RU138948U1 - AMMUNITION "SMERCH" FOR FIRING WEAPONS - Google Patents

Abstract

1. An ammunition containing a bullet, a sleeve with a capsule and a propellant charge, while the propellant charge consists of at least two parts made of components with different burning speeds and with the possibility of their sequential ignition and burning from slowly burning components to quick-burning components , while the bullet is mounted in a sleeve with an interference fit, characterized in that, in order to increase the accuracy of shooting and armor piercing of the ammunition, the main part of the propellant charge of the ammunition is placed in the cartridge sleeve, and the other part is m The detonating charge is placed in a cylindrical booster block located along the axis of the munition with an emphasis on the central, bottom part of the sleeve and in the bottom of the bullet, while the booster block is made of several steps in the form of thin-walled cups with an internal conical bottom, where there are ignition holes, and on the outside parts of the stages of the booster block, in addition to the first from the bottom of the sleeve, there are grooves from the bottom for installing each step in the previous step of the booster block with an interference fit, and the first, from the bottom of the sleeve, the step of the booster block it has a thickened conical bottom, in which there are radial holes filled with compacted gunpowder and extending into the central pilot hole, with its exit to the stage cavity, and the stage of the booster block itself is filled with a part of the propellant charge, but with a higher burning rate than the main part of the propellant charge in sleeve, and the next stage of the booster block is filled with a powder component of the propellant charge with a higher burning rate than in the previous stage of the booster block, while this stage is also performed

Description

The utility model relates to ammunition for small arms and artillery weapons, in which an initial speed of 1300 m / s is given to give the enemy effective use in armored vehicles and bulletproof vests, as well as to defeat the enemy at a great distance, bullet or projectile (hereinafter bullet). and above, for which, as a rule, the special design of the bullet or the cartridge as a whole is used, while maintaining the standard dimensions and geometric external parameters of the ammunition.

The prior art in the field of ammunition with a high initial velocity of a missile bullet shows that the issue of increasing the speed of a bullet has arisen almost since the appearance of rifled weapons, but the founders of real solutions in this area are Karl Puff (Russian patent No. 14214 of 08/27/1908) and German Gerlich (US patent No. 1944834 from 01/30/1934). G. Gerlich’s patent shows that, developing the ideas of K. Puff, he proposed making the rifle barrel conical, with rifling in it of regressive depth and progressive steepness (the pitch of the rifling decreased as it approached the muzzle), and the Gerlich’s bullet had two leading belts interacting with rifling. All these measures gave a more complete obturation of the bullet (elimination of breakthrough of powder gases) when moving along the barrel and unrelenting resistance to the increase in pressure of powder gases, which made it possible to achieve the maximum possible speed for a handgun, and therefore its energy. Moreover, in some prototype weapons, an initial speed of 1600-1700 m / s was achieved. with a bullet weight of 6.5 g.

But Gerlich’s rifles were never put into service, with rare exceptions, due to technological problems in the manufacture of conical trunks and special rifling in them.

It is known that increasing the speed of bullets increases the accuracy of shooting and increases the armor-piercing ability of these bullets. The higher the initial speed, the more closely the bullets “lie down”, the less the lead that is necessary when shooting at moving targets, which means that the less is the error from inaccuracy in determining the speed and direction of movement of the target.

It is known that if a bullet containing no explosive charge moves at a speed of about 1300 m / s. and more, when it hits a barrier, a large amount of thermal energy is released and a bullet with fragments of the barrier acquires incendiary-dynamic properties comparable to a kinetic explosion, which creates an additional striking characteristic.

It is known that in modern types of barrel firearms, as well as in newly developed ones, they prefer to use standard (spent) ammunition in terms of external geometric parameters, which creates conditions for the predictability of the internal ballistics of the weapon barrel and makes the excess safety factor of the barrels obvious, and this is the main reserve for development new types of ammunition. So, in a standard ammunition, 7.62 × 54R, (Fig. 2), after the capsule is triggered, the main pressure of the propellant propellant gases is achieved in the preliminary and initial path of the bullet’s movement, where after ignition of the propellant charge and cutting the bullet’s shell into the grooves of the barrel, the bullet accelerates with a rapid drop in gas pressure in the barrel due to the lag of the gas expansion rate from the bullet velocity in the increasing back space, because the movement of gases in the barrel is actively throttled by the barrel channel, and the external region is and the gas is still actively slowed down by its laminar layer interacting with the inner surface and the grooves of the barrel, and the limits of the elastic resistance of the barrel allow a higher gas pressure - but this does not imply a significant increase in the propellant charge, because it would have to change the design of the weapon by increasing the thickness of the barrel walls in its breech and strengthen the bolt.

The well-known "Cartridge with an active-reactive bullet" (patent RU No. 2107886, F42B 5/10, 02.16.1996), which contains a sleeve, propellant charge, an igniter capsule and an active-reactive bullet consisting of a head part in the form of a shell with a core and a jet engine, including a housing with slotted nozzles, a powder charge of the engine, while the jet engine nozzles are located radially in front of its housing, and on the outer surface of the rear of the jet engine housing there is a turbine for imparting rotation and stabilization of the bullet to a tive-trajectory. In this case, the bullet head part is provided with a jacket, the shell of the bullet is made with an obturator.

This technical solution involves a relatively high initial velocity of the bullet when the propellant and the jet engine are triggered, as well as the possibility of further increasing the speed of the bullet after departure from the barrel due to the operation of the jet engine.

However, the proposed cartridge design has a very bulky bullet, because, after the jet engine is fully activated, it continues to fly with its empty casing, which significantly increases the aerodynamic drag of the bullet.

In this case, the working jet engine of the bullet, when it is still in the barrel, also works as a propellant charge, only with a slowdown due to the gradual outflow of gases through slotted nozzles, which will significantly reduce the initial velocity of the bullet. And the operation of a jet engine of a bullet on its flight path and the interaction with the air-gas medium of its turbine at the end of a jet engine creates the prerequisites for unstable flight at a heading due to the heterogeneity of the turbulent air-gas medium interacting with the bullet, engine block and turbine, and also, on the rear bottom of the jet engine of the bullet, a vacuum is created during its movement, which also actively inhibits the translational movement of the bullet. These main disadvantages of the described design create conditions for reducing the range of the aimed shot and worsen the accuracy i.e. complex aerodynamic flow around the bullet length with jet nozzles in the front and turbine protrusions at the end of the bullet does not allow an increase in the bullet’s flight speed and improved firing accuracy, moreover, this will lead to a “yaw” of the bullet in the course.

Closest to the claimed technical solution is the "Cartridge with a reactive bullet" (RU No. 2372581, F42B 5/10, 11/26/2008) - a prototype that is a sleeve with a capsule and located with a gap to the inner surface of its bottom bullet with an inner the cavity in which the propellant charge and the hole in the form of a nozzle are placed, while the propellant charge consists of several parts made of components with different burning speeds and completely placed in the bullet cavity with the possibility of their sequential ignition and burning from a slower but the burning of components to quickly burning components. In this case, the cavity in the pool is made parabolic or in the form of a truncated cone, and the nozzle is made in the form of a calibrated hole. And also the propellant charge is divided into parts by easily combustible partitions.

This technical solution involves increasing accuracy and accuracy of the battle of weapons with a simultaneous increase in the initial velocity of the bullet.

Performing a propellant charge of several parts with different burning rates provides a smoother increase in the pressure of powder gases with an increase in the volume of the back of the room.

However, when the whole propellant charge is in the cavity of the bullet, and this cavity has a jet nozzle and, moreover, the propellant charge is separated by combustible baffles, the bullet will actually have a slower acceleration in the barrel channel than in a regular cartridge of this type, i.e., the primary pulse is excluded high pressure propellant charge, and there is a rapid sequential burning, which will lead to a longer time of the shift of the bullet from the rest state and the time of leaving the chamber. And when there is no initial high-pressure pulse (~ 3000 kg / cm ² ), the bullet throwing from the barrel will be a certain average pressure due to temporary losses in the bullet jet nozzle and the time spent on burning combustible partitions between parts of the propellant charge.

After leaving the muzzle of the barrel, a cartridge reactive bullet with a burning propellant charge immediately receives a factor of instability in the course of flight due to the occurrence of a reduced pressure zone, after the propellant is fully triggered, in an empty bullet body when its jet nozzle is the bullet bottom and is created on the back of the bullet, in addition to turbulence, there is a deep discharge of air, and with a relatively large volume of the bullet cavity, the discharge will be prone to self-oscillating changes, which will lead to an active brake a decrease in the bullet’s flight and its instability along the course, and this will affect a decrease in accuracy and firing range, and the increased weight of the bullet, due to the material of the cavity under the propellant charge, will not allow the bullet to achieve flight speed, like a similar bullet with a standard cartridge.

The objective of the claimed utility model is to increase the effectiveness of ammunition by expanding the means to obtain a high initial velocity of the bullet.

The technical result provided by the utility model is to increase the damaging properties of the ammunition by increasing the initial velocity of the projectile bullet to 1300 m / s. and higher, which will increase the armor-piercing, range and accuracy of fire.

The problem is solved due to the fact that in the claimed utility model there is a sleeve, usually a bottle, capsule, propellant charge, and propellant charge consists of several or at least two parts made of components with different burning speeds and the possibility of their sequential ignition, while the bullet is mounted in a sleeve with an interference fit, and parts of the propellant charge are in the sleeve and in successive stages of the booster unit. The proposed technical solution is a standard unitary cartridge (for example, a cartridge of 7.62 × 54R with a bullet weighing ~ 10 grams, a barrel with a length of 620 mm. SVD rifles), where the propellant charge is divided into several parts. Moreover, the main part of the propellant propellant charge (for example: smokeless pyroxylin powder, grade VT with a loading density of 0.87 g / cm ³ ) is in the sleeve, and the other part of the charge is in several steps of the accelerating unit installed, from the bottom of the sleeve to the bottom of the bottom ammunition bullets. The stages of the booster block are thin-walled cups with a conical bottom inside, in which there are firing holes. Moreover, the first-lower step to the bottom of the cartridge case (the vertical position of the munition is considered to be the bullet at the top) of the booster block has an external conical surface of the bottom, and it is centered on the axis of the cartridge case with the conical protrusion of the bottom against the central part of the cartridge case zone. And the very bottom of the stage is made thickened and conical inside, where there are radial ignition openings filled with compacted powder, moreover, these ignition openings communicate with the central ignition opening extending into the stage cavity. The stage cavity itself is filled with a powder component with a higher burning rate than the main part of the propellant charge in the sleeve.

The next, second stage of the booster block is made in the form of a thin-walled cup on the conical bottom of which a cone pilot hole is made, closed by a stopper from compacted gunpowder, moreover, the step with its outer groove from the bottom side is installed with an interference fit into the open part of the first stage of the booster block, and its outer part the bottom is made coaxially concave with a pilot hole in the center. The cavity of the second stage of the booster block is filled with a powder component with a higher burning rate than in the first stage.

If it is necessary to further increase the speed of the bullet, the next stage of the booster block is installed, similar to the previous, second stage, which also consists of a thin-walled glass with a conical ignition hole, on the conical bottom of the glass a closed stopper from compacted powder and with an external groove in this zone, which this stage installed with an interference fit in the open upper part of the previous stage of the upper stage, moreover, the outer part of the bottom of the stage is made coaxially concave with the ignition hole in the center.

The stage cavity is filled with a powder component with a higher burning rate than in the previous second stage of the upper stage. The charge in the stage cavity is closed by a thin quickly combustible baffle-wad, and in the open part of this stage of the booster unit an adapter with a central hole in the form of a Laval nozzle is fitted with an interference fit, and in the upper part of the adapter adapted for the bottom of the bullet (this type of cartridge and bullets), the bottom of the bullet is installed.

The first stage of the booster block and the entire assembly of steps of the booster block, as well as the adapter with the bullet, abut against the central part of the capsule zone of the sleeve (the notch of the “anvil” capsule) of the munition. Each stage of the booster block and the entire assembly of steps of the booster block with an adapter has an outer diameter equal to the caliber of the weapon (barrel), and the material from which the steps of the booster block and adapter are made is similar to the material from which the cartridge cartridges for weapons are used, where the claimed technical solution is used and with a bimetallic outer surface, including the shell of the bullet, namely, with cladding tompak, but when installing more than two stages of the booster block - cladding, mainly to produce sulfur bromine or gold, to reduce friction in the bore.

The technical result provided by the given set of features is the improved use of the pressure of the powder gases of the propellant charge of the ammunition as the bulging space increases when the bullet moves along the barrel, which allows maintaining high pressure of the powder gases directly behind the bullet along the entire length of the barrel. In this case, the high pressure in the barrel does not exceed the ultimate elastic resistance of the barrel along its entire length. This makes it possible to obtain a high initial velocity of the bullet without increasing the propellant charge and changing the aerodynamic forms of the bullet itself and, as a result, the overall ammunition efficiency is increased.

The ammunition according to the claimed utility model is illustrated in FIG. 1, which shows a sectional view of the ammunition showing its main elements: a cartridge case with a capsule and a bullet, as well as a propellant charge located in the cartridge case and in the steps of the booster block; in FIG. 2 shows a graph of the pressure distribution in the ammunition space using standard ammunition, depending on the speed of the bullet. In FIG. 3 shows a graph of the pressure in the barrel when using the proposed utility model, as well as the limits of the elastic resistance of the barrel and the initial velocity of the bullet obtained in this case, and at points A, B, C on the graph of pressure in the barrel, the zones (in the barrel) of operation of the stages of the booster block are indicated . In FIG. 4 depicts a photograph of an affected armor plate and ammunition cartridges "Tornado".

Ammunition "Tornado" for firearms, figure 1, includes a bullet 1 connected to a sleeve 2 in which there is a capsule and the main part of the propellant charge 4, and the other part of the propellant charge is in the steps of the booster unit 30; the first is the lower stage 5 with a thickened conical bottom 6 and the same conical bottom-protrusion 7 from the outside; in the thickened bottom 6 of step 5 there are made radial firing holes 8 extending into the central firing hole 9 on the bottom 6 of step 5, and the radial firing holes 8 are filled with compacted powder 10, and the internal cavity of the step 5 is filled with part of the propellant propellant charge 11, and into the open part of the first stage 5 of the booster unit 30, the second stage 12 of the booster unit 30 is installed with its groove 13 in the bottom part with a conical surface 14, and in the central part of the bottom 14 there is a pilot hole 15 closed by a plug 16 from the compacted porosity a, and the internal cavity of the second stage 12 is filled with a part of the propellant charge 17, and in the open part of the stage 12 of the booster unit 30, the stage 18 of the booster unit 30 is installed with its groove 19 on the conical bottom part 20, and in the central part of the bottom 20 there is a firing hole 21 closed by a plug 22 of compacted gunpowder; the inner cavity of the stage 18 is filled with a part of the propellant charge 23 closed with the open part of the stage 18 with a thin easily combustible wad 24, an adapter 25 is installed in the same open part of the stage 18 with its outer groove 26, and the upper part of the adapter has an adapted surface 27 under the bottom of the bullet 1, and in the central part of the adapter 25, along its axis, the nozzle hole elements 28 and 29 are made. In FIG. 3, the pressure graph in the barrel, point “A” is shown — the place of actuation of part of the propellant charge 11 in stage 5 of the booster unit 30, point “B” is the place where the part of the propellant charge 17 of stage 12 of the booster unit 30 is shown, and at point “B” "- shows the place of operation of part of the propellant charge 23 in the stage 18 of the booster unit 30.

The device operates as follows. Given that the claimed utility model solves the issue of the most rational use of propellant charge energy during a shot so that a bullet of a given weight and caliber reports a certain initial high speed while observing the strength characteristics of the barrel - the main part of the propellant charge 4 (Fig. 1) works sleeve 2 after actuation of the capsule 3, and in the barrel of the weapon (Fig. 3, 1), parts of the propellant charge (Fig. 1) 11, 17, 23 which are in steps 5, 12, 18, of the booster block 30 and sequentially play Amen create, zapulnoe high pressure on the pressure graph (FIG. 3) zones A, B, C. In this firing process (acceleration bullet in the barrel) takes 0.001-0.005 seconds. and occurs in a sequential algorithm. From striking the striker on the capsule 3 (Fig. 1), the cartridge case 2, the shock composition of the capsule explodes and a flame is formed that penetrates the main part of the propellant charge 4 and ignites it, while the compacted powder 10 is ignited and burns with a delay in the radial holes 8 stage 5 of the booster unit 30. When the main part of the propellant charge 4 is burned in the sleeve 2, a large amount of heated gases is generated, creating high pressure (Fig. 3) to the bottom 7 of the first stage 5 of the booster unit 30 and part of the bottom of the bullet 1, as well as to the bottom and the walls of the sleeve 2. As a result tate gas pressure to the bottom 7 of step 5 and part of the bottom of the bullet 1, the entire assembly of steps (Fig. 1) 5, 12, 18, adapter 25, bullet 1 - are displaced and bullet 1 cuts into the grooves of the barrel, rotating and moving along the channel barrel, and the steps 5, 12, 18, adapter 25 move with the bullet 1 as their outer diameter is equal to the caliber of the barrel. At a distance of 60-100 mm, from the beginning of the rifling of the barrel, it works with a cumulative effect, due to the bottom cone 6, the propellant charge 11 (Fig. 3, zone A) in stage 5 of the booster unit 30 due to its ignition after the flame exits into the central ignition hole 9, burning with a delay of compacted gunpowder 10 in the radial holes 8 of stage 5. The case of stage 5, when part of the propellant charge 11 is triggered, starts to lag behind bullet 1 with adapter 25 and stages 12, due to the pressure of the gases formed, in front of it 18 creating a pressure impulse towards the smallest its resistance in the direction of movement of the bullet 1, while the case of the stage 5 begins to restrain the expansion of powder gases from the operation of the main part of the propellant charge 4 while maintaining their elasticity and pressure, and also creating conditions for a more complete combustion of this main part of the propellant charge 4. After the complete operation of the propellant charge 11, heated gases burn the plug from the compacted gunpowder 16 in the ignition hole 15 of the stage 12 of the booster block 30 and at a distance of 150-250 mm., from the beginning of the barrel rifling, it works with a cumulative effect volume due to the conical bottom 14, part of the propellant charge 17 (Fig. 3, zone B), while creating the main impulse of gas pressure in the direction of movement of the bullet 1 forms a moving elastic medium between the bodies of steps 12 and 5, and the bottom of the sleeve 2. After the full throwing of the propellant charge 17 in step 12 (Fig. 1), it is burned the plug of compacted gunpowder 22 in the ignition hole 21 of the stage 18 of the accelerating block 30 and at a distance of ~ 400 mm., from the beginning of the rifling of the barrel, the propellant charge of stage 23 is triggered (Fig. 3, zone B), while the actuation of the charge 23 occurs with a cumulative effect due to the conical bottom 20.

When the propellant charge 23 is triggered in stage 18, the cumulative gas stream breaks through the thin quickly combustible wad 24 and, accelerating in the nozzle 28, 29 of the adapter 25, creates the main gas-dynamic pressure pulse at the bottom of bullet 1 giving it maximum speed (Fig. 3). After the bullet 1 takes off from the barrel of the weapon and ends after the action of gases, the casing of steps 5, 12, 18 and the adapter 25 fly out of the barrel and, having no aerodynamic streamlined shapes, soon fall at a distance safe for the shooter. In the proposed utility model, steps 5, 12, 18, of the booster block 30 (Fig. 1), with their parts of the propellant charge, do not increase the total propellant volume, but create conditions for the formation of dynamic high-pressure pulses in a limited volume, directly to the barrel, in side of the bullet 1 with their sequential (Fig. 3, zone A, B, C) operation. Moreover, when any stage of the booster block 30 is triggered, the previous (spent) stage cannot stop due to the moment of inertia and the impossibility at the “nano” time, to change the direction of rotation since the spent case bodies actively interact with the rifling of the barrel due to their clamping the walls to the rifling of the barrel with common bullet pressure and pulse pressure in front of them, while the pressure immediately behind the stage bodies continues to accelerate them in the direction of the bullet movement. And since dynamic pulses are mainly directed towards the bullet, as the direction of least resistance, and any previous stage casing moves in the same direction, the operation of each next stage of the booster block increases the speed of the bullet in the barrel without the expense of energy for cutting the shell the bullet into the rifling of the barrel and its acceleration from a state of rest, that is, almost all the energy of the propellant charge in each stage of the booster block is spent on increasing the speed of the bullet, this shows that the use of Ammunition IPASA allows you to use 60-80% of the energy of the propelling charge, in the stages of the booster block, for the message of the translational motion pool (main job) at the same time is considered the norm, when 25-35% of the allocated energy of the propelling charge is spent on accelerating the bullet in the barrel, and 15- 25% of the energy is spent on minor works (cutting the bullet shell into the barrel rifling and overcoming friction of the bullet when moving along the barrel, heating, moving the moving parts of the weapon) and about 40% of the energy is not used and is lost after the bullet leaves the barrel.

In the proposed utility model, it is permissible, due to the high speed in the barrel of the last (in front of the bullet) stage 18 of the booster block 30 to charge it not only with gunpowder with a high burning rate of 23, but also with explosive with a burning speed of up to 6000-8000 m / s., which is safe for the barrel, since at the moment the charge is triggered, bullet 1 and stage 18 are already moving in the barrel at a speed of more than 1000 m / s. (Fig. 3), and this exceeds the rate of elastic deformation through the entire thickness of the barrel due to the movement of the deformation zone along the barrel with a speed that does not allow to complete this deformation and destroy the barrel, and all the energy, almost a shock wave, will be directed to accelerate the bullet, while the nozzle 28, 29 (Laval nozzle) in the adapter 25 allows you to concentrate the density of the gas shock wave at the bottom of the bullet, additionally creating the conditions for obtaining a high initial velocity, which increases the efficiency of the shot and guarantees damage to the chain.

During the development of the Smerch Ammunition based on the standard 7.62 × 54R cartridge with a bullet weighing 10 grams, with a steel core and a cermet core based on tungsten carbide, firing was carried out, which showed (averaged) positive results:

- muzzle velocity 1500-1700 m / s - sighting range 3000-3500 m - defeat of "manpower" 5000-6000 m - defeat lightly armored vehicles 1000-1500 m - defeat of "manpower" equipped with personal protective equipment 1000-1500 m - damage to the steel sheet (St.45) with a thickness of 50 mm. 300 m

Moreover, the hit of a Smerch ammunition bullet for a firearm in a "live force", as a rule, causes amputation injuries (a mannequin made of polyurethane grade TPU-2T).

Claims (9)

1. An ammunition containing a bullet, a sleeve with a capsule and a propellant charge, while the propellant charge consists of at least two parts made of components with different burning speeds and with the possibility of their sequential ignition and burning from slowly burning components to quick-burning components , while the bullet is mounted in a sleeve with an interference fit, characterized in that, in order to increase the accuracy of shooting and armor piercing of the ammunition, the main part of the propellant charge of the ammunition is placed in the cartridge sleeve, and the other part is m The detonating charge is placed in a cylindrical booster block located along the axis of the munition with an emphasis on the central, bottom part of the sleeve and in the bottom of the bullet, while the booster block is made of several steps in the form of thin-walled cups with an internal conical bottom, where there are ignition holes, and on the outside parts of the stages of the booster block, in addition to the first from the bottom of the sleeve, there are grooves from the bottom for installing each step in the previous step of the booster block with an interference fit, and the first, from the bottom of the sleeve, the step of the booster block it has a thickened conical bottom, in which there are radial holes filled with compacted gunpowder and extending into the central pilot hole, with its exit into the stage cavity, and the stage of the booster block itself is filled with part of the propellant charge, but with a higher burning rate than the main part of the propellant charge in sleeve, and the next stage of the booster block is filled with a powder component of the propellant charge with a higher burning rate than in the previous stage of the booster block, while this stage is also performed and in the form of a thin-walled cup with a conical bottom and with a central pilot hole in the bottom, closed by compacted powder, the next step similar to the previous one is installed in this stage of the booster block, similar to the previous one, in the form of a thin-walled cup with a conical bottom and with a central ignition hole in this bottom compacted gunpowder, and the stage cavity is filled with a component of the propellant charge with a higher burning rate than in the previous step, and the propellant charge of the step is closed from the open part of the thin, quickly combustible with a partition-wad, also on this side of this stage an adapter is installed with an interference fit, with its outer groove, in the central part of which there is an opening in the form of a Laval nozzle, and the adapter on the side of the bullet has an adapted surface under the bullet bottom where the bullet bottom is installed, creating an interference between the bottom of the bullet, all the stages of the booster block, the adapter and the bottom of the sleeve. 2. The ammunition according to claim 1, characterized in that the outer diameters of all stages of the booster block and the outer diameter of the adapter are equal to the caliber of the weapon barrel. 3. The ammunition according to claim 1, characterized in that when using more than two stages of the booster block, cladding of the outer surface of all stages of the booster block, adapter and bullet shell is performed not only with a tompack, but with silver or gold to reduce friction in the barrel bore. 4. The ammunition according to claim 1, characterized in that the bottom in each stage of the booster block is conical, to create a cumulative effect when part of the propellant is triggered in the steps of the booster block, moreover, the total cone bottom angle is from 140 ° to 60 °. 5. The ammunition according to claim 1, characterized in that the stage of the booster block closest to the bottom of the bullet can be equipped not only with a quick-burning powder component, but also with an explosive like trimethylenetrinitroamine, with a burning speed of up to 6000 - 8000 m / s. 6. The ammunition according to claim 1, characterized in that the central ignition openings closed with compacted gunpowder in the second stage from the liner, the stages of the booster block and in other subsequent stages of the booster block can be conical, with a common angle to the previous stage from 1 ° to 70 °. 7. The ammunition according to claim 1, characterized in that the outer surfaces of the bottom parts of all stages of the booster block, except for the first from the bottom of the sleeve, are made coaxially concave with firing holes in the center. 8. The ammunition according to claim 1, characterized in that the central firing holes in the stages of the upper stage are made with a diameter, in a smaller section, from 0.5 to 3.0 mm. 9. The ammunition according to claim 1, characterized in that when the booster block is made up of the required number of steps, a rapidly combustible partition is always installed in the step in front of the bullet bottom - wad closing the charge and with its outer groove an adapter with an adapted surface under the bullet bottom and with a central hole in the form of a Laval nozzle.

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