrels are used in almost all rifles, pistols and cannons. Non-rifled, i.e. smooth, barrels are used today in shotguns, grenade launchers, rocket launchers, tank cannons and some cannons.

There are mostly four to eight grooves in the barrel of handguns, but other solutions are also used. The number of grooves in rifle caliber guns is usually from four to six, and they are made for the entire length of the barrel. As an exception, a separate, — knurled shrink sleeve made for the shotgun. The distance during which one rib makes a full turn in the barrel is called the rib pitch. The depth of the grooves in a handgun is usually between 0.1-0.3 mm and the rise is about one round at a distance of 20-30 cm. A long bullet usually needs a short rise to stabilize. Too frequent ridge rise may cause a phenomenon called overstabilization, where the bullet does not change its axial angle according to the angle of the flight path. In this case, it — finds itself in an oblique position in its flight path relative to its direction of travel, which is disastrous both in terms of accuracy and power. Also, the pressure level and the weapon's susceptibility to wear may increase, the barrel may copper faster than normal and the accuracy may suffer.

Although rifle-caliber weapons improved their accuracy considerably after the introduction of rifling, the opposite development has also taken place. The accuracy and penetration are good and the first shot against, for example, an enemy tank can be fired from about 3,000 meters away or even further. With a smooth & barrel, higher output velocities can be achieved than with a rifled barrel, which in this context 5 25 — means a longer sweep area and better armor penetration, especially with sub-caliber and arrow ammunition and armor-piercing grenades.

O a Bullets can also have grooves called grooves. This is the case, for example, with some shotgun pellets 5. In this case, we are talking about air rifles, and their purpose is the same as the rifles in the barrel a 30 —: to make the bullet rotate, in this case with the help of air resistance. &

Flechette, or dart projectile or cartridge, is based on arrow-shaped "bullets". They resemble nails with arrow-like wings at the end to stabilize the flight.

They don't shatter on target. Arrow ammunition is used in military operations against human targets. They are designed for various weapons: cannons, rifles, pistols and shotguns. Arrow ammunition is particularly effective against various types of protective equipment such as protective and shrapnel vests and helmets. For this reason, the use of dart ammunition is often limited to official use only.

Small-caliber arrow ammunition is mainly used against other tanks. The arrow projectile used in the smoothbore carriage cannon (100-125 mm) reaches a velocity of over 1,500 m/s. The arrow itself is a "dart" with a diameter of 2-3 cm and more than half a meter (the dimensions depend on the caliber of the weapon), which has small wings that stabilize the flight. The arrow's manufacturing material is a hard and very heavy metal: "tungsten" i.e. tungsten carbide or "DU" (depleted uranium). Arrow projectile penetration is based on very high impact speed, high kinetic energy and small impact area. The tip of the arrow is already inside the carriage, — while the tail is still outside. The high weight of the arrow in relation to the cross-sectional area maintains the flight speed and allows for an earlier opening of fire than other a-munitions, and the short flight time forgives distance and prejudgment errors. The high penetration speed detaches hot fragments from the armor, which cause fires and explosions inside the vehicle, destroying the vehicle's structures and the crew. Oxidation of depleted uranium (DU) during penetration reduces penetration friction and causes an explosion inside the carriage.

Main battle tank (MBT) main gun caliber (100-125 mm) is arrow & larger for firing fragmentation and hollow grenades and missiles. Therefore, the thin arrow is 5 25 — tied to its socket with a sealing and centering sabot, which is, for example, an aluminum sealing sleeve consisting of a sectors. The sabot puts the arrow through the tube and opens = due to air resistance, it detaches from the arrow as the sectors scatter into the front field. The arrow may penetrate several meters of armor steel. Today, the subcaliber projectile is the main pst-5 projectile against heavily armored targets, such as battle tanks. 3 30

N For example, the publication EP 1297293 BI presents a state-of-the-art solution for ammunition. The projectile comprises a casing, a core and a stabilizer part, which stabilizer part consists of a shaft and a wing part attached to the shaft at the first end of the stabilizer part. The heart of the projectile has a cylindrical cavity and in addition a channel passes through the stem.

The solution according to the invention can be considered as a projectile belonging to the group of arrow projectiles. It eliminates or reduces the problems of using traditional arrow ammunition, such as leaving sealing sleeves unnecessary. The design of the projectile allows for a rifle-free barrel, which enables firing with heavy loads. The speed of projectiles fired with larger charges is higher, which results in a stable trajectory and a high impact speed on the hit target.

At the same time, the effect caused by the grooves on the accuracy of the hit can be removed, which becomes — significant when shooting at long distances.

The solution according to the invention comprises a fine-mechanized projectile for a precision weapon, which is fired into motion with a smooth barrel. While the projectile is in the barrel of the weapon, the powder gas generated upon firing pushes out a tail from the rear of the projectile, which stabilizes the trajectory of the projectile after the projectile leaves. The use of a rifled barrel enables the use of higher initial velocities than before and thus the extension of the shooting distance and increased accuracy, especially at long shooting distances. The projectile can be set into a rotating motion, similar to the movement achieved by rifling, by means of the design of the tail. The solution according to the invention eliminates the manufacture of the gun barrel — the manufacture of the rifling, thus making the manufacturing process simpler. The solution according to the invention is particularly, but not exclusively, suitable for large-caliber weapons.

Typically, the solution according to the invention is advantageous for projectiles with a diameter of % inch and larger.

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& — In the following, the invention is explained in more detail with the help of application examples <t

ST by referring to the accompanying simplified drawings in which 3

Tr a figure 1 shows, as a simplified principle drawing, an advantageous 5 projectile according to the invention before the projectile is launched, and

No. 30

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Figure 2 shows, as a simplified principle drawing, an inexpensive projectile according to the invention after the projectile has been fired.

The terms front, front and the like refer below to the direction or surface corresponding to the direction of flight of the projectile, and correspondingly, the terms rear, rear and the like refer to the direction or surface opposite to the direction of flight of the projectile.

Longitudinal direction refers to the direction of the gun's barrel. 5

Figure 1 shows a simplified principle diagram of an inexpensive projectile 1 according to the invention before the projectile is fired. The projectile comprises a shell 2 and a core 3.

The sheath 2 and the core 3 are typically of the same material and the solution according to the invention is suitable for use in all ammunition according to known technology. Ammunition 1 is — attached to the shell 4, in which case the shell contains the teddy bear and gunpowder needed to launch the projectile, which are not shown in Figure 1. When the gun is fired, the teddy bear ignites the gunpowder and when the gunpowder burns, gunpowder gas is formed that sets the projectile in motion. The pressure of the powder gas that forms in the case and later in the barrel propels the projectile through the barrel that gives direction to the projectile.

The core 3 of the projectile 1 has a cylindrical cavity 5, in which the stabilizing part 6 of the projectile, i.e. the tail part, is placed at least partially. The cavity 5 is closed at least partially in its rear part with a closing part 25. The stabilizer part 6 consists of a wing part 7 and a stem 8, the wing part is attached to the first end 20 of the stem, and a piston 9 that enables and stops the movement in the longitudinal direction of the stabilizer part, which is attached to the other end of the stabilizer part 30. The piston of the stabilizer part 6 9 is located in the cavity 5 of the heart 3 and can move longitudinally inside the cavity. The closing part 25 of the cavity 5 has an opening 26 for the arm 8 of the stabilizing part 6. The arm 8 of the stabilizing part 6 can move in the longitudinal direction & inside the opening 26 of the closing part 25. Before firing the projectile 1, the stabilizer part 6 is positioned 5 25 — in its first extreme position according to figure 1, when the piston 9 at the other end of the stabilizer part a is in its front extreme position. The piston 9 of the stabilizing part 6 forms = together with the cavity 5 formed in the core 3, the space 11 for the gunpowder gases of the projectile 1, which are released when the projectile is fired. Gunpowder gases enter the space 11 5 along the channel 12 formed inside the stem of the stabilizing part 6. The wing part 7 of the stabilizing part 6 is a 30 — positioned closed, or almost closed, to the rear part 13 of the projectile 1 before the projectile is launched.

N The rear part 13 of the projectile 1 forms the closing part 25 that at least partially closes the cavity 5 formed in the core 3 of the projectile. The closing part 25 is attached to the projectile on the inner surface of the back part of the cavity 5 with threads 27. When pushing the projectile 1 out of the cavity 5 into the open space 11, the wing part 7 of the stabilizing part 6 stabilizes the projectile 1 trajectory after the projectile leaves the gun barrel. In this example, the sleeve 4 is attached only to the closure part 25, but it must be understood that the sleeve can also extend into the area of the jacket 2 of the projectile 1, in which case the sleeve is attached to both the jacket of the projectile and the closure part. Likewise, the closing part 25 can be smaller in diameter than the diameter of the casing 2 of the projectile 1 at the end on the side of the socket 4, in which case the socket is attached only to the shell of the projectile.

There are sealing rings 14 on the outer surface of the casing 3 of the projectile 1, which seal the gap between the projectile and — the barrel of the weapon. There may be one or more sealing rings 14 around the projectile. These sealing rings 14 prevent gunpowder gas from escaping to the front of the projectile 1 in the barrel of the gun after the projectile is fired and enable the projectile to have maximum acceleration and firing speed.

Figure 2 shows a simplified principle diagram of an inexpensive projectile according to the invention 1 after the projectile has been fired. The gunpowder gases released when the weapon is fired get pushed into the space 11 formed inside the core 3 of the projectile 1 — through the channel 12 passing through the stem 8 of the projectile stabilization part 6. The pressure of the gunpowder gas causes the space 11 to expand, whereby the gunpowder gases push the piston 9 at the end of the stem 8 of the stabilizing part 6 from its first extreme position to its second extreme position and maximize the space 11 in the cavity 5 of the heart 3 of the projectile 1. In its second extreme position, the rear surface 16 of the piston 9 is pressed against the closing part 25. The arm 8 of the stabilizing part 6 and the opening 26 of the closing part 25 are 5 25 — dimensioned so that when the stabilizing part moves from its first extreme position to its second a extreme position, due to the pressure of the gunpowder gases, the arm of the stabilizing part locks into its second = extreme position. Locking is achieved, for example, by making the stem 8 of the stabilizing part 6 slightly thicker, at least in the vicinity of the piston 9, so that it gets stuck in the opening 26 of the closing part 25 when the stabilizing part moves to its other extreme position. When a 30 — the arm 8 of the stabilizing part 6 is firmly attached to the opening 26 of the closing part 25 can

The wing 7 of the stabilizer part N prepares a lift, which enables the projectile 1 to rotate around its own longitudinal axis. The rise of the wings 7 creates the same effect for the projectile 1 as the rifling of the gun barrel. In the solution according to the invention, the barrel of the gun is therefore without a rifle. The wings can also be shaped in another way, in order to get the projectile to rotate around its longitudinal axis.

The solution according to the invention can also consist of more than — one arm 8 with regard to the stabilizer part 6, in which case the arm parts are telescopically opened and locked in their extreme position opened due to friction. Locking is achieved by making the parts of the stem 8 slightly conical, at least at the ends of the stem parts, so that in the opened position of the stem, the outer diameter of the end of the inner stem part is slightly larger than the inner diameter of the outer stem part. In the closed position, the parts of the stem 8 are nested and only open thanks to the pressure of the gunpowder gases and wedge into the locked position. The wing part 7 can be attached to any part 8, in which case one or more stem parts can still extend behind the wing part. The wing part 7 can also be attached to one or more parts of the stem 8. Thanks to the telescopic structure, the length of the projectile 1 can be increased and, if desired, the wing part 7 can be placed further from the shell 2 of the projectile. With such a solution — the trajectory of the projectile 1 can be further stabilized.

The loading of the projectile according to the invention is greater than the projectile according to the corresponding known technology, which results in a higher initial velocity with the projectile. A higher departure speed provides a more stable trajectory and a higher impact speed on the target. — At the same time, the projectile's hit accuracy improves compared to traditional projectiles. This is noticeable especially at long shooting distances. At the same time, we get rid of the effects caused by rifling on the projectile's trajectory and accuracy. The rifling affects the stability of the gun and tends to turn the barrel/tube of the gun while the projectile is in the gun & barrel/tube. The effects of knurling on hit accuracy come to the fore especially 5 25 — when firing precision-required shots at distant targets. Likewise, part of the gunpowder gas pressure can be released through the ribbing a, so a ribless solution like the one in the invention makes more efficient use of the resulting pressure. i 5 The projectile according to the invention also produces a two-part impact on the hit target, which is a 30 — particularly effective against armored targets. When the projectile hits the target

N's first hit comes from the impact of the projectile's shell and heart. At the same time, the stabilizer part, with its piston and wings, can move forward. When the stabilizing part hits the target, a hint of the mantle and heart later, the stabilizing part causes a second blow to the target, which enhances the penetration ability. If it is an embodiment with a telescopic arm 8, there will be several impacts as the telescopic structure collapses after the impact.

It is clear to a person skilled in the art that the invention is not limited exclusively to the examples presented above, but may vary within the framework of the patent claims presented below.

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Claims (11)

PATENT CLAIMS 1. A projectile (1) with a jacket (2), a core (3) and a stabilizer part (6), which stabilizer part (6) consists of a shaft (8) and of a wing part (7) attached to the shaft (8) ) in the first end (20) of the stabilizer part (6), characterized in that in the core (3) of the projectile (1) there is a cylindrical cavity (5) which is at least partially closed by a closing part (25), which closing part (25) is provided with an opening (26) for the shaft (8) of the stabilizer part (6), whereby at the other end (30) of the shaft (8) of the stabilizer part (6) is attached a piston (9) which is placed in the cavity (5) to create a space (11) in front of the piston (9), and whereby a channel (12) runs through the shaft (8) of the stabilizer part (6) to the space (11). 2. Projectile (1) according to patent claim 1, characterized in that the shaft (8) of the stabilizer part (6) becomes wider in the direction of the piston (9) and has a larger diameter than the opening (26) in the closing part (25) at the base of the piston ( 9) to fix the stabilizer part (6) in the closing part (25) by friction. 3. Projectile (1) according to claim 1 or 2, characterized in that the shaft (8) of the stabilizer part (6) consists of more than one part, which parts are telescopically openable and closable and attach to each other through friction in their open position. 4. Projectile (1) according to patent claim 3, characterized in that the wing part (7) is attached to any of the parts of the telescopic shaft (8). 5 Projectile (1) according to patent claim 3, characterized in that the wing part (7) consists of more than one part, which parts of the wing part (7) are attached to more than one part of the telescopic shaft (8). 6. Projectile (1) according to any of the preceding patent claims, characterized in that the wing part (7) of the stabilizer part (6) is designed to set the projectile (1) in rotational motion around its own longitudinal axis. a 7. Projectile (1) according to any of the preceding patent claims, characterized in that - the closing part (25) is connected to the inner surface of the cavity (5) by means of threads (27). i 8. Projectile (1) according to one of the preceding patent claims, characterized in that the shell (2) of the projectile (1) includes at least one sealing ring (14) which seals the projectile (1) against the inner surface of the barrel. N 9. Projectile (1) according to any of the preceding claims 1 - 8, characterized in that a sleeve (4) is attached to the closing part (25). 10. Projectile (1) according to one of the preceding patent claims 1 - 8, characterized in that the sleeve (4) is attached to the closing part (25) and to the shell (2) of the projectile (1). 11. Projectile] (1) according to one of the preceding claims 1 - 8, characterized in that the sleeve (4) is attached to the shell (2) of the projectile (1). ™ N O N < S LO O I a a <t © <t LO AN N O N