How an armor-piercing projectile works. What is a sub-caliber projectile? The principle of operation of a sub-caliber projectile. Fragmentation and high-explosive shells

) and 40 tons ("Puma", "Namer"). In this regard, overcoming the armor protection of these vehicles is a serious problem for anti-tank ammunition, which includes armor-piercing and cumulative projectiles, rockets and rocket-propelled grenades with kinetic and cumulative warheads, as well as striking elements with an impact core.

Among them, armor-piercing sub-caliber shells and missiles with a kinetic warhead are the most effective. Possessing high armor penetration, they differ from other anti-tank munitions in their high approach speed, low sensitivity to the effects of dynamic protection, the relative independence of the weapon guidance system from natural / artificial interference, and low cost. Moreover, these types of anti-tank munitions can be guaranteed to overcome the active protection system of armored vehicles, which is increasingly becoming widespread as a front line for intercepting striking elements.

Currently, only armor-piercing sub-caliber shells have been adopted for service. They are fired mainly from smooth-bore guns of small (30-57 mm), medium (76-125 mm) and large (140-152 mm) calibers. The projectile consists of a two-bearing leading device, the diameter of which coincides with the diameter of the barrel bore, consisting of sections separated after departure from the barrel, and a striking element - an armor-piercing rod, in the bow of which a ballistic tip is installed, in the tail - an aerodynamic stabilizer and a tracer charge.

As the material of the armor-piercing rod, ceramics based on tungsten carbide (density 15.77 g / cc), as well as metal alloys based on uranium (density 19.04 g / cc) or tungsten (density 19.1 g / cc) are used. cc). The diameter of the armor-piercing rod ranges from 30 mm (obsolete models) to 20 mm (modern models). The higher the density of the rod material and the smaller the diameter, the greater the specific pressure exerted by the projectile on the armor at the point of its contact with the front end of the rod.

Metal rods have much greater bending strength than ceramic ones, which is very important when the projectile interacts with active protection shrapnel elements or explosive dynamic protection plates. At the same time, the uranium alloy, despite its somewhat lower density, has an advantage over tungsten - the armor penetration of the first is 15-20 percent greater due to the ablative self-sharpening of the rod in the process of penetrating armor, starting from an impact speed of 1600 m / s, provided by modern cannon shots.

The tungsten alloy begins to exhibit ablative self-sharpening starting at 2000 m/s, requiring new ways to accelerate projectiles. At a lower speed, the front end of the rod flattens out, increasing the penetration channel and reducing the penetration depth of the rod into the armor.

Along with the indicated advantage, the uranium alloy has one drawback - in the case of nuclear conflict neutron radiation penetrating the tank induces secondary radiation in the uranium, which affects the crew. Therefore, in the arsenal of armor-piercing shells, it is necessary to have models with rods made of both uranium and tungsten alloys, designed for two types of military operations.

Uranium and tungsten alloys also have pyrophoricity - the ignition of heated metal dust particles in air after breaking through the armor, which serves as an additional damaging factor. The specified property manifests itself in them, starting from the same speeds as the ablative self-sharpening. Dust is another damaging factor. heavy metals, which has a negative biological effect on the crew of enemy tanks.

The leading device is made of aluminum alloy or carbon fiber, the ballistic tip and aerodynamic stabilizer are made of steel. The lead device serves to accelerate the projectile in the bore, after which it is discarded, so its weight must be minimized by using composite materials instead of aluminum alloy. The aerodynamic stabilizer is subjected to thermal effects from the powder gases generated during the combustion of the powder charge, which can affect the accuracy of shooting, and therefore it is made of heat-resistant steel.

armor penetration kinetic projectiles and missiles is defined as the thickness of a homogeneous steel plate, installed perpendicular to the flight axis of the striking element, or at a certain angle. In the latter case, the reduced penetration of the equivalent thickness of the plate is ahead of the penetration of the plate, installed along the normal, due to the large specific loads at the entrance and exit of the armor-piercing rod into / out of the inclined armor.

Upon entering the sloping armor, the projectile forms a characteristic roller above the penetration channel. The blades of the aerodynamic stabilizer, collapsing, leave a characteristic "star" on the armor, by the number of rays of which it is possible to determine the belonging of the projectile (Russian - five rays). In the process of breaking through the armor, the rod is intensively ground off and significantly reduces its length. When leaving the armor, it elastically bends and changes the direction of its movement.

A characteristic representative of the penultimate generation of armor-piercing artillery ammunition is the Russian 125-mm separate-loading round 3BM19, which includes a 4Zh63 cartridge case with the main propellant charge and a 3BM44M cartridge case containing an additional propellant charge and the 3BM42M "Lekalo" sub-caliber projectile itself. Designed for use in the 2A46M1 gun and newer modifications. The dimensions of the shot allow it to be placed only in modified versions of the automatic loader.

The ceramic core of the projectile is made of tungsten carbide, placed in a steel protective case. The leading device is made of carbon fiber. As the material of the sleeves (except for the steel pallet of the main propellant charge), cardboard impregnated with trinitrotoluene was used. The length of the cartridge case with the projectile is 740 mm, the length of the projectile is 730 mm, the length of the armor-piercing rod is 570 mm, and the diameter is 22 mm. The weight of the shot is 20.3 kg, the cartridge case with the projectile is 10.7 kg, the armor-piercing rod is 4.75 kg. The initial speed of the projectile is 1750 m / s, armor penetration at a distance of 2000 meters along the normal is 650 mm of homogeneous steel.

The latest generation of Russian armor-piercing artillery ammunition is represented by 125-mm separate-loading rounds 3VBM22 and 3VBM23, equipped with two types of sub-caliber projectiles - respectively 3VBM59 "Lead-1" with an armor-piercing rod made of tungsten alloy and 3VBM60 with an armor-piercing rod made of uranium alloy. The main propellant charge is loaded into the 4Zh96 "Ozon-T" cartridge case.

The dimensions of the new projectiles coincide with the dimensions of the Lekalo projectile. Their weight is increased to 5 kg due to the greater density of the rod material. To disperse heavy projectiles in the barrel, a more voluminous main propellant charge is used, which limits the use of shots, including Lead-1 and Lead-2 projectiles, only new cannon 2A82, which has an enlarged charging chamber. Armor penetration at a distance of 2000 meters along the normal can be estimated as 700 and 800 mm of homogeneous steel, respectively.

Unfortunately, the Lekalo, Lead-1 and Lead-2 projectiles have a significant design flaw in the form of centering screws located along the perimeter of the supporting surfaces of the leading devices (protrusions visible in the figure on the front supporting surface and points on the surface of the sleeve ). The centering screws serve to guide the projectile steadily in the bore, but their heads at the same time have a destructive effect on the surface of the bore.

In foreign designs of the latest generation, precision obturator rings are used instead of screws, which reduces barrel wear by a factor of five when fired with an armor-piercing sub-caliber projectile.

The previous generation of foreign armor-piercing sub-caliber projectiles is represented by the German DM63, which is part of a unitary shot for the standard 120 mm NATO smoothbore gun. Armor-piercing rod is made of tungsten alloy. The weight of the shot is 21.4 kg, the weight of the projectile is 8.35 kg, the weight of the armor-piercing rod is 5 kg. Shot length is 982 mm, projectile length is 745 mm, core length is 570 mm, diameter is 22 mm. When firing from a cannon with a barrel length of 55 calibers, the initial speed is 1730 m / s, the speed drop on the flight path is declared at the level of 55 m / s for every 1000 meters. Armor penetration at a distance of 2000 meters normal is estimated at 700 mm of homogeneous steel.

The latest generation of foreign armor-piercing sub-caliber projectiles includes the American M829A3, which is also part of the unitary shot for the standard 120-mm NATO smoothbore gun. Unlike the D63 projectile, the armor-piercing rod of the M829A3 projectile is made of a uranium alloy. The weight of the shot is 22.3 kg, the weight of the projectile is 10 kg, the weight of the armor-piercing rod is 6 kg. Shot length is 982 mm, projectile length is 924 mm, core length is 800 mm. When firing from a cannon with a barrel length of 55 calibers, the initial speed is 1640 m/s, the speed drop is declared at the level of 59.5 m/s for every 1000 meters. Armor penetration at a distance of 2000 meters is estimated at 850 mm homogeneous steel.

When comparing the latest generation of Russian and American sub-caliber projectiles equipped with armor-piercing uranium alloy cores, a difference in the level of armor penetration is visible, to a greater extent due to the degree of elongation of their striking elements - 26-fold for the lead of the Lead-2 projectile and 37-fold for the rod projectile М829А3. In the latter case, a quarter greater specific load is provided at the point of contact between the rod and armor. In general, the dependence of the armor penetration value of shells on the speed, weight and elongation of their striking elements is shown in the following diagram.

An obstacle to increasing the elongation of the striking element and, consequently, the armor penetration of Russian projectiles is the automatic loader device, first implemented in 1964 in the Soviet T-64 tank and repeated in all subsequent models of domestic tanks, which provides for a horizontal arrangement of projectiles in a conveyor, the diameter of which is not may exceed the internal width of the hull, equal to two meters. Taking into account the case diameter of Russian shells, their length is limited to 740 mm, which is 182 mm less than the length of American shells.

In order to achieve parity with the cannon weapons of a potential enemy for our tank building, the priority for the future is the transition to unitary shots, located vertically in an automatic loader, the shells of which have a length of at least 924 mm.

Other ways to increase the effectiveness of traditional armor-piercing projectiles without increasing the caliber of guns have practically exhausted themselves due to restrictions on the pressure in the barrel chamber developed during the combustion of a powder charge, due to the strength of weapon steel. When moving to a larger caliber, the size of the shots becomes comparable to the width of the tank hull, forcing the shells to be placed in the aft niche of the turret with increased dimensions and a low degree of protection. For comparison, the photo shows a shot of 140 mm caliber and a length of 1485 mm next to a mock shot of a 120 mm caliber and a length of 982 mm.

In this regard, in the United States, within the framework of the MRM (Mid Range Munition) program, active missiles MRM-KE with kinetic warhead and MRM-CE with HEAT warhead. They are loaded into the cartridge case of a standard 120-mm cannon shot with a propellant charge of gunpowder. The caliber body of the shells contains a radar homing head (GOS), a striking element (an armor-piercing rod or a shaped charge), impulse trajectory correction engines, an accelerating rocket engine and a tail unit. The weight of one projectile is 18 kg, the weight of the armor-piercing rod is 3.7 kg. The initial speed at the level of the muzzle is 1100 m/s, after the completion of the accelerating engine, it increases to 1650 m/s.

Even more impressive figures have been achieved in the framework of the creation of an anti-tank kinetic rocket CKEM (Compact Kinetic Energy Missile), whose length is 1500 mm, weight 45 kg. The rocket is launched from a transport and launch container using a powder charge, after which the rocket is accelerated by an accelerating solid-propellant engine to a speed of almost 2000 m / s (Mach 6.5) in 0.5 seconds.

The subsequent ballistic flight of the rocket is carried out under the control of the radar seeker and aerodynamic rudders with stabilization in the air using the tail unit. The minimum effective firing range is 400 meters. The kinetic energy of the damaging element - armor-piercing rod at the end of jet acceleration reaches 10 mJ.

During the tests of the MRM-KE projectiles and the CKEM rocket, the main drawback of their design was revealed - unlike sub-caliber armor-piercing projectiles with a separating leading device, the inertia flight of the striking elements of a caliber projectile and a kinetic missile is carried out assembled with a body of large cross-section and increased aerodynamic resistance, which causes a significant drop in speed on the trajectory and a decrease in the effective firing range. In addition, the radar seeker, impulse correction engines and aerodynamic rudders have a low weight perfection, which forces to reduce the weight of the armor-piercing rod, which negatively affects its penetration.

The way out of this situation is seen in the transition to the separation in flight of the caliber body of the projectile / rocket and the armor-piercing rod after the completion of the rocket engine, by analogy with the separation of the leading device and the armor-piercing rod, which are part of the sub-caliber projectiles, after their departure from the barrel. Separation can be carried out with the help of an expelling powder charge, which is triggered at the end of the accelerating section of the flight. Reduced-size seeker should be located directly in the ballistic tip of the rod, while the flight vector control must be implemented on new principles.

A similar technical problem was solved as part of the BLAM (Barrel Launched Adaptive Munition) project to create small-caliber guided artillery shells, performed at the Adaptive Aerostructures Laboratory AAL (Adaptive Aerostructures Laboratory) of Auburn University by order of the US Air Force. The aim of the project was to create a compact homing system that combines a target detector, a controlled aerodynamic surface and its drive in one volume.

The developers decided to change the direction of flight by deflecting the projectile tip at a small angle. At supersonic speed, a fraction of a degree deflection is enough to create a force capable of implementing a control action. A simple technical solution was proposed - the ballistic tip of the projectile rests on a spherical surface, which plays the role of a ball bearing, several piezoceramic rods are used to drive the tip, arranged in a circle at an angle to the longitudinal axis. Changing their length depending on the applied voltage, the rods deflect the tip of the projectile to the desired angle and with the desired frequency.

The calculations determined the strength requirements for the control system:
- accelerating acceleration up to 20,000 g;
- acceleration on the trajectory up to 5,000 g;
- projectile speed up to 5000 m / s;
— tip deflection angle up to 0.12 degrees;
— drive actuation frequency up to 200 Hz;
- drive power 0.028 watts.

Recent advances in the miniaturization of infrared radiation sensors, laser accelerometers, computing processors and lithium-ion power supplies resistant to high accelerations (such as electronic devices for guided missiles - American and Russian), make it possible in the period up to 2020 to create and adopt kinetic projectiles and missiles with an initial flight speed of more than two kilometers per second, which will significantly increase the effectiveness of anti-tank munitions, and also make it possible to abandon the use of uranium as part of their striking elements.

This article will look at the various types of ammunition and their armor penetration. Photographs and illustrations of traces of armor remaining after a projectile hit are given, as well as an analysis of the overall effectiveness of various types of ammunition used to destroy tanks and other armored vehicles.
When studying this issue, it should be noted that armor penetration depends not only on the type of projectile, but also on the combination of many other factors: firing range, muzzle velocity, type of armor, armor slope angle, etc. mm armor plates of various types. The shelling was carried out with 75-mm armor-piercing shells in order to show the difference in the resistance of armor of the same thickness, but of different types.

The iron armor plate had a brittle fracture of the rear surface, with numerous spalls in the area of the hole. The impact speed is chosen in such a way that the projectile is stuck in the plate. Penetration is nearly achieved with a projectile speed of just 390.3 m/s. The projectile itself was not damaged at all, and will certainly work properly, breaking through such armor.

Iron-nickel armor, without hardening according to the Krupp method (that is, in fact - structural steel) - demonstrated plastic failure with a classic "envelope" (cross-shaped tear on the rear surface), without any traces of fragmentation. As you can see, close to the previous test, the projectile impact speed no longer even leads to through penetration (hit No. I). And only an increase in speed to 437 m / s leads to a violation of the integrity of the rear surface of the armor (the projectile did not penetrate the armor, but a through hole was formed). To achieve a result similar to the first test, it is necessary to bring the speed of the projectile to the armor up to 469.2 m/s (it would not be superfluous to recall that the kinetic energy of the projectile grows in proportion to the square of the speed, i.e. almost one and a half times!). At the same time, the projectile was destroyed, its charging chamber was opened - it will no longer be able to work properly.

Krupp armor - the high hardness front layer contributed to the splitting of shells, while the softer base of the armor deformed, absorbing the energy of the projectile. The first three shells collapsed almost without even leaving marks on the armor plate. Projectile No. IV, which hit the armor at a speed of 624 m / s, also completely collapsed, but this time almost squeezing out the “cork” in its caliber. We can assume that with a further, even a slight increase in the speed of the meeting, a through penetration will occur. But to overcome the Krupp armor, the projectile had to be given more than 2.5 times more kinetic energy!

Armor-piercing projectile

The most massive type of ammunition used against tanks. And as the name implies, it was created specifically for breaking through armor. According to their design, armor-piercing shells were solid blanks (without an explosive charge in the body) or shells with a chamber (inside which an explosive charge was placed). Blanks were easier to manufacture and hit the crew and mechanisms of an enemy tank only at the point of penetration of the armor. Chamber shells were more difficult to manufacture, but when armor was pierced, explosives exploded in the chamber, causing more damage to the crew and mechanisms of an enemy tank, increasing the likelihood of detonation of ammunition or arson of fuel and lubricants.

Also, the shells were sharp-headed and blunt-headed. Equipped with ballistic tips to give the correct angle when meeting with sloped armor and reduce ricochet.

HEAT projectile

Cumulative projectile. The operating principle of this armor-piercing ammunition differs significantly from the principle of operation of kinetic ammunition, which includes conventional armor-piercing and sub-caliber projectiles. A cumulative projectile is a thin-walled steel projectile filled with a powerful explosive - RDX, or a mixture of TNT and RDX. At the front of the projectile, explosives have a goblet-shaped recess lined with metal (usually copper). The projectile has a sensitive head fuse. When a projectile collides with armor, an explosive is detonated. At the same time, the lining metal is melted and compressed by an explosion into a thin jet (pestle), flying forward at an extremely high speed and penetrating armor. Armored action is provided by a cumulative jet and splashes of armor metal. The HEAT shell hole is small and has melted edges, which has led to a common misconception that HEAT shells “burn through” armor. The penetration of a HEAT projectile does not depend on the velocity of the projectile and is the same at all distances. Its production is quite simple, the production of the projectile does not require the use a large number scarce metals. The cumulative projectile can be used against infantry and artillery as a high-explosive fragmentation projectile. At the same time, cumulative shells during the war years were characterized by numerous shortcomings. The manufacturing technology of these projectiles was not sufficiently developed, as a result, their penetration was relatively low (approximately corresponded to the caliber of the projectile or slightly higher) and was characterized by instability. The rotation of the projectile at high initial speeds made it difficult to form a cumulative jet, as a result, the cumulative projectiles had a low initial velocity, a small effective range and high dispersion, which was also facilitated by the non-optimal shape of the projectile head from the point of view of aerodynamics (its configuration was determined by the presence of a notch). The big problem was the creation of a complex fuse, which should be sensitive enough to quickly undermine the projectile, but stable enough not to explode in the barrel (the USSR was able to work out such a fuse, suitable for use in powerful tank and anti-tank guns, only at the end of 1944 ). The minimum caliber of a cumulative projectile was 75 mm, and the effectiveness of cumulative projectiles of this caliber was greatly reduced. Mass production of HEAT shells required the deployment of large-scale production of hexogen. The most massive HEAT shells were used by the German army (for the first time in the summer-autumn of 1941), mainly from 75 mm caliber guns and howitzers. The Soviet army used cumulative shells, created on the basis of captured German ones, from 1942-43, including them in the ammunition of regimental guns and howitzers that had a low muzzle velocity. The British and American armies used shells of this type, mainly in heavy howitzer ammunition. Thus, in the Second World War (in contrast to the present time, when improved projectiles of this type form the basis of the ammunition load of tank guns), the use of cumulative projectiles was quite limited, mainly they were considered as a means of anti-tank self-defense of guns that had low initial speeds and low armor penetration by traditional projectiles (regimental guns, howitzers). At the same time, other anti-tank weapons were actively used by all participants in the war. cumulative ammunition- grenade launchers (illustration No. 8), air bombs, hand grenades.

Sub-caliber projectile

Sub-caliber projectile. This projectile had enough complex structure, which consisted of two main parts - an armor-piercing core and a pallet. The task of the pallet, made of mild steel, was to disperse the projectile in the bore. When the projectile hit the target, the pallet was crushed, and the heavy and hard sharp-headed core made of tungsten carbide pierced the armor. The projectile did not have an explosive charge, ensuring that the target was hit by core fragments and armor fragments heated to high temperatures. Sub-caliber shells had a significantly lower weight compared to conventional armor-piercing shells, which allowed them to accelerate in the gun barrel to significantly higher speeds. As a result, the penetration of sub-caliber shells turned out to be significantly higher. The use of sub-caliber shells made it possible to significantly increase the armor penetration of the existing guns, which made it possible to hit more modern, well-armored armored vehicles even with outdated guns. At the same time, sub-caliber shells had a number of disadvantages. Their shape resembled a coil (there were shells of this type and streamlined shape, but they were much less common), which greatly worsened the ballistics of the projectile, in addition, the light projectile quickly lost speed; as a result, at long distances, the armor penetration of sub-caliber shells dropped dramatically, turning out to be even lower than that of classic armor-piercing shells. Sub-caliber shells did not work well on sloped armor, because under the action of bending loads the hard but brittle core easily broke. The armor-piercing effect of such shells was inferior to armor-piercing caliber shells. Sub-caliber projectiles of small caliber were ineffective against armored vehicles that had protective shields made of thin steel. These shells were expensive and difficult to manufacture, and most importantly, scarce tungsten was used in their manufacture. As a result, the number of sub-caliber shells in the ammunition load of guns during the war years was small, they were allowed to be used only to destroy heavily armored targets at short distances. The German army was the first to use sub-caliber shells in small quantities in 1940 during the fighting in France. In 1941, faced with heavily armored Soviet tanks, the Germans switched to the widespread use of sub-caliber shells, which significantly increased the anti-tank capabilities of their artillery and tanks. However, the shortage of tungsten limited the release of shells of this type; as a result, in 1944, the production of German sub-caliber shells was discontinued, while most of the shells fired during the war years had a small caliber (37-50 mm). Trying to get around the problem of tungsten, the Germans produced Pzgr.40(C) sub-caliber shells with a steel core and Pzgr.40(W) surrogate shells, which are a pallet sub-caliber projectile without a core. In the USSR, a fairly mass production of sub-caliber shells, created on the basis of captured German ones, began at the beginning of 1943, and most of the shells produced were of 45 mm caliber. The production of these shells is over large calibers was limited by the shortage of tungsten, and they were issued to the troops only when there was a threat of an enemy tank attack, and a report was required for each expended projectile. Also, sub-caliber shells were used to a limited extent by the British and American armies in the second half of the war.

high-explosive projectile

High-explosive fragmentation projectile. It is a thin-walled steel or steel-cast iron projectile filled with an explosive (usually TNT or ammonite), with a head fuse. Unlike armor-piercing shells, high-explosive shells did not have a tracer. Upon hitting the target, the projectile explodes, hitting the target with fragments and a blast wave, either immediately - a fragmentation action, or with some delay (which allows the projectile to go deeper into the ground) - a high-explosive action. The projectile is intended mainly to destroy openly located and covered infantry, artillery, field shelters (trenches, wood-and-earth firing points), unarmored and lightly armored vehicles. Good armored tanks and self-propelled guns are resistant to high-explosive fragmentation shells. However, projectile impact large caliber can cause the destruction of lightly armored vehicles, and damage to heavily armored tanks, consisting in cracking of armor plates (illustration No. 19), jamming of the turret, failure of instruments and mechanisms, injuries and shell shock to the crew.

Literature / useful materials and links:

Artillery (State Military Publishing House of the People's Commissariat of Defense of the USSR. Moscow, 1938)
Artillery Sergeant's Manual ()
Artillery book. Military publishing house of the Ministry of Defense of the USSR. Moscow - 1953 ()
Internet materials

And passive (pallet), made according to the caliber of the gun. In the first BPS, the pallet was an integral part of the projectile, but already in 1944, British ammunition designers developed their modern modification - an armor-piercing sub-caliber projectile with a separating pallet from the active part after it left the bore. BPS with separating pallet - basic anti-tank projectile in ammunition modern tanks. Armor-piercing sub-caliber shells with an integral pallet also continue to be used, but to a greater extent as ammunition for automatic small-caliber guns, where the implementation of a pallet that separates from the active part is difficult or impossible. There are BPS stabilized in flight by rotation and plumage.

English designations for BPS types

In foreign, and after them in domestic publications on the relevant topic, the following abbreviations are often used English designations BPS types:

APCR - A rmour- P iercing C composite R igid (armor-piercing composite rigid) - BPS with an integral pallet and a harder active part (core);
APCNR - A rmour- P iercing C composite N on- R igid (armor-piercing composite non-rigid) - BPS with an integral collapsible pallet and a harder active part (core) for artillery pieces with a conical bore;
APDS - A rmour- P iercing D iscarding S abot (armor-piercing sub-caliber with a detachable pallet);
APFSDS, APDS-FS - A rmour- P iercing D iscarding S abot- F in- S tabilized (armor-piercing feathered sub-caliber with a detachable pallet).

Armor-piercing feathered sub-caliber projectiles (BOPS, OBPS)

With the adoption of the T-62 medium tank, the USSR became the first country in the world to massively use armor-piercing feathered armor in tank ammunition. sub-caliber ammunition(BOPS). Thanks extremely high speed and long range direct shot.

Armor-piercing shells for the 115-mm gun U-5TS (2A20) were superior in armor penetration at an angle of 60 degrees. from the normal, the best sub-caliber shells for rifled guns by 30% and had a direct shot range 1.6 times greater than regular ones. However, unitary shots for the GSP U-5TS did not allow to fully realize the potential for rate of fire and reduce the internal reserved volume of a promising tank, in addition, due to increased gas contamination fighting compartment T-62 designers were forced to resort to a mechanism for removing spent cartridges, which somewhat reduced the rate of fire of the tank. Thus, the problem of automating the process of loading a tank gun became urgent, which, along with an increase in the rate of fire, significantly reduced the internal volume, and, consequently, security.

At the beginning of 1961, work began on the creation of 115-mm separate-loading rounds with OBPS, cumulative and high-explosive fragmentation shells for the D-68 (2A21) gun.

Completion of work on the creation of separate loading shots for the D-68 gun, installed in a new medium tank with mechanized loading, was successfully completed, and the newly created ammunition was put into mass production in 1964.

In 1966, the T-64 tank with the D-68 gun and new shots for it was put into service.

However, for a number of reasons, the 115 mm caliber gun of the T-64 tank was considered insufficient to ensure guaranteed destruction of promising foreign tanks. Perhaps the reason was an overestimated assessment of the armor resistance of the new, most powerful English tank of that period, the Chieftain, as well as fears of the imminent entry into service of the promising American-German MBT-70 tank, which was never put into service. For these reasons, an improved version of the T-64 tank was created, which received the designation T-64A and was adopted by the Soviet Army in May 1968. The tank was armed with a 125 mm D-81T (2A26) gun developed in 1962 at the plant number 172 (Perm) in OKB-9 under the leadership of F.F. Petrov.

Subsequently, this gun, which deserved a lot of positive reviews for its high technical and performance characteristics underwent numerous upgrades aimed at further growth of its characteristics. Upgraded versions guns D-81T (2A26) such as 2A46M, 2A46M-1, 2A46M-2, 2A46M-4 are the main armament of domestic tanks to this day.

The beginning of the 60s and the end of the seventies, the adoption of OBPS stabilized by plumage.

The late 1960s and late 1970s were characterized by evolutionary development foreign tanks, the best of which had a homogeneous armor shield within 200 (Leopard-1A1), 250 (M60) and 300 (Chieftain) millimeters of armor. Their ammunition included BPS for 105 mm L7 guns (and its American counterpart M68) and 120 mm L-11 rifled gun of the Chieftain tank.

At the same time, a number of OBPS for 115 and 125 mm GSP tanks T-62, T-64 and T-64, as well as 100 mm smoothbore anti-tank guns T-12, entered service in the USSR.

Among them were shells of two modifications: solid-shell and having a carbide core.

One-piece OBPS 3BM2 for PTP T-12, 3BM6 for GSP U-5TS of the T-62 tank, as well as one-piece OBPS for 125 mm GSP 3BM17, which was intended primarily for export and crew training.

OBPS with a carbide core included 3BM3 for the GSP U-5TS of the T-62 tank, 125 mm OBPS 3BM15, 3BM22 for the T-64A / T-72 / T-80 tanks.

Second generation (late 70s and 80s)

In 1977, work began to improve the combat effectiveness of tank artillery rounds. The staging of these works was associated with the need to defeat new types of reinforced armor protection developed abroad for a new generation of M1 Abrams and Leopard-2 tanks. The development of new design schemes for OBPS has begun, ensuring the destruction of monolithic combined armor in a wide range of angles of impact with the armor, as well as overcoming remote sensing.

Other tasks included improving the aerodynamic qualities of the projectile in flight in order to reduce drag, as well as increasing its muzzle velocity.

The development of new alloys based on tungsten and depleted uranium with improved physical and mechanical characteristics continued. The results obtained from these research projects made it possible at the end of the 70s to begin the development of new OBPS with an improved master device, which ended with the adoption of the Nadezhda, Vant and Mango OBPS for the 125-mm GSP D-81.

One of the main differences between the new OBPS compared to those developed before 1977 was a new master device with sectors of the "clamp" type using aluminum alloy and polymer materials.

In OBPS, before that, leading devices with steel sectors of the "expanding" type were used.

In 1984, the OBPS 3VBM13 "Vant" was developed with the 3BM32 projectile of increased efficiency, "Vant" became the first domestic monoblock OBPS made of a uranium alloy with high physical and mechanical properties.

OBPS "Mango" was developed specifically to destroy tanks with combined and dynamic protection. The design of the projectile uses a highly effective combined core made of tungsten alloy placed in a steel casing, between which there is a layer of low-melting alloy.

The projectile is able to overcome dynamic protection and reliably hit the complex composite armor of tanks that entered service in the late 70s and until the mid-80s.

In terms of the development of BOPS, since the late nineties, a lot of work has been done, the backlog of which was BOPS 3BM39 "Anker" and 3BM48 "Lead". These projectiles were significantly superior to such BOPS as the Mango and Vant, the main difference was the new principles of the guidance system in the bore and the core with a significantly increased elongation.

The new projectile guidance system in the bore not only allowed the use of longer cores, but also made it possible to improve their aerodynamic properties.

It was these products that served as the basis for the creation of modern domestic OBPS of a new generation. The results obtained from these works served as a basis for the creation of new, modern projectiles.

After the collapse of the USSR in the early 90s, a sharp degradation of the domestic military-industrial complex began, which had a particularly painful effect on the industry for the production of new types of ammunition. During this period, the issue of modernizing the ammunition load of both domestic and exported tanks arose. The development, as well as small-scale production of domestic BPS, continued, however, mass introduction and large-scale production of new generation BPS samples were not carried out. Positive trends in some aspects of this issue have emerged only recently.

Due to the lack of modern BPS, a number of countries with a large fleet of domestic tanks armed with a 125 mm gun have made their own attempts to develop BPS.

One of the tasks of a modern main battle tank is the destruction of similar enemy equipment, for which it requires a powerful weapon and appropriate armor-piercing shells. Russian tanks are armed with several anti-tank munitions that allow them to deal with well-protected enemy vehicles. In addition, in the near future, new samples intended for use with weapons of advanced technology should go into large-scale production.

Armor-piercing feathered sub-caliber projectiles (BOPS) show the highest armor penetration characteristics. Such ammunition appeared several decades ago, and later proved to be a convenient means of destroying armored vehicles with powerful protection different types. As a result, at present, it is BOPS that turn out to be the main tool for tanks to fight other tanks. The development of this class of projectiles continues.

Serial "Mango"

According to various sources, Russian armored units are currently armed with several types of BOPS, and the most massive representative of this class is the 3BM-42 Mango product. The development of a new projectile with increased power under the code "Mango" began in the first half of the eighties. Through the use of certain materials, technologies and solutions, it was necessary to increase armor penetration in comparison with existing projectiles. The future projectile 3BM-42 was supposed to be used with the existing tank guns of the 2A46 family.

The T-72B3 main tank carries an improved automatic loader compatible with extended projectile lengths. Photo Vitalykuzmin.net

A few years later, the 3VBM-17 round with the 3BM-42 BOPS entered service. It includes the so-called. a burning cylinder, inside of which a driving device with a projectile is rigidly attached. Also, a separate partially combustible cartridge case with means of ignition is used for the shot. The cavities of the sleeve and cylinder are filled with tubular powder, which ensures the acceleration of the projectile.

The creators of the Mango projectile coped with the task of increasing armor penetration, and they did it in a very interesting way. The projectile has a special design, due to which an increase in the main characteristics is achieved. At the same time, outwardly, 3BM-42 is almost no different from other products of its class. This BOPS is a hollow cylindrical body of small diameter, made of steel and equipped with a tail stabilizer. The front end of the body is closed with a ballistic cap and the so-called. armor-piercing damper. Two tungsten cores are located one behind the other in the housing cavity, held in place by a low-melting metal jacket.

A resettable lead device made of aluminum is installed on the projectile. It has a conical shape with a widening front. Interaction with the bore is provided by several rings on the outer surface of the device. Shot 3VBM-17, including a cylinder, a projectile and a leading device, has a length of 574 mm with a diameter of 125 mm. The mass of the projectile itself is 4.85 kg.

Shot 3VBM-17 with a projectile 3BM-42 "Mango". Photo Fofanov.armor.kiev.ua

The combustion of gunpowder in the sleeve and cylinder makes it possible to accelerate the projectile with the driving device to a speed of no more than 1700 m / s. After exiting the barrel, the master device is reset. Upon hitting the target, the holding jacket melts, after which tungsten cores can pierce armor. The maximum armor penetration at a distance of 2 km is determined as 500 mm. With a meeting angle of 60 ° at the same distance, this characteristic is reduced to 220 mm.

The 3VBM-17 shot with the 3BM-42 projectile was put into service in 1986 and had a noticeable effect on fighting qualities all existing main tanks Soviet army. This product is still used in tank troops and is almost the basis of their arsenals. Subsequently, modernization was carried out, which consisted in increasing the length of the body and cores. As a result, "Mango-M" weighs 5 kg and can penetrate up to 270 mm of armor at an angle of 60 °.

Long way "Lead"

Soon after the appearance of the Mango BOPS, well-known unpleasant events began in our country that hit a lot of areas, including the development of promising shells for tank guns. Only by the end of the nineties was it possible to obtain real results in the form of another projectile with improved performance. This ammunition was the result of development work with the code "Lead".

Scheme of the product "Mango". Figure Btvt.narod.ru

Experience has shown that a further increase in the main combat characteristics is associated with a mandatory increase in the length of the projectile. This parameter was increased to 740 mm, but this fact did not allow the use of the future projectile with existing tank loaders. As a result, the next project for the modernization of armored vehicles had to include an update of the automation that serves the gun.

From the point of view of the general appearance, the 3VBM-20 shot with the 3BM-46 "Lead-1" projectile is somewhat similar to the older 3VBM-17 and also consists of a projectile in a burning cylinder and a cartridge case with a metal pallet. At the same time, the design of the projectile itself is seriously different from the existing one. This time it was decided to use a monolithic depleted uranium core (according to other sources, from a tungsten alloy), which is actually the basis of the projectile. A ballistic cap and tail stabilizers are attached to the metal core, the diameter of which is less than the caliber of the barrel.

For a longer projectile, an improved lead device was created. It is distinguished by its large length and the presence of two contact zones. In front of the device there is a large cylinder of the usual type, and the second zone is created by three rear supports. After exiting the barrel, such a master device is reset and releases the projectile.

"Mango-M" and a cartridge case with a propelling charge. Photo btvt.narod.ru

According to available data, Lead-1 has a mass of 4.6 kg and is capable of accelerating to a speed of 1750 m/s. Due to this, it penetrates up to 650 mm of homogeneous armor at a shot distance of 2000 m and a zero encounter angle. It is known about the existence of the project "Lead-2", which provided for the replacement of the core with a product made of another material. Thus, similar shells from uranium and tungsten could appear in the arsenals.

Due to its long length, the new type of projectile could not be used with the existing automatic loaders of mass-produced tanks. This problem was solved in the middle of the 2000s. The T-90A armored vehicles of the new series were equipped with modified machine guns compatible with "long" shells. In the future, the upgraded T-72B3 began to receive similar equipment. Thus, a significant part of the equipment of the armored forces can use not only the relatively old "Mango" with limited characteristics.

"Vacuum" for "Armata"

Observed increase in tank protection characteristics potential adversary is a real challenge for weapons developers. Further research work led to the conclusion about the need for a new increase in the length of the ammunition. An BOPS 1000 mm long could show the optimal ratio of characteristics, but such a projectile, for obvious reasons, could not be used with the 2A46 gun and its automatic loader.

Projectile 3BM-46 with a leading device. Photo Fofanov.armor.kiev.ua

The way out of this situation was the creation of a completely new weapon with additional equipment. The promising gun later became known under the index 2A82, and the new projectile received the code "Vacuum". From a certain time new complex weapons began to be considered in the context of the project of the promising Armata tank. In case of successful completion of work on the gun and BOPS, new tank could get them as the main weapon.

According to some sources, the Vacuum project was turned off in favor of new developments. In connection with the start of the development of the 2A82-1M gun, instead of such a projectile, it was proposed to create a smaller BOPS with the code "Vacuum-1". It was supposed to have a length of "only" 900 mm and be equipped with a carbide core. In the recent past, representatives of the defense industry mentioned that organizations from Rosatom were involved in the development of a new projectile. Their participation is due to the need to use depleted uranium.

According to some reports, a projectile called "Vacuum-2" is being created in parallel. In its design, it should be similar to a product with a unit, but at the same time differ in material. It is proposed to make it from a tungsten alloy, more familiar to domestic BOPS. Also, for use with the 2A82-M gun, a high-explosive fragmentation munition with a controlled detonation with the Telnik code and a 3UBK21 Sprinter guided missile are being created. Accurate information about the creation of a new 125-mm cumulative projectile is not yet available.

Main tank T-14 with 2A82-1M gun. Photo by NPK "Uralvagonzavod" / uvz.ru

The appearance and exact technical characteristics of the promising BOPS of the Vacuum family have not yet been specified. It is only known that a projectile with a uranium core will penetrate about 900-1000 mm of homogeneous armor. Probably, such characteristics can be obtained with an ideal angle of impact. Other details are missing.

Promising "Slate"

According to various reports of past years, promising domestically developed tanks were also supposed to receive an armor-piercing projectile called the Lead. However, there was not too much information about him, which led to confusion and misconceptions. So, for some time it was believed that the "Slate" was intended for new 125-mm guns. It is now known that this product is planned to be used with a more powerful 152 mm 2A83 gun.

Apparently, the projectile for high-powered cannons will be similar in appearance to other representatives of its class. It will receive a high elongation core equipped with a ballistic cap and an armor-piercing damper in the head part, as well as a relatively small-caliber stabilizer. Earlier it was reported that the "Grifel-1" and "Grifel-2" projectiles will be equipped with tungsten and uranium cores. At the same time, there are no data on the parameters of the armor penetration of new shells.

Models of 125-mm guns 2A82-1M. Photo Yuripasholok.livejournal.com

According to various estimates, based on the caliber and estimated energy indicators, the Leads will be able to penetrate at least 1000-1200 mm of homogeneous armor at the optimal angle of impact. However, there are reports of some characteristic problems in the development of such ammunition. Due to certain objective limitations, the efficiency of using shot energy for 152-mm guns may be lower than for systems of a smaller caliber. Whether it will be possible to cope with such problems and fully use the energy reserve of the propellant charge is unknown.

The promising 2A83 tank gun is currently being developed in the context of further development unified tracked platform "Armata". The already created main tank T-14 is equipped with an uninhabited turret with a 2A82-1M gun. In the foreseeable future, it is expected that new version tank, featuring a different fighting compartment and a more powerful 2A83 gun. Along with them, the improved Armata will also receive the BOPS of the Grifel line.

Shells of the present and future

Currently, the armored forces are armed with several armor-piercing feathered sub-caliber projectiles designed for use with guns of the rather old but successful 2A46 line. A significant part of the main tanks of existing models has a relatively old automatic loader, and therefore can only use Mango shells and older products. At the same time, late-series T-90A tanks, as well as modernized T-72B3 tanks, are equipped with improved automatic loaders, thanks to which they can use relatively long shells of the Lead line.

The alleged appearance of the BOPS type "Slate". Picture Otvaga2004.mybb.ru

BOPS 3BM-42 and 3BM-46 have fairly high performance, and due to this they are able to deal with a wide range of targets present on the battlefield. At the same time, sub-caliber ammunition is not the only means of combating enemy tanks. For the same purposes, our tanks can use guided missiles and cumulative shots. Thus, "Mango", "Lead" and others tank ammunition provide combat with various targets in a wide range of ranges.

The next generation of Russian tanks, so far represented only by the T-14 Armata, is equipped with a new 2A82-1M gun, which shows higher performance and is compatible with new ammunition. The new family of shells and missiles will provide a noticeable increase in combat qualities and is quite capable of bringing the Armata to a leading position in the world.

It is no secret that in the recent past there has been a significant lag of domestic BOPS from modern foreign models. However, the situation is gradually changing, and new models of this kind are coming into service. In the foreseeable future, armored units will receive fundamentally new combat vehicles with modern weapons and ammunition. There is every reason to believe that the gap will at least narrow. Moreover, one cannot rule out the possibility of being ahead of foreign competitors with understandable consequences for the combat capability of the army.

According to the websites:
http://vpk.mane/
http://ria.ru/
http://tass.ru/
http://otvaga2004.ru/
http://btvt.narod.ru/
http://russianarms.ru/
http://fofanov.armor.kiev.ua/
http://gurkhan.blogspot.com/
http://bmpd.livejournal.com/

120 mm shots of the Israeli company IMI. In the foreground is an M829 shot (USA), manufactured by IMI under license.

Terminology

Armor-piercing feathered sub-caliber projectiles can be abbreviated as BOPS, OBPS, OPS, BPS. Currently, the abbreviation BPS is also applied to feathered sabot arrow-shaped projectiles, although it should be correctly used to designate sabot armor-piercing projectiles of the usual elongation for rifled artillery projectiles. The name of the armor-piercing feathered arrow-shaped ammunition applicable to rifled and smoothbore artillery systems.

Device

Ammunition of this type consists of an arrow-shaped feathered projectile, the body (body) of which (or the core inside the body) is made of a durable and high-density material, and the feathering is made of traditional structural alloys. The materials most used for the body include heavy alloys (of the VNZh type, etc.), uranium alloys (for example, the American Stabilloy alloy or the domestic analogue of the UNTs alloy type). The plumage is made of aluminum alloys or steel.

With the help of annular grooves (forgings), the BOPS body is connected to a sector pallet made of steel or high-strength aluminum alloys (type V-95, V-96Ts1 and similar). A sector pallet is also called a master device (VU) and consists of three or more sectors. The pallets are fastened to each other by leading bands made of metal or plastic and in this form are finally fixed in a metal sleeve or in the body of a burning sleeve. After leaving the gun barrel, the sector pallet is separated from the body of the BOPS under the action of the oncoming air flow, breaking the leading belts, while the body of the projectile itself continues to fly towards the target. Dropped sectors, having high aerodynamic drag, slow down in the air and fall at some distance (from hundreds of meters to more than a kilometer) from the muzzle of the gun. In the event of a miss, the BOPS itself, which has low aerodynamic drag, can fly away to a distance of 30 to more than 50 km from the muzzle of the gun.

The designs of modern BOPS are extremely diverse: the bodies of shells can be either monolithic or composite (a core or several cores in a shell, as well as longitudinally and transversely multilayered), plumage can be almost equal to the caliber of an artillery gun or sub-caliber, made of steel or light alloys. Master devices (VU) may have a different principle of distribution of the gas pressure action vector into sectors (VU of the “expanding” or “clamping” type), different amount sectors, made of steel, light alloys, as well as composite materials - for example, carbon composites or aramid composites. Ballistic tips and dampers can be installed in the head parts of the BOPS bodies. Additives can be added to the material of tungsten alloy cores to increase the pyrophoricity of the cores. Tracers can be installed in the tail parts of the BOPS.

The mass of BOPS bodies with plumage ranges from 3.6 kg in old models to 5-6 kg or more in models for advanced tank guns of 140-155 mm caliber.

The diameter of BOPS bodies without plumage ranges from 40 mm in older models to 22 mm or less in new promising BOPS with a large elongation. The elongation of BOPS is constantly increasing and ranges from 10 to 30 or more.

Heavy alloy cores with elongations exceeding 30 are prone to bending deformations when driven through the bore and after separation of the pallet, as well as to destruction when interacting with multi-barrier and spaced armor. The density of the material is currently limited, since at present there are no materials denser than tungsten and uranium in technology that are practically used for military purposes. The speed of the BOPS is also limited to values in the range of 1500-1800 m / s and depends on the design of artillery pieces and ammunition for them. A further increase in speed is associated with research work, carried out in the field of throwing shells with the help of artillery guns on liquid propellants (LMP), with an electrothermochemical method of throwing, with an electrothermal method of throwing, an electric (magnetic) method of throwing using railguns, Gauss systems, their combinations, as well as combinations of electrothermochemical and electromagnetic methods of throwing. At the same time, an increase in velocity above 2000 m/s for many variants of projectile materials leads to a decrease in armor penetration. The reason is the destruction of the projectile upon contact with most variants of armored barriers, which ultimately exceeds the increase in armor penetration due to the increase in speed. As such, projectile velocity generally increases armor penetration as it increases, while the durability of armor materials decreases at the same time. The effect in some cases can be summed up, in some - not, if we are talking about complex armored barriers. For monoblocks, these are often just different names for the same process.

In the USSR and Russia, several types of BOPS are widely known, created in different times and having proper names, which originated from the name / cipher R & D . The BOPS are listed below in chronological order from oldest to newest. The device and material of the BOPS body are briefly indicated:

"Hairpin" 3BM22 - a small core of tungsten carbide in the head of the steel body (1976);
"Nadfil-2" 3BM30 - uranium alloy (1982);
"Hope" 3BM27 - a small core made of tungsten alloy in the tail section of a steel body (1983);
"Vant" 3BM32 - a monolithic body made of a uranium alloy (1985);
"Mango" 3BM42 - two elongated tungsten alloy cores in a steel body jacket (1986);
"Lead" 3BM48 - a monolithic body made of a uranium alloy (1991);
Anker 3BM39 (1990s);
"Lekalo" 3BM44 M? - improved alloy (details unknown) (1997); perhaps this BOPS is called the "Projectile of increased power";
"Lead-2" - judging by the index, a modified projectile with a uranium core (details unknown).

Other BOPS also have proper names. For example, a 100 mm anti-tank smoothbore gun has the Valshchik ammunition, a 115 mm tank gun has the Kamerger ammunition, etc.

Armor penetration indicators

Comparative evaluation of armor penetration indicators is associated with significant difficulties. The assessment of armor penetration indicators is influenced by quite different test methods for BOPS in different countries, the lack of a standard type of armor for testing in different countries, different conditions placement of armor (compact or spaced apart), as well as constant manipulations by developers of all countries with firing ranges of test armor, armor installation angles before testing, various statistical methods for processing test results. As a material for testing in Russia and NATO countries, homogeneous rolled armor is adopted, to obtain more accurate results, composite targets are used.

According to published data [ ] , an increase in the elongation of the flight part to a value of 30 made it possible to increase the relative thickness of the RHA homogeneous armor pierced by rolled armor (the ratio of armor thickness to gun caliber, b / d p) to the following values: 5.0 in caliber 105 mm, and 6.8 in caliber 120 mm.

a number of other US

BOPS М829А1 for a gun of caliber 120 mm (USA) - 700 mm;
BOPS M829A2- 730 mm;
BOPS M829A3- 765 mm; often mentioned for many years "before 800"
BOPS M829A4 nothing has been announced, outwardly it is quite consistent with its predecessor.

Germany

Of the known BPS of other countries, any record-breaking ammunition for recent decades on the this moment not noticed, which has little to do with the actual state of the situation, especially in the sense of additional data (for example, the number of shells and guns and the security of the carrier).

Story

The emergence of BOPS was due to the lack of armor penetration of conventional armor-piercing and sub-caliber rounds for rifled artillery in the years after World War II. Attempts to increase the specific load (that is, to lengthen their core) in sub-caliber projectiles ran into the phenomenon of loss of stabilization by rotation with an increase in the length of the projectile over 6-8 calibers. The strength of modern materials did not allow more angular velocity projectile rotation.

In 1944, for a 210 mm caliber gun of an ultra-long-range railway installation K12(E) German designers created a caliber projectile with a drop-down plumage. The length of the projectile was 1500 mm, weight 140 kg. With an initial speed of 1850 m / s, the projectile was supposed to have a range of 250 km. For firing feathered projectiles, a smooth artillery barrel 31 m long was created. The projectile and gun did not leave the testing stage.

The most famous project that used an ultra-long-range finned sub-caliber projectile was the project of the chief engineer of the Rechling company Conders. The Conders gun had several names - V-3, "HDP-High Pressure Pump", "Centipede", "Hardworking Lizhen", "Buddy". A multi-chamber gun of 150 mm caliber used an arrow-shaped feathered sub-caliber projectile weighing in different versions from 80 kg to 127 kg, with an explosive charge from 5 kg to 25 kg. The caliber of the projectile body ranged from 90 mm to 110 mm. Different versions of the shells contained from 4 folding to 6 permanent stabilizer feathers. The elongation of some models of projectiles reached 36. A shortened modification of the LRK 15F58 gun fired a 15-cm-Sprgr swept projectile. 4481, designed at Peenemünde, and saw action firing at Luxembourg, Antwerp and the US 3rd Army. At the end of the war, one gun was captured by the Americans and taken to the United States.

Feathered shells of anti-tank guns

In 1944, the Rheinmetall company created a smooth-bore anti-tank artillery gun. 8Н63 caliber 80 mm, firing feathered HEAT projectile weighing 3.75 kg with an explosive charge of 2.7 kg. The developed guns and shells were used in combat until the end of World War II.

In the same year, the Krupp company created a smooth-bore anti-tank gun. P.W.K. 10.H.64 caliber 105 mm. The gun fired a feathered cumulative projectile weighing 6.5 kg. The projectile and gun did not leave the testing stage.

Experiments were carried out on the use of high-speed arrow-shaped projectiles of the Tsp-Geschoss type (from German Treibspiegelgeschoss - a sub-caliber projectile with a pallet) for anti-tank combat (see below "arrow-shaped anti-aircraft guns"). According to unconfirmed reports, German developers at the end of the war experimented with the use of natural uranium in pierced feathered projectiles, which ended to no avail due to the insufficient strength of unalloyed uranium. However, even then the pyrophoric nature of uranium cores was noted.

Arrow-shaped shells of anti-aircraft guns

Experiments with arrow-shaped feathered sub-caliber projectiles for high-altitude anti-aircraft artillery were carried out at a training ground near the Polish city of Blizna under the guidance of designer R. Herman ( R. Hermann). have been tested anti-aircraft guns caliber 103 mm with a barrel length of up to 50 calibers. During the tests, it turned out that arrow-shaped feathered projectiles, which reached very high speeds due to their small mass, have insufficient fragmentation action due to the impossibility of placing a significant explosive charge in them. [ ] In addition, they demonstrated extremely low accuracy due to rarefied air at high altitudes and, as a result, insufficient aerodynamic stabilization. After it became clear that swept finned shells were not applicable for anti-aircraft fire, attempts were made to use high-velocity finned piercing shells to fight tanks. The work was stopped due to the fact that serial anti-tank and tank guns at that time had sufficient armor penetration, and the Third Reich was living out its last days.

Arrow-shaped bullets of handguns

Arrow-shaped bullets for handguns were first developed by AAI designer Irwin Bahr.

Firms "AAI", "Springfield", "Winchester" designed various arrow-shaped bullets with an arrow mass of 0.68-0.77 grams, with an arrow body diameter of 1.8-2.5 mm with stamped plumage. The initial speed of arrow-shaped bullets varied depending on their type from 900 m/s to 1500 m/s.

The recoil momentum of the rifles when firing arrow-shaped ammunition was several times lower than that of the M16 rifle. During the period from 1989 to 1989, many modifications of arrow-shaped ammunition and special weapons for it were tested in the United States, but the expected advantages over conventional jacketed bullets (both medium and small caliber) were not achieved. Arrow-shaped bullets of small mass and caliber with a high flatness of the trajectory, had insufficient accuracy and insufficient lethal effect at medium and long distances.grain) (19.958 g) in a detachable pallet. With an initial speed of a swept bullet of 1450 m / s, the muzzle energy of a sniper rifle is 20,980 J. At a distance of 800 meters, a tungsten alloy sub-caliber feathered arrow pierces an armor plate 40 mm thick when it hits at an angle of 30 °, when firing at a distance of 1 km, the maximum excess of the trajectory over the aiming line is only 80 cm.

Hunting arrow-shaped bullets

Most types of elongated bullets for hunting smoothbore weapons have an aerodynamic principle of flight stabilization and belong to lancet (arrow-shaped) projectiles. Due to the slight elongation of conventional hunting bullets in most models (1.3-2.5 and even less (for example, the Mayer bullet, which is also stabilized not by the turbine, but by the lancet method)), the lancet (sweep) of hunting bullets is not visually obvious.

The most pronounced arrow-shaped form currently have Russian Zenith bullets (designed by D. I. Shiryaev) and foreign Sovestra bullets. For example, some types of Sovestra bullets have an elongation of up to 4.6-5, and some types of Shiryaev bullets have an elongation of more than 10. Both arrow-shaped feathered bullets with a large elongation differ from other hunting lancet bullets in high rates of fire accuracy.

Arrow-shaped feathered bullets of underwater weapons

Russia is developing arrow-shaped (needle-shaped) underwater ammunition without plumage, which is part of the SPS cartridges of 4.5 mm caliber (for the special underwater pistol SPP-1; SPP-1M) and MPS cartridges of 5.66 mm caliber (for the special APS underwater assault rifle ). Non-feathered arrow-shaped bullets for underwater weapons, stabilized in water by a cavitation cavity, practically do not stabilize in the air and require not regular, but special weapons for use under water.

Currently, the most promising underwater-air ammunition, which can be fired with equal efficiency both under water at a depth of up to 50 m, and in air, are cartridges for regular (serial) machine guns and assault rifles, equipped with Polotnev's arrow-shaped feathered bullet, developed at the Federal State Unitary Enterprise "TsNIIKhM". Stabilization of Polotnev's bullets under water is carried out by the cavitation cavity, and in air - by the plumage of the bullet.

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