Capping for gunpowder from an artillery shell. The army will receive new cappings for shells. Painting of German mines, shells and fuses

The merciless “god of war” in armed conflicts of the first half of the twentieth century was artillery. Not an elegant, fast fighter plane or a formidable tank, but a simple and unpretentious-looking mortar and cannon destroyed fortifications, firing points and command posts, quickly and mercilessly destroyed the enemy who had risen to attack (they accounted for half of all those killed and wounded in World War II), and paved the way for their tanks and motorized infantry.

((direct))

Among all the components of artillery equipment, ammunition should be considered the most important. Ultimately, it is the projectile (mine, bullet) that is the “payload” for the sake of delivering which to the target the entire huge complex, consisting of people, guns, artillery tractors, cars, communication lines, spotter aircraft, etc., works.

Astronomical figures

Low shooting accuracy was compensated for in that era by the huge consumption of ammunition (according to the standards, 60–80 shells were supposed to be used to suppress one machine gun point). As a result, even in terms of the simplest characteristic - total weight - artillery shells were significantly superior to the weapon with which they were brought down on the enemy’s head.

Thus, established by order of the People's Commissariat of Defense No. 0182 (by a strange irony of history, this order was signed on May 9, 1941), the ammunition load for the most popular 122-mm howitzer in the Red Army was 80 rounds. Taking into account the weight of the projectile, charge and closure (shell box) total weight one ammunition load (about 2.7 tons) was more weight the howitzer itself.

However, you can’t fight much with just ammunition. As a rule, to conduct offensive operation(which corresponds to 10–15–20 days in calendar terms), the planned ammunition consumption was 4–5 rounds of ammunition*. Thus, the weight of the required ammunition was many times greater than the weight of the guns involved. Unfortunately, the Second World War was not limited to one or two operations, and ammunition consumption began to be measured in absolutely astronomical figures.

In 1941, the Wehrmacht spent about 580 kilotons of ammunition of all types on the Eastern Front, which is approximately 20 times the total weight of all artillery systems operating on the front (and even ten times the weight of all German tanks and self-propelled guns). And subsequently, both the production of ammunition in Germany and their consumption became even greater. Ammunition production in the USSR for the entire period of the Great Patriotic War estimated at a staggering 10 million tons.

Collage by Andrey Sedykh

Here it is also necessary to remember that a ton is different from a ton. If the weight of a gun is the weight of relatively cheap ferrous metal (the carriage elements are made of simple low-alloy steel), then expensive brass, copper, bronze, and lead are spent on the production of an artillery round; the production of gunpowder and explosives requires a huge consumption of chemicals, which are scarce in war conditions, expensive and highly explosive. Ultimately, the cost of producing ammunition during the Second World War was comparable to the total cost of producing everything else (tanks, guns, airplanes, machine guns, tractors, armored personnel carriers and radars).

Oddly enough, it was precisely this most important information about the material preparation for the war and its progress that was traditionally kept silent in Soviet historiography. Those who want to verify this for themselves can open, for example, the 2nd volume of the fundamental 6-volume “History of the Great Patriotic War of the Soviet Union” (M., Voenizdat, 1961). To describe the events of the initial period of the war (from June 22, 1941 to November 1942), the team of authors needed 328 thousand words in this volume. And why isn’t there! The labor initiatives of home front workers and the uplifting plays of Soviet playwrights are listed; neither the vile machinations of the faithless allies (that is, the USA and Great Britain), nor the leading role of the party are forgotten... But the specific figure for ammunition consumption in the operations of the Red Army appears only once (“ during the defensive battle of Stalingrad, 9,898 thousand shells and mines were delivered to the troops of the Stalingrad and Don fronts"), and even then without the detail required within the framework of a scientific monograph. Not a word at all about the consumption of ammunition in the operations of 1941! More precisely, there are words and there are many of them, but without numbers. Usually the words are: “having spent last shells, the troops were forced...", "an acute shortage of ammunition led to...", "already on the third day the ammunition was almost completely exhausted..."

We will try, as far as possible within the framework of a newspaper article, to partially fill this omission.

To whom has history given little time?

Let us immediately note that Comrade Stalin loved and appreciated artillery, and fully understood the role and importance of ammunition: “Artillery decides the fate of the war, mass artillery... If you need to fire 400-500 thousand shells a day to smash the enemy’s rear, smash the enemy’s forward edge in order to he was not calm, so that he could not sleep, it was necessary not to spare shells and cartridges. More shells, more ammunition, less people will be lost. If you skimp on cartridges and shells, there will be more losses...”

These remarkable words were spoken at the April (1940) Meeting of the Red Army's senior command staff. Unfortunately, such a correct statement of tasks was not properly reflected in the real state of affairs with which soviet artillery a year later came to the threshold of the Great War.

As we see, surpassing Germany in the number of guns of all main types, Soviet Union inferior to his future enemy and total number accumulated reserves of ammunition, and by the specific number of shells in terms of one barrel. Moreover, it was precisely this indicator (the number of accumulated ammunition per unit of gun) that turned out to be the ONLY one by which the enemy had a significant quantitative superiority over the Red Army (of course, we are talking about the main components of material preparation for war, and not about some ungulate rasps) .

And this is all the more strange considering that Germany was in a particularly difficult situation in accumulating ammunition for a future war. Under the terms of the Versailles Peace Treaty, the victorious countries set strict limits for it: 1000 artillery rounds for each of the 204 75 mm guns and 800 rounds for each of the 84 105 mm howitzers. And it's all. A meager (compared to the armies of the great powers) number of guns, 270 thousand (less than Comrade Stalin proposed to use in one day) medium-caliber artillery rounds and zero large-caliber rounds.

Only in the spring of 1935 did Hitler announce Germany’s withdrawal from subjection to the conditions Treaty of Versailles; There were just over four years left before the start of the World War. History gave Hitler little time, and nature gave him even fewer raw materials. As is known, the extraction and production of copper, lead, tin, saltpeter and cellulose in Germany is not very good. The Soviet Union was in an incomparably better position, but by June 1941, Germany had accumulated about 700 kilotons of “payload” (shells) of medium-caliber artillery (from 75 mm to 150 mm), and the Soviet Union - 430 kilotons. 1.6 times less.

The situation, as we see, is quite paradoxical. The following idea is generally accepted: Germany had enormous scientific and technical potential, but was limited in raw materials, while the “young Soviet republic” had just embarked on the path of industrialization and therefore could not compete on equal terms in the field of “ high technology"with German industry. In fact, everything turned out to be exactly the opposite: the Soviet Union produced incomparably large quantity more advanced tanks, surpassed Germany in the number of combat aircraft, guns and mortars, but at the same time, possessing huge reserves of non-ferrous metal ores and raw materials for the chemical industry, it lagged significantly behind in the matter of mass production and accumulation of ammunition.

How KV was “lowered” to the level of the German “four”

In the general situation with the supply of ammunition to the Red Army on the eve of the war, there was a failure that is completely difficult to explain with reasonable arguments. The troops had very few armor-piercing rounds for the 76 mm cannon. Specifically, this “very little” is expressed by the figure of 132 thousand armor-piercing 76-mm rounds available as of May 1, 1941. In terms of one divisional or tank 76-mm gun, this means 12.5 rounds per barrel. And this is on average. But in the Western Special Military District, which found itself in the direction of the main attack of two Wehrmacht tank groups, the corresponding figure was only 9 armor-piercing shells per barrel (the best situation - 34 AR shells per barrel - turned out to be in the Odessa district, that is, exactly where there were no not a single German tank division).

Ammunition for: GermanyUSSR
Total (million pieces) For one barrel (pcs.)Total (million pieces)For one barrel (pcs.)
81 mm (82-, 107 mm) mortars12,7 1100 12,1 600
75 mm (76 mm) field guns8,0 1900 16,4 1100
105 mm (122 mm) howitzers25,8 3650 6,7 800
150 mm (152 mm) howitzers7,1 1900 4,6 700
Total artillery shots43,4 2750 29,9 950
Total artillery rounds and mines56,1 2038 42,0 800

The shortage of armor-piercing 76-mm rounds has largely “nullified” two significant military-technical advantages of the Red Army: the presence in the rifle division’s armament of 16 “divisions” of F-22 or USV, capable of penetrating the frontal armor of any German tank in the summer of 1941, and long-barreled “three-inch” guns on new types of tanks (T-34 and KV). In the absence of armor-piercing shells, the latest soviet tanks“sank” to the level of the German Pz-IV with a short-barreled 75-mm “cigarette butt”.

What was missing to organize mass production of 76-mm armor-piercing rounds? Time? Resources? Production capacity? The T-34 and KV tanks were adopted by the Red Army on December 19, 1939. The F-22 divisional 76-mm cannon was put into service even earlier - in 1936. At a minimum, from this moment on, we should be concerned with the production of ammunition that would allow us to fully realize the combat potential of these weapon systems. The production capacity of the Soviet economy made it possible to accumulate 16.4 million high-explosive fragmentation rounds for 76-mm regimental, divisional and mountain cannons and another 4.9 million rounds for 76 mm anti-aircraft guns. Total - 21.3 million 76-mm artillery rounds. At the same time, it should also be taken into account that an armor-piercing shot is in no way superior to a high-explosive fragmentation shot in cost and resource intensity, and an anti-aircraft shot is much more complex and more expensive than an armor-piercing shot.

The most convincing answer to the question about the ability of Soviet industry to establish mass production armor-piercing shells can be considered the presence of 12 million armor-piercing rounds for 45-mm guns at the beginning of the war. And even this quantity was still considered insufficient, and in the ammunition production plan for 1941, a separate line was prescribed for the production of 2.3 million armor-piercing 45-mm rounds.

Only on May 14, 1941, the alarming situation with the shortage of 76-mm armor-piercing rounds was realized by the country's leadership. On this day, a resolution was adopted by the Council of People's Commissars and the Central Committee of the VKP(b), according to which at plant No. 73 alone it was planned to increase the production of 76-mm BR rounds to 47 thousand per month. The same decree ordered the production of ballistic missiles for the 85-mm anti-aircraft gun (at a rate of 15 thousand per month) and the heavy 107-mm hull gun. Of course, in the few weeks remaining before the start of the war, it was not possible to radically change the situation.

Everything is relative

“So that’s why German tanks crawled to Moscow and Tikhvin!” - the hasty reader will exclaim and will be deeply wrong. Everything is learned by comparison, and comparing the number of ballistic missile shells with the number of artillery barrels is only one of many evaluation criteria. After all, the projectile is not intended to grind down a gun barrel, but to hit the enemy. Armor-piercing shells are not fired “at areas”, “fire curtains” are not set up, barrage fire is not conducted, and they do not have to be spent in millions. Armor-piercing shells are used when firing a direct shot at a clearly visible target.

As part of the German invasion army, targets that would be worth spending a three-inch armor-piercing projectile, was about 1400 (strictly speaking, even less, since among the average Pz-IV tanks there were a number of early series vehicles with 30 mm frontal armor). Dividing the actually available shells by the number of tanks, we get an impressive figure: 95 pieces of 76-mm armor-piercing shells for one medium German tank or self-propelled gun with reinforced frontal armor.

Yes, of course, war is not solitaire, and in war you cannot ask the enemy to move medium tanks to the firing positions of 76-mm “divisions”, and other lightly armored little things - closer to anti-tank “forty-fives”. But even if circumstances force us to spend scarce 76-mm BR shells on any armored tracked vehicle that appears in the sights (and there were no more than four thousand of them in the Wehrmacht on the Eastern Front, including machine-gun wedges and light self-propelled guns), then even then, purely arithmetically, in our There are 33 projectiles available for one target. If used skillfully, it is quite enough to guarantee defeat. “Very little” this will be only in comparison with the gigantic scale of production of armor-piercing 45-mm shells, of which by the beginning of the war three thousand pieces had been accumulated per German tank.

The above “arithmetic” is too simple and does not take into account many important circumstances, in particular the real distribution of the available ammunition resource between various theaters of operations (from Brest to Vladivostok) and central artillery supply depots. On the eve of the war, 44 percent of the total population was concentrated in the western border districts. total stock artillery shots; share of 45-mm artillery rounds (all types, not just ballistic missiles) concentrated in western districts, accounted for 50 percent of the total resource. A significant part of the 45-mm rounds were not found in infantry (rifle) divisions, but in tank (mechanized) units and formations, where light tanks (T-26 and BT) and armored vehicles BA-6/BA-10 were armed with 45-mm guns . In total, in five western border districts (Leningrad, Baltic, Western, Kiev and Odessa) there were almost 10 thousand “forty-five” under armor, which even exceeded the number of towed 45-mm anti-aircraft guns. tank guns, of which there were “only” 6870 units in the western districts.

"Mud-clay"

On average, each of these 6,870 guns carried 373 armor-piercing 45 mm shells; In the districts themselves, this figure varied from 149 in Odessa to 606 in Western. Even counting at the very minimum (not taking into account the presence of their own tanks, not taking into account the troops and weapons of the Leningrad and Odessa districts), on the morning of June 22, 1941, German tanks were expected to meet 4997 anti-tank “forty-fives”, in the charging boxes of which 2.3 million armor-piercing rounds were stored . And another 2551 divisional 76-mm cannon with a very modest supply of 34 thousand BR rounds (an average of 12.5 per barrel).

It would be appropriate to recall the presence in three border districts of 2201 anti-aircraft gun caliber 76 mm and 85 mm, 373 hull 107 mm guns. Even with complete absence BR rounds, they could be used to fight tanks, since the energy of these powerful guns made it possible to accelerate a high-explosive fragmentation or shrapnel projectile to speeds sufficient to penetrate the armor of German light tanks at a kilometer range.** As one would expect, artillery rounds For anti-aircraft guns a particularly large number were accumulated (more than 1,100 per 76-mm anti-aircraft gun in the western districts).

Two weeks after the start of the war, on July 5, 1941, signed by Lieutenant General Nikolai Vatutin, who assumed the duties of Chief of Staff of the North-Western Front (on the eve of the war - Head of the Operations Directorate, Deputy Chief of the General Staff of the Red Army), “Instructions for combating tanks” were issued. enemy”, which instructed “to prepare mud and clay, which is thrown into the viewing slots of the tank.” And if Vatutin’s desperate order can still be classified as a tragic curiosity, then the infamous Molotov cocktails in July 1941 were quite officially adopted by the Red Army and were produced by dozens of factories in millions of quantities.

Where have other, incomparably more effective means of fighting tanks than “mud-clay” and bottles gone?


*For example, in the original (October 29, 1939) plan for the defeat Finnish army on the Karelian Isthmus, the following ammunition consumption was planned: 1 ammunition for combat in the border zone, 3 ammunition for breaking through a fortified area (Mannerheim Line) and 1 ammunition for the subsequent pursuit of a retreating enemy

**As practice has shown, the most effective was the use of shrapnel shells with the fuse set “on impact”; in this case, in the first microseconds of interaction between the projectile and the armor, the impact of the steel body of the projectile led to cracking of the cemented surface of the armor plate, then, after the fuse and expelling charge were triggered, the lead shrapnel pierced the armor. The use of HE shells to combat armored vehicles was possible in two versions. In one case, the fuse was set to “non-explosion” or simply replaced with a plug; penetration of the armor occurred due to the kinetic energy of the projectile. Another method involved shooting at the sides of the tank at high angles; the projectile “slipped” along the surface and exploded, while the energy of the shock wave and fragments was enough to penetrate the side armor, the thickness of which on any German tanks in the summer of 1941 did not exceed 20–30 mm

For the first time, guns using gunpowder as a propellant appeared in the 14th century. From the walls of the fortresses, stone cannonballs were thrown from “shooting pipes” at the attackers. There was a lot of smoke, fire, and roar, but such shooting caused little damage to the attackers.

In Russia, in the Galishsh and Alexander Chronicles (1382), the use of weapons called “mattresses”, “pusk-chi”, “guns” in defense against the Tatar-Mongol hordes was described for the first time.

In 1480, during the reign of Ivan III, the “Cannon Yard” was built in Moscow, which was the first cannon factory in the world. One of the goals of its creation was to streamline the manufacture of guns, in which the parameters for strength requirements, caliber and design would be maintained. This will ensure

established the conditions for the rapid and targeted development of artillery, which was successfully used in the wars waged by Ivan III and Ivan IV.

At the beginning of the 17th century. Russian craftsmen created a new generation of guns that were loaded not from the muzzle, but from the breech. These were guns with wedge and screw-in bolts, which were the prototypes of the bolts used in modern artillery guns. In addition, the guns had a rifled barrel, which opened up the possibility of moving from cannonballs to more powerful cylindrical projectiles. However, these inventions significantly outstripped the technical production capabilities of that time, so their mass application was delayed for 150-200 years.

During the reign of Peter I, artillery underwent a serious organizational and technical transformation. Peter I divided all artillery into four types: siege, garrison (fortress), regimental and field. Organized the calibers and mass of charges and shells. The results were not long in coming. IN early XVIII V. in the war with Sweden, whose army was considered invincible thanks to its artillery, Russian troops won brilliant victories near Narva and Poltava. During the capture of Narva, for example, artillery shelling was carried out continuously for 10 days. 12,358 cannonballs and 5,714 mortar bombs were fired at the fortress, 10 thousand pounds of gunpowder were consumed

The history of Russian artillery has many glorious pages. These are victories over the Prussian king Frederick II (mid-18th century), the capture of Izmail in the war with Turkey (1790), the defeat of French troops in the war of 1812, many naval battles (Battle of Chesme 1779, battles during the defense of Sevastopol in 1854 Crimean War 1853-1856 etc.).

The most intensive development of artillery occurred in the second half of the 19th century. Improvement technical base made it possible to completely switch to the production of rifled guns with breech loading. The first steps were taken to increase the rate of fire of guns, in particular, thanks to the creation of a high-speed piston bolt and a unitary artillery cartridge, in which the projectile and powder charge were connected into one whole using a cartridge case. But the most rapid, revolutionary development of artillery began after the invention of smokeless gunpowder (1886). Smokeless gunpowder was three times stronger than smoky gunpowder. This made it possible to increase the firing range and accuracy.

Smokeless powder also eliminated the enormous amount of smoke that, during mass shooting with black powder, created a smoke screen that did not allow targeted fire.

The development of artillery led to the creation of several types of guns, each with its own design features and purpose - these are cannons, howitzers, and mortars. Later, mortars and recoilless rifles appeared.

The guns (Fig. 10.1) were intended for firing over long distances (up to 30 km) at ground and air targets.


The caliber of guns is from 20 to 180 mm. Barrel length 40 - 70 calibers. The initial speed of the projectile is at least 600 m/s (for some tank guns it reaches 1600 m/s, for example, in the Leopard - 2 tank). The guns fire at low elevation angles (usually up to 20 degrees). The projectile's flight path is flat (sloping).

Howitzers are used to fire at hidden targets. They have a shorter barrel (10-30 calibers), fire at large elevation angles (mounted trajectory), howitzer calibers are 100 mm or more. The initial speed of a projectile is less than that of a cannon projectile. For example, the projectile speed of a 76 mm cannon is 680 m/s, and that of a 122 mm howitzer is no more than 515 m/s. The reduction in speed is achieved by reducing the ratio of the mass of the gunpowder charge to the mass of the projectile in comparison with the gun. The firing range is about 18 km.

In Fig. Figure 10.2 shows the appearance of the howitzer.

Currently, guns that combine the properties of a howitzer and a cannon (the possibility of flat and mounted firing) are becoming increasingly popular.

These are howitzers - guns. Their caliber is from 90 mm or more, the barrel length is 25-^0 calibers, the firing range is about 20 km.

Mortar-type weapons have been used since the 15th century. They had co-

short barrel (no more than 10 calibers), large caliber, fired powerful bombs with a large explosive charge and were intended to destroy particularly strong structures. The flight path had a large steepness (steep overhead trajectory). The initial flight speed of the projectile was about 300 m/s, and the flight range was relatively short. The ratio of the mass of the gunpowder charge to the mass of the projectile was even less than for a howitzer. In service modern army no mortars. However, by the beginning of World War II, the reserves of the Red Army High Command included 280 mm caliber mortars with a firing range of 10 km (initial projectile speed 356 m/s).

To replace mortars in all armies of the world at the beginning of the 20th century. new type of guns arrived - mortars. These are smooth-bore guns for mounted firing, providing the ability to defeat the enemy located in trenches located adjacent to their positions (400 - 500 m). Today in service are mortars of calibers from 60 to 240 mm, with a mine weight from 1.3 to 130 kg and a firing range from several hundred meters to 10 km.

The initial flight speed of the mine with the smallest charge of gunpowder is only 120 m/s.

By design, the mortar is a steel pipe smooth inside, supported by a ball heel on a plate (Fig. 10.3).

Firing is carried out by lowering the mine with its tail into the barrel (large-caliber mortars are loaded from the breech). In the mine stabilizer tube

there is a tail cartridge with the main charge of gunpowder. In the bottom of the cartridge there is an igniter primer that bumps

on the firing pin when the mine reaches its lowest position, it explodes and initiates the combustion of the powder charge. The main charge of gunpowder is taken small. If necessary, an additional charge of gunpowder is placed on the stabilizer tube to increase the firing range. The mortar's rate of fire reaches 15-20 rounds per minute.

In the first quarter of the 20th century. appeared the new kind artillery guns - recoilless (dynamo-reactive) guns designed to destroy manpower, destroy fortifications and, mainly, to fight tanks. The operating principle of a recoilless rifle is shown in Fig. 10.4.

The shell casing has holes covered with cardboard. When fired, the cardboard breaks through and through the opened holes, part of the gaseous combustion products enters the breech, in the rear of which there are nozzle holes. The resulting reaction force balances the recoil force. This eliminates the need to make complex anti-tank devices, which greatly simplifies the design of the gun. Recoilless rifles have rifled barrel. For firing, unitary cartridges with fragmentation, high-explosive fragmentation, and cumulative grenades are used, which correspond in power to conventional projectiles. Considering that part of the energy of the powder gases is spent on recoil compensation, the initial speed

flight is about 300 m/s, the firing range is significantly less than conventional guns and shooting is most effective at visible targets. Depending on the caliber, recoilless rifles can be portable or placed on a vehicle.

Before moving on to consider the influence of various factors on an artillery shot, let us dwell on the very concept of “shot”. This term has two meanings. One of them involves the phenomenon of a shot from firearms, and the second is the product, the ammunition, with which the shot is fired.

The phenomenon of a shot is the process of ejecting a projectile due to the energy of powder gases. When fired, in a fraction of a second, powder gases having a temperature of 3000-3500 ° C develop a pressure of up to 300-400 MPa and push the projectile out. This useful type of work requires 25-30% of the energy of the powder charge.

Artillery shot like weapon(ammunition) represents a complete set of all elements necessary to fire one shot. It includes: a projectile, a projectile fuse, a propellant (combat) charge of gunpowder in a cartridge case or cap, a means of igniting the propellant charge (igniter capsule, ignition tube, etc.), auxiliary elements (phlegmatizer, decoupler, flame arrester, cardboard elements).

The main ballistic indicators of an artillery shot are: the maximum pressure in the gun barrel (p t) and the speed of the projectile at the barrel exit (U 0).

It was previously noted that smokeless powder burns in parallel layers on all sides of the powder element. The combination of this quality with the energy characteristics of the gunpowder, shape, grain size and sample size allows you to adjust the basic ballistic parameters of the shot and create charges with specified properties.

Gunpowder, depending on the energy indicator (heat of combustion pg), is divided into three groups:

High-calorie, having () 4200-5300 kJ/kg (1000-1260 kcal/kg). To increase the calorie content, explosives with a high heat of combustion (octogen, RDX, DINA) are introduced into their composition. High-calorie powders are used for mortar rounds;

Medium-calorie powders with () 3300-4200 kJ/kg (800-1000 kcal/kg) are used to make charges for low-power guns;

Low-calorie (“cold”) powders having<3 Г 2700-3300 кДж/кг (650-800 ккал/кг), используются для зарядов к ору­диям больших калибров. Применение «холодных» порохов для
powerful guns is caused by the desire to minimize the heat (erosion) of the internal surface of the barrel, which is directly dependent on the temperature and pressure of the shot.

The rate of gas release during the combustion of gunpowder is to a certain extent regulated by the shape of the powder elements. From the pirok-. siline powders, elements are made in the form of grains with one or seven channels, as well as in the form of tubes (Fig. 10.5 A). Tubes, plates, tapes and rings are prepared from ballistic powders (Fig. 10.5 b)

Channel grains have a progressive combustion character, since the burnout of gunpowder from the surface of the grain and channels leads to an increase in the combustion area. Tubular gunpowders are close to a constant gas release rate. Ribbons and rings (mortar powders) have a regressive combustion pattern.

Powders with a progressive gas release rate are used in long-barreled guns (cannons), since in order to impart high speed to the projectile over a significant length of the barrel, the pressure must be close to the maximum.

For guns with short barrel lengths, tubular powders are used. This is due to the fact that the maximum pressure in a short

bone guns should last a shorter period of time and its value may be lower than in cannons.

In mortars, the initial speed of the mine is low and, therefore, there is no need to create high pressure with a long period of its retention. Therefore, for mortar powder charges Gunpowder with a regressive combustion character is quite suitable.

Depending on the chemical nature and form, artillery powders are marked as follows:

Grained pyroxylin powder is designated by shot,

the numerator of which shows the thickness of the burning arch in tenths of a millimeter, and the denominator is the number of channels. For example: 7/7 - vault thickness 0.7 mm, seven channels; 14/7 - vault thickness 1.4 mm, seven channels; 7/1 - vault thickness 0.7, one channel;

Tubular gunpowder is also designated by shot, but with the addition of the letters TP. For example: 10/1TP - arch thickness 1 mm, one channel, tubular;

Ballistic tubular powders do not have the letter index TP, since they are not manufactured in the form of grains, but they do have the letter index H, for example: 30/1Н denotes tubular nitroglycerin powder with a burning arch thickness of 1 mm and one channel;

Belt gunpowder has the letter index L and a number indicating the thickness of the burning arch in hundredths of a millimeter. For example: NBL-35 - nitroglycerin ballistic tape with a burning arch thickness of 0.35 mm;

Ring-shaped gunpowder has a letter index K and three digital indicators, two of which are written in the form of a fraction (numerator - internal, denominator - external diameter, mm) and the third, separated from the fraction by a line, indicates the thickness of the burning arch in hundredths of a millimeter, for example, NBK30/65-12;

Nitroglycerin ballistic ring powder with an internal diameter of 30 mm. external 65 mm and the thickness of the burning arch is 0.12 mm.

Depending on the gun system, caliber and task performed, different grades of gunpowder are used. All powder charges certainly have two main elements - a sample of gunpowder and an igniter. According to the mounting arrangement, charges are divided into constant and variable. Both can be full or reduced. Constant charges are used in unitary cartridges (Fig. 10.6), which represent factory-assembled artillery shots in the form of a projectile and a powder charge combined with a shell casing, and cannot be changed before firing. Typically, unitary cartridges are used for small and medium caliber guns.



In some cartridge-loading shots with a combat charge of grained powder, central ones are used to ensure simultaneous ignition of the gunpowder throughout the entire volume of the charge; perforated paper tubes filled with hollow cylinders of black powder (Fig. 10.6 b). When a flame extinguishing agent is introduced into the tube, it also acts as a flame arrester.

As the caliber increases, the unitary cartridge becomes inconvenient for loading due to its large mass and size. In this case, cased and caseless separate loading is used.

With separate case loading, a projectile is first sent into the gun barrel, and then - a cartridge case with a portion of gunpowder, which is located in caps (bags made of flammable fabric). In large-caliber guns (ship guns, coastal defense), in which caseless separate loading is carried out, a sample of gunpowder is placed in the chamber in caps without a case.

Separate charging options are shown in Fig. 10.7.

Moreover, the weight can be changed immediately before firing in accordance with the combat mission being solved. The design of mortar powder charges is shown in Fig. 10.8. The figure shows that the amount of gunpowder in a mortar shot has a main charge and an additional charge in the form of caps placed on the shank of the mine, the number of which varies depending on the given firing range.

Percussion, grating or electrical excitation primers are used as igniters in artillery and mortar rounds. Igniter capsules are usually mounted in an igniter sleeve, which has increased ignition ability due to black powder pressed into the sleeve.

For the purpose of quick and complete ignition, additional igniters are used in cap-loading charges, which are cakes of black powder pressed or poured into the cap.

In addition to the two main components (the sample and the igniter), additional elements can be included in the charge - reflux gasser, copper reducer and flame arrester. The first two are used to reduce the height of the trunk. A flash suppressor is used to extinguish muzzle and backfire. The muzzle flame represents hot luminous gaseous products, as well as the glow from the afterburning of products of incomplete oxidation.

The length of the muzzle flame, depending on the gun system, the properties of the gunpowder and meteorological conditions, can be from 0.5 to 50 m, and the width - from 0.2 to 20 m.

The flame from a 76-mm cannon at night can be seen from an airplane 200 km away.

Naturally, this significantly unmasks artillery combat positions, especially during night firing.

Backfire is the flame that occurs when the breech of a gun is opened. It is especially dangerous when fired from tank guns. The fight against muzzle and backfire is carried out by introducing muzzle and backfire flame arresters into the charge. The muzzle flash suppressor is usually a cap with powdered potassium sulfate, taken in an amount of 2-15% of the mass of gunpowder, located in the upper part of the charge.

Backfire flame arresters represent a sample (about 2% of the weight of the gunpowder charge) of flame-extinguishing powder (pyroxylin powder containing 45-50% of a flame-extinguishing substance, for example potassium sulfate) placed in a cap, located in the lower part of the charge.

The ballistic performance of a shot depends on a number of factors, the decisive ones being the design of the gun and the nature of the powder charge (weight, speed and volume of gas release during combustion, maximum pressure in the gun barrel, etc.).

In table 10.2 shows the firing characteristics of some gun systems. The table shows that when moving from cannons to howitzers, the firing range decreases. This is natural, since in a howitzer shot the mass of the powder charge in relation to the mass of the projectile is 2-A times less compared to the ratio in a cannon shot. The maximum firing range for the guns considered does not exceed 40 km.

The question arises: is it possible to create long-range artillery systems?

One of the reasons preventing a significant increase in firing range is air resistance to the flight of the projectile. Moreover, the degree of resistance increases with increasing projectile speed. For example, the estimated flight range of a 76-mm cannon projectile in airless space is 30-40 km, while in practice, due to air resistance, this distance is reduced by 10-15 km.

In 1911, the famous Russian artilleryman Trofimov proposed to the Main Artillery Directorate of the Tsarist Army to build a cannon that would have a firing range of 100 km or more. The main idea of ​​long-range was to launch a projectile to a high altitude, where the atmosphere is very rarefied, there is no resistance and the projectile travels a long distance without hindrance. However, this proposal did not receive support in the Main Artillery Directorate. And seven years later, the Germans fired at Paris from a cannon from a distance of more than 100 km. Moreover, the principle of ensuring long-range capability completely repeated Trofimov’s idea. The long-range gun was a weapon with a total mass of 750 tons, a projectile caliber of 232 mm, a barrel length of 34 m, and an initial projectile speed of 2000 m/s. The projectile was fired at a high angle (about 50°), pierced the dense layers of the atmosphere, rising approximately 40 km, and by this time had a speed of 1000 m/s. In a rarefied atmosphere, the projectile flew 100 km and descended along the descending branch of the trajectory, covering another 20 km of distance.

Thus, the total range was 120 km. However, firing from such a gun required disproportionate consumption of gunpowder. A projectile weighing 126 kg required a gunpowder charge of 215 kg, i.e. the ratio of gunpowder charge to projectile mass was close to two, whereas for conventional guns it is 0.2-0.4.

In addition, the gun barrel could withstand no more than 50-70 shots and after that the 34-meter barrel needed to be replaced.

All of the above casts doubt on the rationality of creating long-range artillery cannons.

To quickly and accurately determine the purpose of ammunition, its calibers and other basic characteristics necessary for proper configuration and operation, branding, painting and marking of ammunition are used.

Data on the manufacture of the projectile body, cartridge case, fuse, and ignition means are applied in the form of marks, and information about the type and equipment of the projectile, the manufacture of gunpowder and combat charge are applied in the form of markings and distinctive coloring.

Branding

Stamps are signs (letters, numbers) extruded or stamped on the outer surface of projectiles, fuses or tubes, cartridges and ignition means.

Artillery shells have main and backup marks (Fig. 1).

The main marks include signs showing the plant number 3, batch number 4 and year of manufacture 5 , shell (bottom) of the projectile, metal smelting number 1, stamp of the technical control department of the plant 6, stamp of the military representative of the GRAU 8 and Brinell sample imprint 2.

Stamps are applied on the outer surface of the projectile by the manufacturer in accordance with the drawing. Their location can be different and depends on the caliber of the projectile, the metal and the design of its shell.

If the projectile has a screw head or screw bottom, then the factory number, batch and year of manufacture of these elements are also applied to them.

For armor-piercing tracer shells, the batch number, quality control department stamp and military representative's stamp are placed on the leading belt. This is explained by the fact that these marks are applied after heat treatment of the body. Duplicate marks are applied at factories that produce equipment for projectiles and serve in case of loss of markings. These include: code of the explosive (smoke-forming) substance 7 with which the projectile is equipped, and weight (ballistic) marks 9.

The meaning of marks on mines is the same as on artillery shells.

They are located on the tail section and on the mine stabilizer tube.

The contents and meaning of marks on warheads, missile parts and rocket candles do not differ from the generally established marks on shells of shells and mines.

The marks on fuses and tubes (Fig. 2) indicate:

· fuse brand 1 (established abbreviated name);

· manufacturer code 2 (number or initial letters);

· production batch number 3;

· year of manufacture 4.

In addition, on the rings of pyrotechnic remote fuses and tubes, the batch number of pressing the remote composition 5 is indicated.



On head fuses, stamps are applied on the side surface of the body. On bottom fuses that have a tracer - along the circumference of the body flange, and in the absence of a tracer - directly on the bottom section of the body. On remote fuses and tubes, similar marks are located on the outer surface of the housing plate so that they can be seen when the sealing cap is screwed on.

Stamps on cartridge cases (Fig. 3) and capsule bushings (Fig. 4) are placed only on the bottom.

Ammunition painting

The coloring of ammunition is divided into protective and distinctive.

Preservative painting serves to protect metal from corrosion. In peacetime, the outer surface of all shells and mines with a caliber of more than 37 mm is painted with gray paint or another paint specified by the technical specifications. The exceptions are practical shells, which are painted black, and propaganda shells and mines, which are painted red. Projectiles of calibers of 37 mm and less, as well as the centering bulges and leading bands of all projectiles, are not painted.

In addition, for projectiles intended for unitary loading shots, the junction of the projectile with the cartridge case is not painted. All unpainted elements of shells and mines are coated with colorless varnish.

In wartime, protective painting, as a rule, is not applied to shells and mines with a caliber of up to 203 mm. A lubricant is used as an anti-corrosion coating, which must be removed before firing at the firing position.

Distinctive coloring is applied to some shells, mines, casings, fuzes and primer bushings.

On shells and mines, distinctive coloring is usually applied in the form of colored ring stripes.

Distinctive stripes applied to the head of the projectile (mine) or under the upper centering thickening indicate the type of projectile and make it easier to recognize them by purpose.



The colors, location and meaning of distinctive markings on shells and mines are given in Table. 1.

Rice. 2. Stamps on fuses and tubes

To distinguish streamlined sub-caliber projectiles from other armor-piercing tracer projectiles, their 35 mm warhead is painted red.

Table 1

For fragmentation and smoke shells, the bodies of which are made of steel cast iron, a continuous black annular strip is applied above the lower centering thickening or leading belt. Thus, a steel cast iron smoke projectile will have two black stripes - one on the head and the other above the lower centering thickening. All other shells are easily recognized by their appearance and do not have a distinctive color.

On cartridge cases of unitary loading shots assembled with a reduced charge, a solid black ring stripe is applied above the marking. The same stripe applied to the cartridge case for a shot of separate cartridge loading indicates that the cartridge case contains a special charge intended for firing an armor-piercing tracer projectile.

A distinctive color is applied to fuses and tubes if there are several samples that are similar in appearance, but different in their effect on the target or purpose.

A distinctive color is applied to capsule bushings only after they have been restored. After the first restoration, one white stripe 5 mm wide is applied along the chord of the bottom cut of the capsule bushings, and after the secondary restoration, two white parallel stripes, each 5 mm wide, are applied.

Ammunition indexing

All artillery weapons, including ammunition, are divided into ten sections (types).

Department numbers have a two-digit number and begin with the number 5. If there is another number at the beginning of the department number, then this means that this item is not under the jurisdiction of the GRAU.

Shots, shells, mines, fuses, tubes and their capping are assigned to the 53rd department; charges, cartridges, ignition means, auxiliary elements of shots and their closure - to the 54th department; ammunition small arms and hand grenades - to the 57th department. Each item is assigned a short symbol - an index.

In ammunition, indices are assigned to artillery rounds, their elements and closures.

Indexes can be full or abbreviated.

The full index consists of two numbers in front, one - three letters in the middle, and three numbers to the right of the letters.

For example, 53-UOF-412. The first two digits indicate the weapons department to which the sample belongs, the letters indicate the type of sample (in most cases they are the initial letters of the sample name), the last three digits indicate the sample number.

If a shot or its element (projectile, charge) is adopted for firing from a specific weapon (mortar), then it is assigned the same number as the weapon. If the shot element is intended for firing from different guns of the same caliber, then a zero is placed instead of the last digit of the index. For example: 53-G-530.

The meanings of the letters included in the ammunition indices are given in table. 2.

Weapons department no. Letter designations Name of items
U Unitary cartridge
IN Separately loaded shot
F High Explosive Grenade
ABOUT Frag grenade
OF High explosive fragmentation grenade
OR Fragmentation tracer projectile
OZR Fragmentation-incendiary-tracer projectile
BR Armor-piercing tracer projectile
BP HEAT rotating projectile
BC Cumulative non-rotating projectile
G Concrete-piercing projectile
D Smoke shell
Incendiary projectile
WITH Lighting projectile
A Propaganda projectile
PBR Practical armor-piercing tracer projectile

In the case when a new model of ammunition is adopted for service, similar in purpose and name to an existing model for a given weapon, but having features that affect ballistics or operational properties. one to three letters are placed at the end of the index.

For example, a 100-mm field gun mod. 1944 had an armor-piercing tracer pointed-head projectile index 53-BR-412. A 100-mm armor-piercing tracer projectile with a blunt point and a ballistic tip is being adopted. Unlike the first one, it is assigned the index 53-BR-412B. Later, the same gun was equipped with an armor-piercing tracer projectile with improved armor penetration (a projectile with armor-piercing and ballistic tips), which was assigned the index 53-BR-412D.

The abbreviated index differs from the full index in that it does not have a first two-digit number. For example, BR-412D; UOF-412U.

The markings on shots, shells, mines, cartridges and closures are marked with an abbreviated index, and the markings on caps and ammunition cases, as well as in technical documents, are marked with a full index.

Marking

Markings are inscriptions and symbols painted on ammunition and its closure.

Markings are applied to shells, mines, cartridges, caps and their sealing with special black paint. Practical equipment painted black is marked with white paint.

Marking of projectiles. Markings are applied to the head and cylindrical parts of the projectile (Fig. 5). On the head part there is information about the equipment of the projectile. These include: code of the explosive 6 with which the projectile is loaded, number of the loading plant 1, batch 2 and year of the equipment 3. On the cylindrical part there is an abbreviated name (index) 8, projectile caliber 4 and ballistic (weight) marks 5. For armor-piercing tracer projectiles except of the above data, under the code of the explosive, the mark of the bottom fuse 9 is applied, with which the projectile is brought into its final loaded form.

Codes are used to abbreviate explosive, smoke-producing and toxic substances.

The most common explosives used to fill projectiles have the following codes:

· TNT – t;

· TNT with a smoke-reinforcing block - TDU;

· TNT with dinitronaphthalene – TD-50, TD-58;

· TNT with hexogen – TG-50;

· TNT, hexogen, aluminum, golovax – TGAG-5;

· ammotol – A-40, A-50, A-60, A-80, A-90 (the figure shows the percentage of ammonium nitrate);

· ammotol with TNT stopper – AT-40, AT-50, etc.;

· phlegmatized hexogen – A-IX-1;

phlegmatized hexogen with aluminum powder – A-IX-2

On smoke shells, instead of the explosive code, the smoke-forming substance code 7 is placed.

The weight (ballistic) sign applied to the projectile shows the deviation of the weight of a given projectile from the table weight. If the projectile has a table weight or a deviation from it upward or downward of no more than 1/3%, then the letter H is written, which means the weight is normal. If the weight of the projectile deviates from the table by more than 1/3%, then this is reflected by the “plus” or “minus” signs. For each sign, a weight fluctuation is given within 2/3% of the table value (Table 3).

Table 3. Values ​​of weight marks marked on projectiles

Note. Shells with the LG and TZh marks are allowed only in wartime with special permission from the GRAU.

Marking on the sleeve. Markings are applied to the body of the cartridge case with the charge by the artillery base that assembled the unitary loading shot or the charge of the separate loading shot.

The markings indicate: abbreviated shot index 2, caliber and abbreviated name of the artillery system from which shot 3 is intended, grade of gunpowder 4, batch number 5 and year of manufacture of gunpowder 6, powder factory code 7, batch number 8, year of assembly 9 and number of the base (arsenal) 10, which collected the shot.

Instead of a shot index, a charge index is applied to the cartridge case for a shot of separate cartridge loading.

If the charge is assembled with a phlegmatizer, then the letter “F” is placed below the shot assembly data 11. In some cases, the markings on the cartridge case may be supplemented with the inscriptions 1: “Full variable”, “Reduced”, “Special”, etc.

Marking on the closure. Markings on the sealed box containing the shots indicate:

– on the front wall of the box – abbreviated designation of gun 1, for which the shots are intended to be fired, type of combat charge 2, type of projectile 3, weight sign 4, number of shots in the box 5, batch of shots assembled, year of assembly and number of the base that collected the shots 6 , brand of head fuses 7 screwed into shells, factory number, batch and year of manufacture of fuses 8, month, year and number of base 9, which carried out bringing the shots into their final loaded form; if the shots are stored in an incompletely loaded form, then the fuse marking is not applied to the front wall of the box;

– on the end wall of the box – shell index 10, loading plant number 11, batch 12 and year the shells were loaded 13, explosive code 14, if the box contains shots with armor-piercing tracer shells, then after the explosive code the brand of the bottom fuse with which the projectile was fired is indicated in a fully equipped state;

– on the lid of the box there is a danger sign and a load discharge 15.

The variety of tasks solved by troops in combat conditions requires the use of types of firearms that differ in their tactical and technical characteristics. This, in turn, leads to the need to have a variety of types of ammunition, including a fairly large variety of gunpowders and RTTs. According to their intended purpose (by type of weapon), gunpowder is usually divided into four groups:

  • 1) gunpowder for small arms;
  • 2) gunpowder;
  • 3) mortar powders;
  • 4) solid rocket fuels (ballistic and mixed).

Charges for small arms are made mainly

from pyroxylin, as well as from spherical ballistic powders of emulsion preparation. The powder elements of pyroxylin powders for small arms are cylindrical in shape without channels, with one and seven channels (grained gunpowder). These are thin-walled gunpowder with dimensions: thickness of the burning roof 2e, = 0.29-0.65 mm; length 2s- 1.3-3.5 mm; channel diameter U k = 0.08-0.35 mm.

Emulsion powders have a spherical shape (that's why they're called spherical), close to spherical (that's why they're sometimes called spherical).

Pyroxylin gunpowder can be grained single-channel and seven-channel cylindrical, seven-channel and 14-channel petal-shaped, as well as tubular. Ballistic gun powders are in the form of tubes with a single channel. The sizes of gunpowders are as follows: grained 2e]= 0.7-1.85 mm; 2s = 8.0-18.0 mm; With! P= 0.25-0.95mm; tubular 2e 1 = 1.4-3.10 mm; 2s = 210-500 mm; c1 k = 1.3-4.10 mm. The shape of gunpowders is shown in Fig. 2.2.

Ballistic mortar powders are prepared in the form of plates, tapes, rings with dimensions: 2e (=0.1-0.92 mm; 2c = 4.0-257 mm; 2в = 4-47 mm; ?) = 65 mm; 32 mm. They are shown in Fig. 2.3.

The shape and size of the powder elements are the main factors determining the law of gas formation during the combustion of gunpowder, which is expressed by the dependence of the intensity of gas formation on the burnt part of the gunpowder, i.e. G = (x t o-i ])/e ]= f(y).

Rice. 2.1

A - channelless grain; 6 - single channel; V - seven-channel; g - spherical

Rice. 2.2.

A - seven-channel grain; 6 - seven-channel, petal-shaped grain; V - a tube

Rice. 2.3. Forms of gunpowders: A - plate; 6 - ribbon; e - ring

It is from the shape (through the shape coefficient x = 1 + 2с,/2в + + 2е ( /2с and the relative burning surface a = -^/b 1,), as well as on the dimensions (through the thickness of the burning arch e,) the possibility of using this or that gunpowder in this or that weapon depends. In this case, the determining size is the thickness of the burning vault. Since the powder element burns from both sides, the thickness of the burning arch is usually designated 2c, (c is half the thickness burning in one direction). The shape and size of the powder elements are usually included in the designation of gunpowders. Pyroxylin gunpowder, for example, is designated by a fraction, the denominator of which indicates the number of channels in the powder element, and the numerator indicates the thickness of the arch in tenths of a millimeter. For example, 7/, - a grain of pyroxylin powder of a cylindrical shape with one channel and a dome thickness of 0.7 mm; 12/7 - grain with seven channels and a thickness of 1.2 mm. By changing the shape of the powder elements and their sizes, it is possible to achieve the desired pattern of gas formation during the combustion of gunpowder, the pattern of changes in the pressure of powder gases in the bore of a weapon, and, consequently, the work of powder gases during a shot, which determines the muzzle velocity of the projectile in accordance with the formula

The initial shape of the powder elements determines the change in surface during their combustion. Depending on this, all gunpowder can be divided into three groups:

  • a) gunpowder with a degressive form of combustion;
  • b) powder of progressive combustion form;
  • c) gunpowder with a constant burning surface.

At the gunpowder degressive s/yurma the combustion surface decreases and the ratio Z/U, = a is always less than unity. Such gunpowders include: cubic, spherical, lamellar, belt, ring gunpowder; single-channel and channelless grained. These types of gunpowder are used in short-barreled guns, mortars and small arms. For degressive powders, the ratio of the surface at the end of combustion of the powder to the initial surface, i.e. values ​​st k = 5^/5 are equal to: for lamellar - 0.67; tape - 0.88; ring « 1.0; cubic and spherical - 0; grained channelless - 0.1; grained single-channel - 0.7; tubular « 1.0.

When burning powders progressive form their current surface before the disintegration of the grain increases and then decreases to zero so that o dis = .5 / 5, > 1 and for grained powders of seven-channel cylindrical and petal shapes equals, respectively, 1.378 at y = 0.855 and 1.382 at u = 0.949. Seven-channel cylindrical gunpowder is most widely used. Gunpowders of this form turned out to be the most universal, applicable to many artillery systems and have a clear technological advantage.

To gunpowder with constant burning surface it would be possible to include tubular-shaped gunpowder with armored ends of the tubes. The long tubes of gunpowder are very close to this shape (they have about k * 1.0).

Gunpowder is used in weapons as the main element of artillery and mortar rounds and in small arms cartridges - a powder charge. Bulk charges are made from granular, lamellar and spherical powders, and bundle charges are made from tubular and belt powders. The ignition of the powder elements in the charges does not occur simultaneously. The ignition time of the charge is short compared to the time of combustion of all the powder elements of the charge simultaneously following ignition. The intensity of gas formation during the combustion of such charges is determined by the shape and size of the powder elements: those that are degressive in shape burn with a decrease in intensity; progressive - with increasing intensity; gunpowder with a constant burning surface - with consistency. Grained powders have the advantage over tubular and other forms that they have a high gravimetric density. And this has great importance for weapon systems with small chambers and cartridges, especially for automatic weapons. The disadvantage of grained gunpowder is that it is more difficult and more inconsistent to ignite charges from them. In long charges this can cause lingering shots and pressure surges. Progressive powders provide equal arch thicknesses and composition highest speed projectile. With the same shape of powder elements and constant weight charge, changing the thickness of the arch changes the initial velocity of the projectile in reverse side. This is illustrated by the data in Table. 2.2.

Table 2.2

Addiction initial speed projectile and maximum pressure of powder gases when fired

from the thickness of the burning body of gunpowder

e y mm

Rmax" MPE

From the table 2.2 it follows that when changing e 1 from 1.5 to 2.0 mm, by 33%, r max changes by 42%, and And () - by 9%. Thus, by changing the shape of the powder element and its dimensions, the desired change can be achieved r max And and 0 .

An increase in the work of powder gases during a shot due to progressive gas formation can be achieved not only due to the shape of the powder elements, but also due to the progressive combustion of phlegmatized powders (degressive in shape) and so-called block charges. Block powder charges They are a composition of standard non-deformed small-sized powder elements of cylindrical or spherical shape - a filler and a thermoplastic combustible polymer (polyacrylate, polyvinyl acetate, cellulose acetate, etc.) filling the inter-element volume. To preserve the energy characteristics of the charge, powerful explosives are added to the gunpowder in an amount that compensates for the loss of energy due to the inert combustible binder. The composition is processed into a heterogeneous monoblock block using industrial methods of extrusion, hydropress, and compression pressing using equipment from powder factories. In Fig. Figure 2.4 shows powder monoblocks of powder charges of convective and layer-by-layer convective combustion.


Rice. 2.4. Structure of monoblock powder charges: A- convective combustion charge; b- layered combustion charge

The idea of ​​developing block powder charges (BP3) is based on the ability of porous systems to burn in a layer-by-volume mode using the convective combustion mechanism. When the BPZ is ignited from the end, the flame front propagates at a constant or increasing speed along the length of the charge. During the combustion process, the block naturally disperses to form a suspension. The gradual ignition of the charge in combination with the accumulation of burning suspension ensures high progressiveness of gas formation at a charge density of 1.20 kg/dm. In Fig. 2.5 shows a physical model of combustion of porous BPZ.

The necessary components of the combustible binder material are cellulose nitrates, which provide high physical and mechanical characteristics and charge burning rate. For getting


Rice. 2.5. Physical model of combustion of porous BPZ:

  • 7 - ignition; 2 - layer-by-layer combustion; 3 - transition of layer-by-layer combustion to convective combustion; 4 - developed convective combustion;
  • 5 - decomposition of BPZ into conglomerates and powder elements; 6 - afterburning of powder elements in layer-by-layer mode

For a high burning rate of BPZ at a density of 1.2-1.4 kg/dm 3, it is necessary to have a fibrous structure of cellulose nitrates. To process a mass containing a fibrous component with a high phase transformation temperature, podivinyl butyral (PVB) is introduced into it - a binder with high adhesive ability and a wide raw material base.

Porous structure - necessary condition obtaining fast-burning BPZ, and the high rigidity of macromolecules and supramolecular formations of NC necessitates the use of a solvent to ensure the processability of the mixture.

The solvent should completely dissolve PVB, but not lead to deep plasticization of NC. Ethyl alcohol fully satisfies these requirements. Thus, one of possible compositions the technological mass for obtaining BPZ is as follows (%): filler (powder elements) - 70-80;

cellulose nitrates -10-20;

polyvinyl butyral - 10-15;

ethyl alcohol (removable, over 100%) - 10-12.

The technological properties of the powder mass of this BPZ composition ensure its processing by the through-pressing method on existing PP production equipment. By using pyroxylin powder and powerful crystalline explosives as a filler in the BPZ, it is possible to regulate the burning rate over a wide range and change the ballistic characteristics.

As part of the ongoing modernization of the armed forces, it is proposed to supply not only new technology and, but also various auxiliary means. The other day it became known that the Ministry of Defense plans to eventually switch to using new containers for ammunition. Instead of the usual wooden closures, it is proposed to use new boxes of an original design for storage and transportation.

Deputy Minister of Defense General of the Army Dmitry Bulgakov spoke about plans to switch to new containers for ammunition. According to the deputy minister, next year the military department plans to begin full-scale use of new closures for ammunition. For the foreseeable future, only certain types of shells, etc. will be supplied in new boxes. products. The new closures have already been tested and can now be used by the military.

D. Bulgakov also spoke about some of the features of the new packaging. According to him, the new closures are made from modern materials whose characteristics are superior to wood. The main advantage over existing wooden boxes is fire resistance. The Deputy Minister of Defense explained that thanks to the use of special materials, the new box is capable of withstanding flames of up to 500°C for 15 minutes. This will allow the fire crew to arrive at the fire site in time and prevent Negative consequences fire. Also, the use of new containers will increase the shelf life of ammunition. When placed in storage, the new closure will last approximately 50 years.

General view of the new closure with a projectile

To date, according to D. Bulgakov, military tests two types of new boxes. The military checked containers for artillery shells of 152 and 30 mm caliber. The new type of closures are recognized as meeting the requirements, which opens the way for them to the troops. Based on the test results, it was decided to supply new shells of 30 and 152 mm calibers in new closures.

Soon photographs of promising containers for separately loaded artillery rounds appeared in the public domain. As follows from these photographs, when developing a new container, it was decided to create standardized boxes with the possibility of relatively simple adaptation to specific ammunition. For this purpose, the closure consists of several main parts: a unified box and lid, as well as inserts-cradles in which the “payload” is secured.

The main elements of a promising closure are a special plastic box of a rectangular oblong shape. The dimensions of this product are designed so that it can accommodate various types of ammunition. Thus, photographs show that 152 mm and 122 mm shells can be transported in boxes of the same size with different supports.

The main box and its lid are made of a special composite material, the type and composition of which has not yet been specified. Various assumptions have been made in discussions about closures, but they have not yet been supported by any acceptable evidence. Perhaps the new box is proposed to be made of fiberglass with special additives that increase strength and provide flame resistance. Thus, resistance to heat, including contact with open fire, is ensured, first of all, by the outer “shell” of the closure.

The outer drawer is made of two parts of a similar shape, but different sizes: the lid has a smaller height compared to the main box. To increase the strength and rigidity of the structure, numerous protrusions are provided around the box and lid. There are recesses on the sides of the main box that can be used as carrying handles. The box and the lid are joined together using a protrusion and a recess running along the perimeter of the joint. In this case, the lid is equipped with a rubber seal that seals the container. They are connected to each other using a set of hinged locks. Three such devices are provided on the long sides of the closure, and two on the short sides.

The inside of the box and lid are covered with a layer of fibrous material, which can serve as additional thermal insulation. Thus, the body of the box protects the contents from open fire, and the internal thermal insulation prevents it from overheating. In addition, the thermal insulation probably plays the role of a seal, ensuring a tighter fit of the cradle liner.


Another capping option designed for a smaller caliber projectile

To rigidly fix the payload inside the new closure, it is proposed to use two plastic supports placed in the box and its lid. These products provide recesses of appropriate shapes and sizes into which the projectile and cartridge case or other products supplied to the troops should be placed. The closures shown in the photographs have a curious feature: on the “working” surface of their inserts, next to the main recesses, additional recesses and protrusions are provided. With their help, the correct joining of the cradle is ensured and the prevention of their shift relative to each other.

Currently, there are versions of similar products for several types of artillery shells, and in the future new modifications may appear with updated inserts adapted to accommodate other payloads, up to small arms cartridges, hand grenades etc.

The proposed closure design allows us to successfully solve the main problems of transportation, storage and use of various types of ammunition. The durable plastic outer shell of the box provides protection from mechanical damage, and also, unlike wood, does not burn and can withstand high temperatures During a long time. Sealing the joints prevents moisture from entering the box and thereby protects its contents from corrosion. Finally, there is an advantage in service life. The possibility of using the new closure for 50 years is declared.

New plastic closures for ammunition are expected to replace existing wooden products. For this reason, many discussions of the innovation attempt to compare old wooden and new plastic boxes. At the same time, it turns out that in some cases new closures may indeed be better than old ones, but from the point of view of other features they are inferior to them.

Perhaps the greatest interest is in eliminating wood to solve problems fire safety. Indeed, fires regularly occur in ammunition depots, resulting in the destruction of a large number of shells, as well as the destruction of buildings. In addition, many times during such events people suffered, both military personnel and residents of nearby settlements. For this reason, the fire resistance of the new boxes could be considered a very useful innovation, which, with certain reservations, could even justify the existing disadvantages.

However, the absence of any wooden elements in some situations can turn into a disadvantage. Empty wooden ammunition caps have traditionally been not only a multi-functional container, but also a source of wood. Wooden boxes can be used by troops for a variety of purposes. With their help, you can build some objects, such as dugouts, trenches, etc., and a disassembled box becomes firewood for a fire. Plastic containers can be used for construction, but it will be impossible to keep warm or cook food with it.


Trials by Fire

An important feature of the new closure is its lighter weight. By using relatively thin plastic housings and inserts made of similar materials, significant weight savings can be achieved in comparison with wooden packaging.

When evaluating a new ammunition container, you should consider not only compliance and some additional “consumer characteristics”, but also cost. Unfortunately, on this moment There is no information about the price of new boxes. There is some information about orders for various containers for the armed forces, but this cannot be directly linked to the new boxes. However, it is obvious that promising plastic containers should be noticeably more expensive than traditional wooden ones. How much is still unknown.

Troops have tested two options for new closures this year, according to the Undersecretary of Defense. These products are designed to transport shells of 30 and 152 mm caliber. The tests were completed successfully, which resulted in the decision to use new packaging in the future. Already next year, the armed forces should receive the first batch of artillery shells, packed in new boxes. In addition, there is information about the existence of closures for 122-mm shells, and the design of this product makes it possible to build boxes for other products. Thus, new types of closures may appear in the foreseeable future.

According to the military department, the promising closures fully comply with the requirements and will be supplied starting next year. What will be the pace of supply of new packaging and will it be able to completely replace existing ones? wooden boxes– it’s not completely clear yet. Nevertheless, there is every reason to believe that promising closures will not only be able to reach the military, but also win a prominent place in warehouses from traditional containers.

Based on materials from sites:
http://vz.ru/
http://vpk-news.ru/
http://redstar.ru/
http://twower.livejournal.com/



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