Psychology of feelings 

Sub-caliber armor-piercing coil-shaped projectile. Bops (armor-piercing feathered sub-caliber projectiles). Chamber and solid armor-piercing shells

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 a detachable pallet is the main anti-tank projectile in the ammunition of modern tanks. Armor-piercing sub-caliber shells with an integral pallet also continue to be used, but in more as ammunition for automatic small-caliber guns, where the implementation of a pallet separating 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 hard) - BPS with an integral pallet and more solid 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). Due to the 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 rounds for the GSP U-5TS did not allow to fully realize the potential in terms of rate of fire and reduction of the internal armored volume of a promising tank, in addition, due to the increased gas contamination of the T-62 fighting compartment, the designers were forced to resort to a mechanism for removing spent cartridges, which somewhat reduced tank speed. 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 positive feedback for their high technical and performance characteristics underwent numerous upgrades aimed at further growth of its characteristics. Upgraded versions of the D-81T (2A26) gun such as 2A46M, 2A46M-1, 2A46M-2, 2A46M-4 are the main armament domestic tanks to this day.

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

The period of the late 60s and late seventies was characterized by the evolutionary development of 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.

The appearance of tanks on the battlefield was one of the most important events military history the last century. Immediately after this moment, the development of means to combat these formidable machines began. If we take a closer look at the history of armored vehicles, then, in fact, we will see the history of the confrontation between the projectile and armor, which has been going on for almost a century.

In this irreconcilable struggle, one or the other side periodically gained the upper hand, which led either to the complete invulnerability of the tanks, or to their huge losses. In the latter case, every time there were voices about the death of the tank and the "end of the tank era." However, even today, tanks remain the main striking force of the ground forces of all the armies of the world.

Today, one of the main types of armor-piercing ammunition that are used to combat armored vehicles are sub-caliber ammunition.

A bit of history

The first anti-tank shells were ordinary metal blanks, which, due to their kinetic energy, pierced tank armor. Fortunately, the latter was not very thick, and even anti-tank guns could handle it. However, already before the start of World War II, tanks of the next generation began to appear (KV, T-34, Matilda), with a powerful engine and serious armor.

Major world powers entered the Second world war, having anti-tank artillery caliber 37 and 47 mm, and finished it with guns that reached 88 and even 122 mm.

By increasing the caliber of the gun and the muzzle velocity of the projectile, the designers had to increase the mass of the gun, making it more complex, expensive, and much less maneuverable. It was necessary to look for other ways.

And they were soon found: cumulative and sub-caliber ammunition appeared. The action of cumulative ammunition is based on the use of a directed explosion that burns through tank armor, a sub-caliber projectile also does not have a high-explosive action, it hits a well-protected target due to high kinetic energy.

The design of the sub-caliber projectile was patented back in 1913 by the German manufacturer Krupp, but their mass use began much later. This ammunition does not have a high-explosive effect, it is much more like an ordinary bullet.

For the first time, the Germans began to actively use sub-caliber shells during the French campaign. They had to use such ammunition even more widely after the start of hostilities on Eastern Front. Only using sub-caliber shells, the Nazis could effectively resist the powerful Soviet tanks.

However, the Germans experienced a serious shortage of tungsten, which prevented them from mass-producing such shells. Therefore, the number of such shots in the ammunition load was small, and the military personnel were given strict orders: to use them only against enemy tanks.

In the USSR, serial production of sub-caliber ammunition began in 1943, they were created on the basis of captured German samples.

After the war, work in this direction continued in most of the world's leading weapons powers. Today, sub-caliber ammunition is considered one of the main means of destroying armored targets.

Currently, there are even sub-caliber bullets that significantly increase the firing range of smoothbore weapons.

Operating principle

What is the basis for the high armor-piercing effect that a sub-caliber projectile has? How is it different from the usual?

A sub-caliber projectile is a type of ammunition with a caliber of the warhead that is many times smaller than the caliber of the barrel from which it was fired.

It was found that a small-caliber projectile flying at high speed has greater armor penetration than a large-caliber one. But in order to get high speed after a shot, a more powerful cartridge is needed, which means a gun of a more serious caliber.

It was possible to resolve this contradiction by creating a projectile, in which the striking part (core) has a small diameter compared to the main part of the projectile. The sub-caliber projectile does not have a high-explosive or fragmentation effect, it works on the same principle as a conventional bullet, which hits targets due to high kinetic energy.

The sub-caliber projectile consists of a solid core made of a particularly strong and heavy material, a body (pallet) and a ballistic fairing.

The diameter of the pallet is equal to the caliber of the weapon, it acts as a piston when fired, accelerating the warhead. On pallets sub-caliber shells for rifled guns, leading belts are installed. Typically, the pallet is in the form of a coil and is made of light alloys.

There are armor-piercing sub-caliber shells with a non-separable pallet, from the moment of the shot until the target is hit, the coil and core act as a single whole. This design creates serious aerodynamic drag, significantly reducing flight speed.

Projectiles are considered more advanced, in which, after a shot, the coil is separated due to air resistance. In modern sub-caliber projectiles, the stability of the core in flight is provided by stabilizers. Often a tracer charge is installed in the tail section.

The ballistic tip is made of soft metal or plastic.

The most important element of a sub-caliber projectile is undoubtedly the core. Its diameter is about three times smaller than the caliber of the projectile, and high-density metal alloys are used to make the core: the most common materials are tungsten carbide and depleted uranium.

Due to the relatively small mass, the core of the sub-caliber projectile immediately after the shot accelerates to a significant speed (1600 m / s). Upon impact with the armor plate, the core pierces a relatively small hole in it. The kinetic energy of the projectile is partly used to destroy armor, and partly converted into heat. After breaking through the armor, red-hot fragments of the core and armor go into the armored space and spread like a fan, hitting the crew and internal mechanisms of the vehicle. This creates multiple fires.

As the armor passes, the core grinds and becomes shorter. Therefore very important characteristic, which affects armor penetration, is the length of the core. Also, the effectiveness of the sub-caliber projectile is affected by the material from which the core is made and the speed of its flight.

The latest generation of Russian sub-caliber projectiles ("Lead-2") is significantly inferior in armor penetration American counterparts. This is due to the greater length of the striking core, which is part of the American ammunition. An obstacle to increasing the length of the projectile (and, hence, armor penetration) is the device of automatic loaders for Russian tanks.

The armor penetration of the core increases with a decrease in its diameter and with an increase in its mass. This contradiction can be solved by using very dense materials. Initially, tungsten was used for the striking elements of such ammunition, but it is very rare, expensive, and also difficult to process.

Depleted uranium has almost the same density as tungsten, and is a virtually free resource for any country that has a nuclear industry.

At present, sub-caliber munitions with a uranium core are in service with the major powers. In the United States, all such ammunition is equipped only with uranium cores.

Depleted uranium has several advantages:

  • when passing through the armor, the uranium rod is self-sharpening, which provides better armor penetration, tungsten also has this feature, but it is less pronounced;
  • after breaking through the armor, under the action high temperatures the remnants of the uranium rod flare up, filling the armored space with poisonous gases.

To date, modern sub-caliber shells have almost reached their maximum efficiency. It can be increased only by increasing the caliber of tank guns, but this will require significant changes in the design of the tank. In the meantime, in the leading tank-building states, they are only engaged in modifying vehicles produced during the Cold War, and are unlikely to take such radical steps.

In the United States, active-rocket projectiles with a kinetic warhead are being developed. This conventional projectile, which immediately after the shot turns on its own upper stage, which significantly increases its speed and armor penetration.

Also, the Americans are developing a kinetic guided missile, the striking factor of which is a uranium rod. After firing from the launch canister, the upper stage turns on, which gives the ammunition a speed of Mach 6.5. Most likely, by 2020 there will be sub-caliber ammunition with a speed of 2000 m/s and higher. This will take their efficiency to a whole new level.

Sub-caliber bullets

In addition to sub-caliber shells, there are bullets that have the same design. Very widely such bullets are used for 12 gauge cartridges.

Sub-caliber bullets of 12 caliber have a smaller mass, after being fired they receive more kinetic energy and, accordingly, have a greater flight range.

Very popular sub-caliber bullets 12 caliber are: bullet Poleva and "Kirovchanka". There are other similar 12-gauge ammunition.

Video about sub-caliber ammunition

If you have any questions - leave them in the comments below the article. We or our visitors will be happy to answer them.

Secrets of Russian artillery. The last argument of the tsars and commissars [with illustrations] Shirokorad Alexander Borisovich

Focus 3rd - sub-caliber shells

Work on the creation of sub-caliber shells began with us at the end of 1918, and it is more convenient to talk about them in chronological order. The first domestic sub-caliber shells were made in Petrograd at the beginning of 1919. By the way, in the documents of the Artillery Directorate of the Red Army in 1918-1938. they were called combined. I use more modern name for the convenience of readers. The "combined" projectile consisted of a pallet and an "active" projectile. The weight of the entire structure was 236 kg, and the active projectile of 203 mm caliber was 110 kg.

Combined shells were intended for 356 / 52-mm guns, which were to be armed with battlecruisers of the Izmail type. Initially, the Naval Department planned to order 76 356 / 52-mm guns, of which 48 were going to be put on cruisers, 24 - spares for cruisers and 4 - on the sea range. 36 guns were ordered from the Vickers plant in England and 40 from the Obukhov steel plant.

The 356/52 mm MA guns should not be confused with the 356/52 mm guns of the Land Office (SA). In 1912–1914 GAU ordered OSZ 17 356 / 52-mm SA guns, which differed from the marine ones in their large weight and large chamber volume.

Until October 1917, at least ten 356/52-mm guns were delivered from England, and the OSZ did not hand over a single one. Field trials of 356/52-mm guns were started in 1917 on a special Durlyakher proving machine. In 1922, the OSZ stored 8 finished Vickers guns and 7 unfinished OSZ guns, of which 4 were 60% complete.

As a result, by 1918 only one 356/52-mm cannon, mounted on the Durlyakher machine on Rzhevka, could fire. The barrels were constantly changed on this installation, and it was always ready to fire. In 1941–1944 A 356-mm range mount from a standard 356/52-mm barrel fired at the German troops besieging Leningrad. The Durlyakher installation is located on Rzhevka even now (but at least it was there in 2000).

Battlecruisers of the Izmail type were not completed. Several projects for the construction of naval monitors armed with 356-mm guns were developed, but they were not implemented either. In the mid-1930s, TM-1-14 railway transporters (the first sea transporter with a 14-inch gun) were armed with 356/52-mm guns. In total, two railway batteries were formed, each of which had three TM-1-14 conveyors. One of these batteries was based near Leningrad, and the other two - near Vladivostok.

But back to the combined shells. During their firing at Rzhevka in 1919, an initial velocity of 1291 m / s was obtained at a pressure in the bore of 2450 kg / cm2 (that is, a little more than with a standard projectile - 2120 kg / cm2).

On October 15, 1920, the Perm plant received an order (in excess of the program) for 70 combined 356/203-mm shells for the Marine range. The first 15 shells were handed over to the customer in June 1921.

For several years, the projectile was designed by trial and error, and finally in June 1924, when firing a 203-mm active projectile weighing 110 kg at a speed of 1250 m / s, a maximum range of 48.5 km was obtained. However, during these firings, a large dispersion in accuracy and range was noted.

The test managers explained the dispersion by the fact that the steepness of the rifling of the standard 356/52-mm gun of 30 calibers does not ensure the correct flight of the projectiles.

In this regard, it was decided to ream the barrel of the 356/52 mm gun to 368 mm with a steeper cut. After calculating several options, the rifling steepness of 20 calibers was finally adopted.

The bore of the barrel of the 368-mm gun No. 1 was made in 1934 at the Bolshevik plant. At the beginning of December 1934, tests of gun No. 1 began, which were unsuccessful due to the quality of the shells.

At the beginning of 1935, the Bolshevik plant manufactured new 220/368-mm sub-caliber projectiles of drawings 3217 and 3218 with girdle pallets, which were fired in June - August 1935. The weight of the structure was 262 kg, and the weight of the 220-mm active projectile - 142 kg, gunpowder charge - 255 kg. On tests, a speed of 1254–1265 m/s was obtained. When shooting on August 2, 1935 received medium range 88,720 m at an elevation angle of about 50°. Lateral deviation during firing was 100–150 m.

To further increase the firing range, work was begun to reduce the weight of the pallet.

At the end of 1935, shells with girdle pallets of drawing 6125 were fired. The weight of the active projectile was 142 kg, and the weight of the pallet was 120 kg, the firing range was 97,270 m at an angle of +42 °. Average dispersion for four shots: lateral - 55 m, longitudinal - 935 m. Expected range at an angle of + 50 ° - 110 km. The pallets fell at a distance of 3–5 km. In total, 47 shots were fired with projectiles of drawing 6125.

By that time, the conversion of the second 356mm gun into a 368mm one had been completed. When testing the 368-mm gun No. 2 in 1936 - early 1937 with a projectile of drawing 6314, satisfactory results were obtained, and on their basis, in March 1937, tables of firing from a 368-mm gun with projectiles of drawing 6314 were compiled. The design of the projectile of drawing 6314 weighed 254 kg, of which 112.1 kg accounted for the girdle pallet, 140 kg for the active projectile. The length of the 220 mm active projectile is 5 calibers. The explosive used was 7 kg of TNT, RGM fuse. When firing with a full charge of 223 kg, the initial speed was 1390 m / s, and the range was 120.5 kg. Thus, the same range was obtained as that of the "Paris Cannon", but with a heavier projectile. The main thing was that an ordinary naval gun was used, and the survivability of the barrel was much greater than that of the Germans. 368-mm trunks were supposed to be installed on railway transporters TM-1-14.

However, at this stage, work with girdle pallets was suspended, since star pallets were preferred. But before moving on to shells with star-shaped pallets, I will finish the story about ultra-long guns with conventional belt shells.

In 1930–1931 in the design bureau of the Bolshevik plant, a 152-mm ultra-long AB gun was designed, and in 1932 an agreement was signed with the plant for the manufacture of an experimental 152-mm AB gun, more precisely, for reworking the barrel of a 305/52-mm standard gun. A new inner tube of 152 mm caliber was inserted into the old barrel and a new muzzle was made. The outer dimensions of the clip were made according to the outlines of the 356/52 mm gun, since all tests were supposed to be carried out on a 356 mm machine of the Durlacher system. The length of the AB gun was 18.44 m (121.5 calibers). The steepness of the grooves is 25 calibers, the number of grooves is 12, the depth of the groove is 3.0 mm. Alteration of the barrel was delayed due to technological difficulties. Therefore, the AB cannon arrived from the Bolshevik at the NIAP only in September 1935. According to calculations, when firing a light caliber projectile of drawing 5465 weighing 41.7 kg, the initial speed should have been 1650 m / s, and the range - 120 km.

The first firing from the 152-mm AB cannon with a projectile of drawing 5465 was carried out on June 9, 1936. A charge of B8 gunpowder weighing 75 kg was used. However, the initial speed was only 1409 m/s, and the estimated range was not obtained.

After testing, the shells were finalized. But the machine tool at NIAP turned out to be occupied at least until October 1940 (as already mentioned, all experiments with heavy guns were carried out from a single Durlyakher machine tool). In addition, in 1940, the standard 356/52-mm cannon was intensively firing new shells for the TM-1-14 railway installations. As a result, repeated tests of the AB gun were repeatedly postponed. The author does not have information about testing it in 1941.

It is interesting that along with the testing of ultra-long-range sub-caliber shells for 356-368-mm guns, tests of sub-caliber shells for 152-mm land guns of 200 pounds (sample 1904) were carried out. Such shells were supposed to be adopted for 6-inch guns of 200 pounds and 6-inch image guns. 1910 About two dozen 152 mm sub-caliber projectiles were designed. The weight of the entire structure was 17–20 kg, while the weight of the 95 mm caliber active projectile was 10–13 kg, the rest was on a pallet. The estimated firing range was 22–24 km.

When firing at the NIAP from 6-inch cannons at 200 pounds on October 21, 1927, 152 / 95-mm sub-caliber shells with a total weight of 18.7 kg and charges weighing 8.2 kg of C42 gunpowder at an elevation angle of 37, an initial velocity of 972 m / from. An active projectile weighing 10.4 kg fell at a distance of 18.7 km (Fig. 5.3).

Rice. 5.3. Sub-caliber 152/95-mm shells.

In 1935, at the ARI of the Red Army, under the leadership of P.V. Makhnevich, turbo pallets for 152/95-mm combined (sub-caliber) shells were developed. Shooting shells with a turbo pallet could be carried out both from conventional rifled and from smoothbore guns. The turbo pan did not have copper or other belts, and its rotation was "provided by the action of jets moving along grooves milled on the outer surface of the pan."

The total weight of the combined projectile drawing 6433 was 20.9 kg, while the weight of the active projectile was 10.14 kg, and the turbo pallet was 10.75 kg.

The first firing tests of the turbo pan were carried out on April 3, 1936 from a 152-mm (6-inch) gun mod. 1904. The weight of the charge was 7.5–8.4 kg, the initial velocity of the projectile was 702–754 m/s. The pallet gave the shells a satisfactory rotational speed. The separation of the projectile elements took place at a distance of 70 m from the muzzle, and the average drop distance of the pallet was about 500 m.

Nevertheless, by the middle of 1936, the ARI recognized work on combined shells with turbo pallets as unpromising and decided to stop them.

By that time, work on the so-called “star-shaped” pallet for combined shells, which had begun already in 1931, was in full swing at the ARI.

Guns with star-shaped pallets had a small number of rifling (usually 3-4) of great depth. The cross sections of the pallets of the shells repeated the cross section of the channel. These guns can formally be attributed to guns with rifled shells.

To begin with, the ARI decided to test toothed pallets on a small caliber gun. In the trunk of a standard 76 mm anti-aircraft gun arr. In 1931, a liner of caliber 67/40 mm was inserted (along the rifling / along the fields). The liner had 3 grooves with a depth of 13.5 mm. The weight of the active projectile is 1.06 kg, the weight of the pallet is 0.6 kg.

Work on the manufacture of the liner began in 1936 at plant No. 8 (in Podlipki). When testing guns with a 67/40 mm liner, an initial speed of 1200 m/s was achieved at a pressure of 2800 kg/cm2, the range was not determined during the tests. The shells tumbled in flight ("had the wrong flight"). According to the commission, the 40-mm active projectiles did not receive the required rotation speed due to the rotation of the pallets relative to the projectiles.

Similar experiments were carried out by the ARI with a regular 152-mm Br-2 cannon, into which a free tube of 162/100 mm caliber was inserted (along the rifling / along the fields). The pipe was cut according to the CEA system at the Barrikady plant. During tests with a projectile with a total weight of 22.21 kg and an active projectile weight of 16.84 kg, an initial speed of 1100 m / s was achieved at a pressure of 2800 kg / cm2, the firing range was not determined, since the projectiles tumbled here too.

According to the decision of the Council of Labor and Defense of October 10, 1935 No. S-142ss, the Barrikady plant was given the task of developing working drawings and converting the 368-mm gun No. 1 into a 305/180-mm gun for firing sub-caliber projectiles with star-shaped pallets. The deadline was set - May 1937.

The final version of the project was made by the ARI under the direction of M. Ya. Krupchatikov with the assistance of E. A. Berkalov. The caliber of the CEA channel has been changed from 305/180mm to 380/250mm, and the number of grooves has been changed from three to four. The drawings were signed at the ARI on June 4, 1936, and received by the Barrikady plant only in August 1936. In the late autumn of 1936, the forging of the inner tube was annealed. The barrel of the 368-mm gun No. 1 was submitted from the NIAP to the factory. However, the work was delayed, and a new deadline for the completion of the shaft was set - February 1, 1938 (Fig. 5.4).

Rice. 5.4. Rifled 380/250 mm projectile.

The calculations were carried out for a chamber volume of 360 dm3 and a charge of NGV gunpowder weighing 237 kg. The length of the channel is the same as the standard 356/52 mm gun. The barrel is fastened in the breech in 5 layers. The shutter is standard from a 356 / 52-mm gun. The increase in the number of rifling to four was done to harden the barrel and better center the active projectile.

According to the calculation, the TM-1-14 installation had to withstand the firing of a 380/250-mm gun.

On January 17, 1938, the Artillery Directorate notified Barricades of the suspension of work on the 380/250 mm barrel.

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II. Missiles and rockets of the USA as of 1956 General information. Missiles "Kapral", "Dart", "Nike" and "Redstone" are in service with the army; missile "Lacrosse" - in service with the army and corps marines; rockets "Bomark", "Folcon", "Matador", "Raskl", "Snark" and

From the author's book

Projectiles for defense A projectile, as a rule, is more commonly referred to as an attribute of an offensive weapon. However, Honored Inventor of Russia V.A. Odintsov came up with shells that can be attributed to self-defense weapons. Member of the Scientific and Expert Council of the State Duma Committee on

IN War Thunder implemented many types of shells, each of which has its own characteristics. In order to competently compare different shells, choose the main type of ammunition before the battle, and in battle for different purposes in different situations to use suitable projectiles, you need to know the basics of their device and principle of operation. This article talks about the types of projectiles and their design, as well as gives advice on their use in combat. Do not neglect this knowledge, because the effectiveness of the weapon largely depends on the shells for it.

Types of tank ammunition

Armor-piercing caliber shells

Chamber and solid armor-piercing shells

As the name suggests, the purpose armor-piercing shells- to break through the armor and thereby hit the tank. Armor-piercing shells are of two types: chamber and solid. Chamber shells have a special cavity inside - a chamber, in which an explosive is located. When such a projectile penetrates the armor, the fuse is triggered and the projectile explodes. The crew of an enemy tank is hit not only by armor fragments, but also by explosions and fragments of a chamber shell. The explosion does not occur immediately, but with a delay, thanks to which the projectile has time to fly into the tank and explode there, causing the most damage. In addition, the sensitivity of the fuse is set to, for example, 15 mm, that is, the fuse will only work if the thickness of the armor being penetrated is above 15 mm. This is necessary so that the chamber projectile explodes in the fighting compartment when it breaks through the main armor, and does not cock against the screens.

A solid projectile does not have a chamber with an explosive, it is just a metal blank. Of course, solid shells deal much less damage, but they penetrate a greater thickness of armor than similar chamber shells, since solid shells are stronger and heavier. For example, the armor-piercing chamber projectile BR-350A from the F-34 cannon pierces 80 mm at a right angle at close range, and the solid BR-350SP projectile as much as 105 mm. The use of solid projectiles is very typical for British school tank building. Things got to the point that the British removed explosives from American 75-mm chamber shells, turning them into solid ones.

The lethal force of solid shells depends on the ratio of the thickness of the armor and the armor penetration of the shell:

  • If the armor is too thin, then the projectile will pierce through it and damage only those elements that it hits along the way.
  • If the armor is too thick (on the border of penetration), then small non-lethal fragments are formed that will not cause much harm.
  • Maximum armor action - in case of penetration of sufficiently thick armor, while the penetration of the projectile should not be completely used up.

Thus, in the presence of several solid shells, the best armor action will be with the one with greater armor penetration. As for chamber shells, the damage also depends on the amount of explosive in TNT equivalent, as well as on whether the fuse worked or not.


Sharp-headed and blunt-headed armor-piercing shells

An oblique blow to the armor: a - a sharp-headed projectile; b - blunt projectile; c - arrow-shaped sub-caliber projectile

Armor-piercing shells are divided not only into chamber and solid shells, but also into sharp-headed and dumb-headed ones. Pointed shells pierce thicker armor at a right angle, since at the moment of impact with the armor, all the impact force falls on a small area of ​​the armor plate. However, the efficiency of work on sloping armor in sharp-headed projectiles is lower due to a greater tendency to ricochet at large angles of impact with the armor. Conversely, blunt-headed shells penetrate thicker armor at an angle than sharp-headed shells, but have less armor penetration at right angles. Let's take for example the armor-piercing chamber shells of the T-34-85 tank. At a distance of 10 meters, the BR-365K sharp-headed projectile penetrates 145 mm at a right angle and 52 mm at an angle of 30 °, and the BR-365A blunt-headed projectile penetrates 142 mm at a right angle, but 58 mm at an angle of 30 °.

In addition to sharp-headed and blunt-headed shells, there are sharp-headed shells with an armor-piercing tip. When meeting armor plate at a right angle, such a projectile works like a sharp-headed one and has good armor penetration compared to a similar blunt-headed projectile. When hitting sloping armor, the armor-piercing tip “bites” the projectile, preventing ricochet, and the projectile works like a dumb-ass.

However, sharp-headed shells with an armor-piercing tip, like blunt-headed shells, have a significant drawback - greater aerodynamic resistance, due to which armor penetration drops more at a distance than sharp-headed shells. To improve aerodynamics, ballistic caps are used, due to which armor penetration is increased at medium and long distances. For example, on the German 128 mm KwK 44 L/55 gun, two armor-piercing chamber shells are available, one with a ballistic cap and the other without it. Armor-piercing sharp-headed projectile with an armor-piercing tip PzGr at a right angle pierces 266 mm at 10 meters and 157 mm at 2000 meters. But an armor-piercing projectile with an armor-piercing tip and a ballistic cap PzGr 43 at a right angle pierces 269 mm at 10 meters and 208 mm at 2000 meters. In close combat, there are no special differences between them, but at long distances the difference in armor penetration is huge.

Armor-piercing chamber shells with an armor-piercing tip and a ballistic cap are the most versatile type of armor-piercing ammunition that combines the advantages of sharp-headed and blunt-headed projectiles.

Table of armor-piercing shells

Sharp-headed armor-piercing shells can be chamber or solid. The same applies to blunt-headed shells, as well as sharp-headed shells with an armor-piercing tip, and so on. Let's put it all together possible options to the table. Under the icon of each projectile, the abbreviated names of the projectile type are written in English terminology, these are the terms used in the book "WWII Ballistics: Armor and Gunnery", according to which many shells in the game are configured. If you hover over the abbreviated name with the mouse cursor, a hint with decoding and translation will appear.


dumb-headed
(with ballistic cap)
sharp-headed
sharp-headed
with armor-piercing tip
sharp-headed
with armor-piercing tip and ballistic cap

Solid projectile
APBC
AP
APC
APCBC

Chamber projectile

APHE
APHEC

Sub-caliber shells

Coil sub-caliber projectiles

The action of the sub-caliber projectile:
1 - ballistic cap
2 - body
3 - core

Armor-piercing caliber shells have been described above. They are called caliber because the diameter of their warhead is equal to the caliber of the gun. There are also armor-piercing sub-caliber shells, the warhead diameter of which is smaller than the caliber of the gun. The simplest type of sub-caliber projectiles is coil (APCR - Armor-Piercing Composite Rigid). The coil sub-caliber projectile consists of three parts: a body, a ballistic cap and a core. The body serves to disperse the projectile in the barrel. At the moment of meeting with the armor, the ballistic cap and the body are crushed, and the core pierces the armor, hitting the tank with shrapnel.

At close range, sub-caliber shells penetrate thicker armor than caliber shells. Firstly, the sabot projectile is smaller and lighter than a conventional armor-piercing projectile, thanks to which it accelerates to higher speeds. Secondly, the core of the projectile is made of hard alloys with a high specific gravity. Thirdly, due to the small size of the core at the moment of contact with the armor, the impact energy falls on a small area of ​​​​the armor.

But coil sub-caliber shells also have significant drawbacks. Due to their relatively light weight, sub-caliber shells are ineffective at long distances, they lose energy faster, hence the drop in accuracy and armor penetration. The core does not have an explosive charge, therefore, in terms of armor action, sub-caliber shells are much weaker than chamber shells. Finally, sub-caliber shells do not work well against sloped armor.

Coil sub-caliber shells were effective only in close combat and were used in cases where enemy tanks were invulnerable against caliber armor-piercing shells. 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.

Sub-caliber projectiles with a detachable pallet

APDS projectile and its core

Sectional view of an APDS projectile, showing the ballistic-tipped core

Armor-Piercing Discarding Sabot (APDS) - a further development of the design of sabot projectiles.

Coil sub-caliber projectiles had a significant drawback: the hull flew along with the core, increasing aerodynamic drag and, as a result, a drop in accuracy and armor penetration at a distance. For sub-caliber shells with a detachable pallet, a detachable pallet was used instead of the body, which first dispersed the projectile in the gun barrel, and then separated from the core by air resistance. The core flew to the target without a pallet and, due to the significantly lower aerodynamic resistance, did not lose armor penetration at a distance as quickly as coil sub-caliber shells.

During the Second World War, sub-caliber shells with a detachable pallet were distinguished by record-breaking armor penetration and flight speed. For example, the Shot SV Mk.1 sub-caliber projectile for the 17-pounder accelerated to 1203 m/s and pierced 228 mm of soft armor at a right angle at 10 meters, while the Shot Mk.8 armor-piercing caliber projectile only 171 mm under the same conditions.

Sub-caliber feathered shells

Separation of the pallet from BOPS

BOPS projectile

Armor-Piercing Fin-Stabilized Discarding Sabot (APFSDS) is the most modern type of armor-piercing projectile designed to destroy heavily armored vehicles protected by the latest types of armor and active protection.

These shells are a further development of sub-caliber shells with a detachable pallet, they also have great length and smaller cross section. Spin stabilization is not very effective for high aspect ratio projectiles, so armor piercing finned sabots (BOPS for short) are stabilized by the fins and are generally used to fire smoothbore guns (however, early BOPS and some modern ones are designed to fire rifled guns).

Modern BOPS projectiles have a diameter of 2-3 cm and a length of 50-60 cm. To maximize the specific pressure and kinetic energy of the projectile, high-density materials are used in the manufacture of ammunition - tungsten carbide or an alloy based on depleted uranium. The muzzle velocity of the BOPS is up to 1900 m / s.

Concrete-piercing projectiles

The concrete projectile is artillery shell, designed to destroy long-term fortifications and solid buildings of capital construction, as well as to destroy enemy manpower and military equipment hidden in them. Often, concrete-piercing shells were used to destroy concrete pillboxes.

In terms of design, concrete-piercing shells occupy an intermediate position between armor-piercing chamber and high-explosive fragmentation shells. Compared to high-explosive fragmentation projectiles of the same caliber, with a close destructive potential of the explosive charge, concrete-piercing ammunition has a more massive and durable body, which allows them to penetrate deep into reinforced concrete, stone and brick barriers. Compared to armor-piercing chamber shells, concrete-piercing shells have more explosives, but a less durable body, so concrete-piercing shells are inferior to them in armor penetration.

The G-530 concrete-piercing projectile weighing 40 kg is included in the ammunition load of the KV-2 tank, the main purpose of which was the destruction of pillboxes and other fortifications.

HEAT rounds

Rotating HEAT projectiles

The device of the cumulative projectile:
1 - fairing
2 - air cavity
3 - metal cladding
4 - detonator
5 - explosive
6 - piezoelectric fuse

The cumulative projectile (HEAT - High-Explosive Anti-Tank) differs significantly from kinetic ammunition, which include conventional armor-piercing and sub-caliber shells. It is a thin-walled steel projectile filled with a powerful explosive - RDX, or a mixture of TNT and RDX. In front of the projectile in explosives there is a goblet-shaped or cone-shaped recess lined with metal (usually copper) - a focusing funnel. The projectile has a sensitive head fuse.

When a projectile collides with armor, an explosive is detonated. Due to the presence of a focusing funnel in the projectile, part of the explosion energy is concentrated at one small point, forming a thin cumulative jet consisting of the metal of the lining of the same funnel and explosion products. The cumulative jet flies forward at great speed (approximately 5,000 - 10,000 m / s) and passes through the armor due to the enormous pressure it creates (like a needle through oil), under the influence of which any metal enters a state of superfluidity or, in other words, leads itself as a liquid. The armored damaging effect is provided both by the cumulative jet itself and by hot drops of pierced armor squeezed inward.


The most important advantage of a HEAT projectile is that its armor penetration does not depend on the velocity of the projectile and is the same at all distances. That is why cumulative shells were used on howitzers, since conventional armor-piercing shells for them would be ineffective due to the low speed of flight. But the cumulative shells of the Second World War also had significant drawbacks that limited their use. 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 speed, a small effective range and high dispersion, which was also facilitated by the shape of the projectile head, which was not optimal from the point of view of aerodynamics. The manufacturing technology of these shells at that time was not sufficiently developed, so their armor penetration was relatively low (approximately corresponded to the caliber of the projectile or slightly higher) and was unstable.

Non-rotating (feathered) cumulative projectiles

Non-rotating (feathered) cumulative projectiles (HEAT-FS - High-Explosive Anti-Tank Fin-Stabilised) are a further development of cumulative ammunition. Unlike early cumulative projectiles, they are stabilized in flight not by rotation, but by folding fins. The lack of rotation improves the formation of a cumulative jet and significantly increases armor penetration, while removing all restrictions on the speed of the projectile, which can exceed 1000 m/s. So, for early cumulative shells, typical armor penetration was 1-1.5 calibers, while for post-war shells it was 4 or more. However, feathered projectiles have a slightly lower armor effect compared to conventional HEAT projectiles.

Fragmentation and high-explosive shells

High-explosive shells

A high-explosive fragmentation projectile (HE - High-Explosive) is a thin-walled steel or cast iron projectile filled with an explosive (usually TNT or ammonite), with a head fuse. Upon hitting the target, the projectile immediately explodes, hitting the target with fragments and an explosive wave. Compared to concrete-piercing and armor-piercing chamber shells, high-explosive fragmentation shells have very thin walls, but they have more explosives.

The main purpose of high-explosive fragmentation shells is to defeat enemy manpower, as well as unarmored and lightly armored vehicles. High-explosive high-explosive shells of large caliber can be used very effectively to destroy lightly armored tanks and self-propelled guns, as they break through relatively thin armor and incapacitate the crew with the force of the explosion. Tanks and self-propelled guns with anti-projectile armor are resistant to high-explosive fragmentation shells. However, large-caliber projectiles can even hit them: the explosion destroys the tracks, damages the gun barrel, jams the turret, and the crew is injured and shell-shocked.

Shrapnel shells

The shrapnel projectile is a cylindrical body, divided by a partition (diaphragm) into 2 compartments. An explosive charge is placed in the bottom compartment, and spherical bullets are in the other compartment. A tube filled with a slowly burning pyrotechnic composition passes along the axis of the projectile.

The main purpose of the shrapnel projectile is to defeat the enemy's manpower. It happens in the following way. At the moment of the shot, the composition in the tube ignites. Gradually, it burns out and transfers the fire to the explosive charge. The charge ignites and explodes, squeezing out a partition with bullets. The head of the projectile comes off and the bullets fly out along the axis of the projectile, deviating slightly to the sides and hitting the enemy infantry.

In the absence of armor-piercing shells in the early stages of the war, gunners often used shrapnel shells with a tube set "on impact". In terms of its qualities, such a projectile occupied an intermediate position between high-explosive fragmentation and armor-piercing, which is reflected in the game.

Armor-piercing shells

Armor-piercing high-explosive projectile (HESH - High Explosive Squash Head) - post-war type anti-tank projectile, the principle of operation of which is based on the detonation of a plastic explosive on the surface of the armor, which causes the armor fragments on the back to break off and damage the fighting compartment of the vehicle. An armor-piercing high-explosive projectile has a body with relatively thin walls, designed for plastic deformation when it encounters an obstacle, as well as a bottom fuse. The charge of an armor-piercing high-explosive projectile consists of a plastic explosive that “spreads” over the surface of the armor when the projectile meets an obstacle.

After “spreading”, the charge is detonated by a slow-acting bottom fuse, which causes the destruction of the rear surface of the armor and the formation of spalls that can hit the internal equipment of the vehicle or crew members. In some cases, penetrating armor can also occur in the form of a puncture, a breach, or a broken plug. The penetrating ability of an armor-piercing high-explosive projectile depends less on the angle of the armor in comparison with conventional armor-piercing projectiles.

ATGM Malyutka (1 generation)

Shillelagh ATGM (2 generations)

Anti-tank guided missiles

anti-tank guided missile(ATGM) - a guided missile designed to destroy tanks and other armored targets. The former name of the ATGM is "anti-tank guided missile". ATGMs in the game are solid-propellant missiles equipped with on-board control systems (operating on the operator's commands) and flight stabilization, devices for receiving and decrypting control signals received via wires (or via infrared or radio command control channels). The warhead is cumulative, with armor penetration of 400-600 mm. The flight speed of missiles is only 150-323 m / s, but the target can be successfully hit at a distance of up to 3 kilometers.

The game features ATGMs of two generations:

  • First generation (manual command guidance system)- in reality, they are manually controlled by the operator using a joystick, eng. MCLOS. In realistic and simulation modes, these missiles are controlled using the WSAD keys.
  • Second generation (semi-automatic command guidance system)- in reality and in all game modes, they are controlled by pointing the sight at the target, eng. SACLOS. The reticle in the game is either the center of the crosshair of the optical sight, or a large white round marker (reload indicator) in the third person view.

In arcade mode, there is no difference between the generations of rockets, they are all controlled with the help of a sight, like second-generation rockets.

ATGMs are also distinguished by the launch method.

  • 1) Launched from the channel of the tank barrel. To do this, you need either a smooth barrel: an example is the smooth barrel of a 125-mm gun of the T-64 tank. Or a keyway is made in a rifled barrel, where a rocket is inserted, for example, in the Sheridan tank.
  • 2) Launched from guides. Closed, tubular (or square), for example, like the RakJPz 2 tank destroyer with the HOT-1 ATGM. Or open, rail (for example, like the IT-1 tank destroyer with the 2K4 Dragon ATGM).

As a rule, the more modern and the larger the caliber of the ATGM, the more it penetrates. ATGMs were constantly improved - manufacturing technology, materials science, and explosives improved. The penetrating effect of ATGMs (as well as cumulative projectiles) can be completely or partially neutralized combined armor and dynamic protection. As well as special anti-cumulative armor screens located at some distance from the main armor.

Appearance and device of shells

    Armor-piercing sharp-headed chamber projectile

    Sharp-headed projectile with armor-piercing tip

    Sharp-headed projectile with armor-piercing tip and ballistic cap

    Armor-piercing blunt projectile with ballistic cap

    Sub-caliber projectile

    Sub-caliber projectile with detachable pallet

    HEAT projectile

    Non-rotating (feathered) cumulative projectile

  • A denormalization phenomenon that increases the path of a projectile through armor

    Starting with game version 1.49, the effect of shells on sloped armor has been redesigned. Now the value of the reduced armor thickness (armor thickness ÷ cosine of the angle of inclination) is valid only for calculating the penetration of HEAT projectiles. For armor-piercing and especially sub-caliber shells, the penetration of sloping armor was significantly reduced due to the denormalization effect, when a short shell turns around during penetration, and its path in the armor increases.

    So, at an angle of inclination of the armor of 60 °, penetration for all shells fell by about 2 times. Now this is true only for cumulative and armor-piercing high-explosive shells. For armor-piercing shells, penetration in this case drops by 2.3-2.9 times, for conventional sub-caliber shells - by 3-4 times, and for sub-caliber shells with a detachable pallet (including BOPS) - by 2.5 times.

    List of shells in order of deterioration of their work on sloped armor:

    1. Cumulative And armor-piercing high-explosive- the most efficient.
    2. Armor-piercing blunt And armor-piercing sharp-headed with an armor-piercing tip.
    3. Armor-piercing sub-caliber with detachable pallet And BOPS.
    4. Armor-piercing sharp-headed And shrapnel.
    5. Armor-piercing sub-caliber- the most inefficient.

    Here, a high-explosive fragmentation projectile stands apart, in which the probability of penetrating the armor does not depend on its angle of inclination at all (provided that no ricochet has occurred).

    Armor-piercing shells

    For such projectiles, the fuse is cocked at the moment of penetration of the armor and undermines the projectile after a certain time, which ensures a very high armor effect. The parameters of the projectile indicate two important: fuse sensitivity and fuse delay.

    If the thickness of the armor is less than the sensitivity of the fuse, then the explosion will not occur, and the projectile will work like a regular solid one, damaging only those modules that are in its path, or simply fly through the target without causing damage. Therefore, when firing at unarmored targets, chamber shells are not very effective (as well as all others, except for high-explosive and shrapnel).

    The fuse delay determines the time after which the projectile will explode after breaking through the armor. Too little delay (in particular, for the Soviet MD-5 fuse) leads to the fact that when it hits a tank attachment (screen, track, undercarriage, caterpillar), the projectile explodes almost immediately and does not have time to penetrate the armor. Therefore, when firing at shielded tanks, it is better not to use such shells. Too much delay of the fuse can cause the projectile to go right through and explode outside the tank (although such cases are very rare).

    If a chamber projectile is detonated in a fuel tank or in an ammunition rack, then with a high probability an explosion will occur and the tank will be destroyed.

    Armor-piercing sharp-headed and blunt-headed projectiles

    Depending on the shape of the armor-piercing part of the projectile, its tendency to ricochet, armor penetration and normalization differ. General rule: blunt-headed shells are best used on opponents with sloped armor, and sharp-headed ones - if the armor is not sloped. However, the difference in armor penetration in both types is not very large.

    The presence of armor-piercing and / or ballistic caps significantly improves the properties of the projectile.

    Sub-caliber shells

    This type of projectile is characterized by high armor penetration at short distances and a very high flight speed, which makes it easier to shoot at moving targets.

    However, when armor is penetrated, only a thin hard-alloy rod appears in the armored space, which causes damage only to those modules and crew members in which it hits (unlike an armor-piercing chamber projectile, which fills the entire fighting compartment with fragments). Therefore, in order to effectively destroy a tank with a sub-caliber projectile, it is necessary to shoot at its weak spots: engine, ammo rack, fuel tanks. But even in this case, one hit may not be enough to disable the tank. If you shoot at random (especially at the same point), it may take a lot of shots to disable the tank, and the enemy may get ahead of you.

    Another problem with sub-caliber projectiles is a strong loss of armor penetration with distance due to their low mass. Studying the armor penetration tables shows at what distance you need to switch to a regular armor-piercing projectile, which, in addition, has a much greater lethality.

    HEAT rounds

    The armor penetration of these shells does not depend on the distance, which allows them to be used with equal efficiency for both close and long-range combat. However, due to design features, HEAT rounds often have a lower flight speed than other types, as a result of which the shot trajectory becomes hinged, accuracy suffers, and it becomes very difficult to hit moving targets (especially at long distances).

    The principle of operation of the cumulative projectile also determines its not very high damaging ability compared to the armor-piercing chamber projectile: the cumulative jet flies for a limited distance inside the tank and inflicts damage only to those components and crew members in which it directly hit. Therefore, when using a cumulative projectile, one should aim just as carefully as in the case of a sub-caliber one.

    If the cumulative projectile hit not the armor, but the hinged element of the tank (screen, track, caterpillar, undercarriage), then it will explode on this element, and the armor penetration of the cumulative jet will significantly decrease (each centimeter of the jet flight in the air reduces armor penetration by 1 mm) . Therefore, other types of shells should be used against tanks with screens, and one should not hope to penetrate the armor with HEAT shells by shooting at the tracks, undercarriage and gun mantlet. Remember that a premature detonation of a projectile can cause any obstacle - a fence, a tree, any building.

    HEAT shells in life and in the game have a high-explosive effect, that is, they work and how high-explosive shells reduced power (light body gives less fragments). Thus, large-caliber cumulative projectiles can be quite successfully used instead of high-explosive fragmentation when firing at lightly armored vehicles.

    High-explosive shells

    The striking ability of these shells depends on the ratio of the caliber of your gun and the armor of your target. Thus, shells with a caliber of 50 mm or less are only effective against aircraft and trucks, 75-85 mm - against light tanks with bulletproof armor, 122 mm - against medium tanks such as T-34, 152 mm - against all tanks, with the exception of head-on shooting at the most armored vehicles.

    However, it must be remembered that the damage inflicted significantly depends on the specific point of impact, so there are cases when even a 122-152 mm caliber projectile causes very minor damage. And in the case of guns with a smaller caliber, in doubtful cases, it is better to use an armor-piercing chamber or shrapnel projectile, which have greater penetration and high lethality.

    Shells - part 2

    What is the best way to shoot? Overview tank shells by _Omero_


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). The 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 principle of operation 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 form 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. 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 (unlike the present, when improved shells of this type form the basis of the ammunition load of tank guns), the use of HEAT shells 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 shells (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, consisting of two main parts - armor-piercing core and 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 a bursting charge, ensuring that the target was hit by fragments of the core and fragments of armor heated to high temperatures. Sub-caliber projectiles had significantly less weight than conventional armor-piercing projectiles, 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 a streamlined shape, but they were much less common), which greatly worsened the ballistics of the projectile, in addition, a 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 armored 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 projectiles with a steel core and Pzgr.40(W) surrogate projectiles, which were a 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 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 an explosive wave, or immediately - shrapnel action, or with some delay (which allows the projectile to go deep 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. Well-armored tanks and self-propelled guns are resistant to high-explosive fragmentation shells. However, the impact of large-caliber shells 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