WO2010086676A2

WO2010086676A2 - Method for the all-round improvement of the military and operating characteristics of a rifled gun and a rifled gun barrel

Info

Publication number: WO2010086676A2
Application number: PCT/GE2010/000001
Authority: WO
Inventors: Виталий АБРАМЯН; Константин АБРАМЯН; Вианор АБРАМЯН; Рональ АБРАМЯН
Original assignee: КУКХАЛЕЙШВИЛИ Рати
Priority date: 2009-01-30
Filing date: 2010-01-27
Publication date: 2010-08-05
Also published as: RU2010102326A; RU2011135991A; WO2010086676A3; GEP20146092B; RU2486426C2

Abstract

The invention relates to a method for the all-round improvement of the military and operating characteristics of a rifled gun and to a rifled gun barrel device. The method consists in displacing compressed air into the space behind the projectile via discontinuous and/or longitudinal inclined grooves, into which the air is forced. The discontinuous grooves increase the pressure of the air to a pressure greater than that of the explosive gases. Once the groove is opened, the air is released into the space behind the projectile, slowing the fall in pressure of the explosive gases. Compressing the air either in a portion or in all of the discontinuous grooves to a pressure less than that in the space behind the projectile makes it possible for the explosive gases to enter a groove and expand and also permits an impact on the wall of the groove. The rifled barrel contains discontinuous grooves which are longitudinal and/or longitudinal and inclined. The inclined longitudinal grooves run along the rifling. The discontinuous grooves are formed in the barrel channel, staring from the section where the bullet enters the rifling. The result is an increase in the initial velocity of the bullet and in the accuracy of fire, and a reduction in the report, the heating of the barrel and the recoil.

Description

METHOD FOR COMPREHENSIVE IMPROVEMENT OF BATTLE AND OPERATIONAL CHARACTERISTICS OF THE THREADED WEAPON AND THE BARBER OF THE THREADED WEAPON ABRAHAMYAN

The invention relates to rifled small arms, in particular, it is intended to improve the technical characteristics of rifled small arms, but can also be used in the field of artillery.

There is a method of increasing the initial velocity of a bullet in a rifled weapon by increasing the mass of gunpowder, which allows to increase the resulting force imparting forward movement to the bullet (V. P. Kostenko “Bullets for smooth-bore hunting weapons.” Handbook, Moscow, Publishing House of the Ruchenkin, 2001, p. 178).

The disadvantage of this method is the increased consumption of gunpowder, an increase in the pressure of powder gases and the return of weapons. The prototype of one of the objects of the invention (method) selected a method of comprehensively improving the combat and operational characteristics of rifled weapons, in which they increase the initial velocity of the bullet, the accuracy of the battle, reduce the sound level of the shot, heat the barrel and return the weapon by moving it into the projectile space in the channel barrel in front of a bullet of air, which is passed between the surface of the leading part of the bullet and the surface of the barrel channel through various forms of recesses (slots, grooves) in it, for example p longitudinal and / or oblique-longitudinal grooves made in the fields between the grooves and / or oblique-longitudinal grooves made in part or in all grooves by increasing the cross-sectional area of the groove, and in the section of the bore with the pressure of the powder gases in the shell space exceeding the pressure of compressed air at the bullet’s shoulder, the movement of compressed air into the projectile space is carried out by intermittent recesses, into which, using the overlap-opening of the air passage into the recess, the leading part of the bullet in the process its movements in the barrel channel, inject air through the sharply final tip of the bullet while moving the bullet shoulder along the recess, stop pumping after the recess is completely blocked by the leading part of the bullet, and, after opening the recess with further movement of the bullet, transfer air to the projectile space, and in the area the bore of the barrel with a pressure of powder gases less than the pressure of compressed air at the shoulder of the bullet, the movement of compressed air into the projectile space is carried out through intermittent longitudinal and / or oblique-longitudinal, and / or through continuous oblique-longitudinal grooves, and discontinuous grooves are placed after the section of the bore, on which the process of cutting the bullet into the grooves when firing is completed, and to the point where the apex of the bullet stops injecting compressed air into the grooves the muzzle section, and continuous oblique longitudinal recesses are located after the section starting from which the pressure of the powder gases at supersonic speed of the bullet can become lower than the air pressure at the shoulder of the bullet, and to the same place at the muzzle with Assuming that intermittent recesses, the initial speed is increased, decreasing the drag force of the air by moving it into the projectile space after the process of cutting the bullet into the rifling, reducing the friction force between the bullet and the barrel bore by reducing the friction surface in the grooves, and, when the pressure of the powder gases is less than the pressure of the compressed air at the shoulder of the bullet, slowing down the pressure drop of the powder gases in the projectile space due to the arrival of compressed air from the barrel bore, the sound level is the relays are reduced, and the accuracy of the battle is increased, preventing the formation of a “ballistic wave cotton” when the bullet takes off, the temperature of the powder gases and barrel heating are reduced by moving less heated air than the powder gases into the projectile after the bullet has been inserted (WO 2008/090385 Al )

The disadvantage of this method is the incomplete use of its capabilities for the comprehensive improvement of the combat and operational characteristics of rifled weapons, since it focuses mainly on increasing the initial velocity of the bullet. Famous rifle barrel - Mosin rifles of the 1991/191 Ogoda sample, caliber -7.62mm, rifle length without bayonet-1304mm, mass-4.2kg, muzzle velocity -880m / s. and Mosin rifles of the 1991/1930 model, caliber 7.62mm, rifle length without bayonet-1227mm, mass-3.8kg, muzzle velocity - 865 m / s. (The journal "Technique-Youth", Ns 5, 1990, p.40). The elongated rifle barrel of the 1991/1910 model increases not only the initial velocity of the bullet, but also the mass of the weapon, which is a drawback for small arms.

The prototype of one of the objects of the invention (device) selected barrel rifled weapons with helical rifling on the inner surface barrel, with intermittent grooves, longitudinal and / or oblique in the fields between the rifling and / or longitudinally inclined, cut into parts or all rifling by increasing the cross-sectional area of the rifling, located after the completion of the process of cutting the bullet into the rifling during firing and to the point where the apex stops the injection of compressed air into the grooves at the muzzle end or, at the same time, with continuous longitudinally inclined grooves made in the fields between rifling and / or rifling similarly to intermittent , and located after the bullet reaches the supersonic speed and to the same place at the muzzle end as the discontinuous grooves, or with the said discontinuous grooves located before the continuous grooves, and the projection of the length of the discontinuous grooves on the longitudinal axis of the gun barrel is less than the length of the leading part bullets (WO 2008/090385 A1).

The disadvantage of a rifle barrel selected by the prototype is that it gives priority to increasing the initial velocity of the bullet, and when considering other characteristics, such as barrel heating, the recoil of the weapon is not provided.

The technical result of the invention is a comprehensive improvement in the combat and operational characteristics of it — an increase in the initial velocity of the bullet, accuracy of the battle, a decrease in the recoil of the weapon, heating of the barrel and a decrease in the level of the sound of the decree of the shot.

The essence of the invention is a method for comprehensively improving the combat and operational characteristics of rifled weapons, in which they increase the initial velocity of the bullet, the accuracy of the battle, reduce the sound level of the shot, heat the barrel and return the weapon by moving it into the projectile space of the air in the barrel channel in front of the bullet, which pass between the surface of the leading part of the bullet and the surface of the bore through various forms of recesses (slots, grooves) in it, for example longitudinal and / or oblique - longitudinal grooves made in the fields between the grooves and / or oblique longitudinal grooves cut into parts or all grooves by increasing the cross-sectional area of the groove, moreover, in the section of the bore channel with the pressure of powder gases in the projectile space exceeding the pressure of compressed air at the shoulder bullets, the movement of compressed air into the projectile space is carried out by intermittent recesses into which, using overlap-opening of the passage air into the recess by the leading part of the bullet in the process of its movement in the barrel channel, inject air through the pointed tip of the bullet while moving the shoulder of the bullet along the recess, stop pumping after the recess is completely blocked by the leading part of the bullet, and, after opening the recess with further movement of the bullet, transfer air to space, and in the section of the bore with the pressure of the powder gases less than the pressure of compressed air at the shoulder of the bullet, the movement of compressed air into the space is carried out through an intermittent recesses and / or through continuous oblique longitudinal recesses, moreover, discontinuous recesses are located after the section of the barrel channel at which the process of cutting the bullet into the grooves when firing is completed, and to the point where the apex of the bullet stops pumping compressed air into the recesses at the end of the barrel, and continuous incline - longitudinal recesses are located after the section starting from which the pressure of the powder gases at supersonic speed of the bullet can become lower than the air pressure at the shoulder of the bullet, and to the same place at the muzzle end as intermittent recesses, The initial speed is increased by reducing the drag force of the air by moving it into the projectile space after the process of cutting the bullet into the rifling, reducing the friction force between the bullet and the bore due to the reduction of the friction surface in the notches, and, when the pressure of the powder gases is less than the pressure of compressed air at the shoulder of the bullet, slowing down the pressure drop of the powder gases in the projectile space due to the arrival of compressed air from the barrel, the sound level of the shot is reduced, and the accuracy of the battle is they prevent the formation of a “ballistic wave cotton” when the bullet takes off, the temperature of the powder gases and barrel heating are reduced by moving less heated air than the powder gases into the projectile after the bullet is inserted into the grooves, while reducing the drag and air temperature of the powder gases and heating the barrel is carried out after the process of embedding the bullet into the rifling, or start earlier, letting air into the projectile space during the embedding bullets into rifling, in intermittent recesses increase air pressure to a pressure exceeding the pressure of the powder gases, and after opening the recess, release air into the projectile space, slowing the pressure drop of the powder gases and further increasing the initial velocity of the bullet, or, to reduce recoil of the weapon and further reduce barrel heating the air is compressed in part or in all discontinuous recesses to a pressure lower than in the casing space, which ensures the entrance to the recess of the powder gases, their expansion with decreasing temperature, and also a dynamic impact on the recess wall used as a muzzle brake, and different air pressure in recesses blocked by a bullet are obtained by performing a threaded barrel with recesses of different volumes, and in grooves made by rifling, in addition, air pressure is additionally increased in the process of overlapping the leading grooves By means of a bullet, the movement of compressed air into the projectile space is carried out through discontinuous longitudinal and / or oblique longitudinal and / or transverse recesses located in the fields between the grooves and / or intersecting the grooves and / or adjacent to the grooves, and / or through the cut along the grooves, the oblique-longitudinal grooves, and the grooves adjacent to the grooves or intersecting the grooves, should not impair the function of the grooves, and discontinuous oblique-longitudinal grooves made in the fields between the grooves or intersecting the grooves, they blow in the direction of the rifling and / or against, preventing or reducing the action on the weapon of the torque that occurs when the bullet rotates along the rifling, and also formed by the reaction of a jet of air or powder gases when they enter the groove, provide obturation of the powder gases throughout the barrel bore, positioning continuous and intermittent recesses to the point where the tip stops pumping compressed air into the recesses at the end of the barrel, or, to further reduce the sound level of the shot, some of the powder gases are released from the barrel channel before the bullet leaves it, passing them through intermittent or continuous grooves made immediately before the muzzle cut, and the length of these intermittent grooves does not depend on the length of the leading part of the bullet.

The proposed method for the comprehensive improvement of the combat and operational characteristics of rifled weapons is carried out in the rifled barrel described below.

A rifle barrel with helical rifling on the inner surface of the bore, with intermittent grooves, longitudinal and / or oblique-longitudinal in the fields between the rifling and / or longitudinally inclined, cut into parts or all rifles by increasing the cross-sectional area of the rifling located after completion area the process of cutting a bullet into rifling during firing and to the point where the apex of the bullet ceases to inject compressed air into grooves at the end of the barrel, or with continuous longitudinally inclined grooves made in the fields between rifling and / or rifling similarly discontinuous, and located after places where the bullet exceeds supersonic speed and to the same place at the muzzle end as intermittent grooves, or with said intermittent grooves located up to the mentioned continuous grooves, and the projection of the length of the intermittent grooves the longitudinal axis of the gun barrel is less than the length of the leading part of the bullet, while intermittent grooves are made longitudinal and / or oblique-longitudinal and / or transverse in the fields between the rifling and / or adjacent to the rifling from the side of the wall, on which the leading part of the bullet has less impact and / or intersecting grooves and / or inclined longitudinal grooves are made in grooves or, in this case, intermittent grooves are made in the bore of the barrel starting from the site of cutting a bullet into grooves, intermittent inclined longitudinal grooves made in the fields between two grooves or intersecting grooves are located in the direction of the grooves and / or in the opposite direction, and the volume of intermittent grooves must ensure that all oncoming air is moved into the casing space and is compressed in the groove to the pressure necessary to obtain the desired technical result, to ensure the entire length continuous and intermittent grooves are made to the channel of the barrel of the obturation of powder gases until the cessation of injection of compressed air by the tip of the bullet into the grooves at the end of the barrel, or further reducing the shot sound level by release of propellant gases from the bore before departure bullets, intermittent or continuous groove made directly to the muzzle, with the length of the discontinuous grooves is not dependent on the length of a leading part of a bullet.

In the rifle barrel, discontinuous longitudinally inclined grooves intersecting the rifling can be continuously intersecting them, and the depth of some or all of the intersections of the groove with the rifling should be equal to the depth of the rifling, and the groove between the two intersections with the above depth to provide an obturation of the powder gases should overlap the leading part of the bullet.

To reduce the recoil of weapons at the end of the rifled barrel, in the fields between the rifling, intermittent recesses can be made, the walls of sides of the muzzle end, performing the function of a muzzle brake, are perpendicular to the direction of the jet of powder gases.

Many embodiments of the method and execution of the rifled barrel due to a variety of calibers, a different range of pressure of the powder gases, different initial speeds and the designation of rifled barrels for small arms or artillery.

The grooves are designed to move compressed air through them from the barrel in front of the bullet into the projectile space. At the same time, they reduce the friction surface between the bullet and the barrel bore wall, reduce the friction force and increase the initial velocity of the bullet. With decreasing volume a of the groove, the air compression in it increases and vice versa.

The pointed tip of the bullet during the movement of the bullet in the barrel channel throws air to the shoulder of the bullet and part of it is pumped into the grooves, which at that moment the shoulder of the bullet is aligned. After the bullet reaches supersonic speed, the discharge intensity increases significantly.

The place where the bullet reaches supersonic speed is determined analytically or experimentally.

Various versions of the rifled barrel are represented by 12 figures: FIG. 1 - A longitudinal section of a section of the bore of a rifled weapon barrel with intermittent grooves in the fields between rifling, made immediately before the muzzle cut, and a section of the barrel bore with intermittent grooves in the fields between rifling, made in the section of cutting a bullet into rifling.

FIG. 2 is a cross-section along A-A in FIG. 1. FIG. 3 - Cross section along BB in FIG. one.

FIG. 4- A longitudinal section of a section of the barrel channel of a rifled weapon with intermittent grooves cut along the rifling directly to the muzzle end and a section of the barrel channel with intermittent grooves cut through the rifling at the site of cutting a bullet into rifling. FIG. 5 is a cross section along AA in FIG. 4. FIG. 6 is a cross-section along BB in FIG. 4. FIG. 7 - A longitudinal section of a section of the end of the barrel with intermittent grooves that perform the function of a muzzle brake. FIG. 8 - A longitudinal section of a section of the trunk with intermittent grooves adjacent to the rifling. Fig.9 is a longitudinal section of a section of the barrel with intermittent grooves intersecting the rifling. Figure 10 - A longitudinal section of a section of the barrel with intermittent grooves, continuously crossing the rifling. Fig.11 is a longitudinal section of a section of the bore with continuous grooves located in the fields between the rifles; Fig.12 is a longitudinal section of a section of the bore with continuous grooves cut into rifles.

The barrel of a rifled weapon 1 with helical grooves 2 on the inner surface of the bore 1, with discontinuous transverse and / or longitudinal and / or oblique-longitudinal grooves 3 and / or with continuous longitudinal and / or oblique-longitudinal grooves 4, made in the fields 5 between grooves 2 and / or adjacent to the grooves 2 from the side of the wall, on which the leading part b of the bullet 7 has less impact, and / or intersecting grooves 2, and / or with intermittent oblique longitudinal grooves 8 and / or with continuous oblique longitudinal grooves 9 you olnennymi on part or all of the rifling 2 by increasing the cross-sectional area rifling

2, and the intermittent grooves 3 and 8 are made starting from the site of cutting 10 of the bullet 7 into the grooves 2, and to the point where the tip 11 stops pumping 7 bullets 7 of compressed air into the grooves of 3.8 at the end of the barrel 1 or directly to the muzzle 12, and the continuous grooves 4 and 9 are located after the bullet 7 reaches supersonic speed and to the same places at the end of the barrel 1 as the discontinuous grooves 3 and 8, the discontinuous oblique longitudinal grooves 3, made in the fields 5 between the grooves 2 or intersecting the grooves 2, are located along the direction of the grooves 2 and / or against, moreover m, the total volume of intermittent grooves 3 and 8 should ensure the movement of all oncoming air into the projection space 13, taking into account its compression in the grooves 3 and 8, to a pressure providing the required technical result. The projection of the length of the discontinuous groove 3 or 8 on the longitudinal axis of the barrel 1 is less than the length of the leading part 6 of the bullet.

Intermittent longitudinally inclined grooves 3 intersecting the grooves 2 can be made continuously intersecting them, and the depth of part or all of the intersections of grooves 3 with grooves 2 is equal to the depth of grooves 2, and the section of groove 3 between two intersections with the above depth for providing obturation of powder gases should be blocked by the leading part 6 of the bullet.

At the end of the rifled gun barrel, intermittent recesses 3 can be made in the fields between the rifling 2, the walls of which from the muzzle end 12, which perform the function of the muzzle brake, are perpendicular to the direction of the powder gas stream.

The method is carried out in the process of a shot from a rifled weapon as follows:

With the beginning of the movement of the bullet 7 in the channel of the barrel 1 of the rifled weapon, air is compressed in front of the bullet 7, which is thrown back by the tip of the bullet 11 and is pumped into one or at the same time into several discontinuous grooves 3.8, made from the site of cutting 10 of the bullet 7 into the grooves 2 , or into the same grooves made after the site of cutting the bullet 7 into the grooves 2. As the volume of the projectile space increases, the pressure of the powder gases decreases, and the pressure of the compressed air in front of the bullet increases. With the acquisition of a supersonic velocity bullet, the compression intensity increases sharply. In the boundary layer of air adjacent to the pool, in which the movement of air particles changes from the speed of the bullet to zero, the vibrational movements of the air particles formed from the collision of air with the bullet cause sound waves that cannot overtake the bullet, but run onto each other and form a wave of very densified air -

"ballistic wave." This boundary layer of air continues to be discarded by the tip 11 of the bullet 7 to the shoulder 14 of the bullet. When the bullet patch14, moving in the bore, aligns with the beginning of the discontinuous groove 3 or 8, the top of the bullet injects compressed air into the discontinuous groove, which continues until the surface of the leading part 6 of the bullet completely covers the groove 3 or 8 and closes the air passage into the groove from the channel barrel 1. In this case, all the oncoming air pumped into the intermittent grooves is compressed, depending on the volume of the grooves, to a smaller or greater pressure than in the behind projectile space.

With further movement of the leading part 6 of the bullet along the intermittent groove 3 or 8, a passage opens from the protruding space 13 into the intermittent groove, and when the compressed air pressure in the groove exceeds the pressure in the protruding space 13, compressed air leaves the grooves in the slug space and slowing down the pressure drop of the powder gases, and when the compressed air pressure is less than the pressure in the slug space 13, the powder gases enter the groove with expansion and with decreasing temperature. Slowing the pressure drop in the projectile space further increases the initial velocity of the bullet, and the expansion of the powder gases at the entrance to the groove reduces the temperature of the powder gases and barrel heating. In addition, the dynamic impact of the powder gases on the front wall of the intermittent recess 3, as a muzzle brake, reduces the recoil of the weapon. Moving air from the barrel to the projectile space, regardless of the pressure in the recess, reduces air resistance to the movement of the bullet and increases its initial speed, prevents the formation of a “ballistic wave” clap and reduces the sound level of the shot, lowers the temperature of the powder gases and reduces barrel heating. The movement of air into the projectile space begun at the site of the bullet cutting into the rifling reduces air resistance from the moment the bullet begins to move and further increases the initial velocity of the bullet.

To maximize the initial velocity of the bullet, the volume of the grooves should be minimally necessary for moving all the air in the bore of the barrel, starting from the section where the bullet cuts into the grooves. In this case, the air pressure in the intermittent groove maximizes, which, after the bullet reaches supersonic speed and the pressure drops in the projectile space, can exceed the pressure of the powder gases, and the air outlet from the groove slows down the pressure drop in the projectile space. To reduce the recoil of the weapon and further reduce the heating of the barrel, increase the volume of the grooves and thereby reduce the air compression in it, setting the level of air pressure in the groove below the pressure level of the powder gases. Grooves to further reduce barrel heating perform minimally obstructing the longitudinal movement of powder gases, for example, longitudinally oriented grooves, and to reduce the recoil of weapons, discontinuous recesses located at the end of the barrel are used, the walls of which on the muzzle side, which function as a muzzle brake, are perpendicular to the direction of the powder gas stream . In weapons, in which after the section, starting with which the pressure of powder gases at a supersonic speed of the bullet can become less than the air pressure at the shoulder of the bullet, part or all of the grooves can be made continuous. When the air pressure exceeds the pressure of the powder gases, the compressed air moves through the continuous grooves 4 or 9 into the projectile space 13. When firing a burst of automatic weapons after the first shot, instead of air, the spent powder gases that fill the bore are moved to the projectile space.

Depending on the purpose of the weapon, the invented method is used to maximize the initial velocity of the bullet while increasing the accuracy of the battle, lowering the sound level of the shot, reducing the heat of the barrel, or, with an optimal increase in the initial velocity of the bullet, also reduce the recoil of the weapon and further reduce the heating the trunk.

Claims

CLAIM

1. A way to comprehensively improve the combat and operational characteristics of rifled weapons, in which they increase the initial velocity of the bullet, the accuracy of the battle, reduce the sound level of the shot, heat the barrel and

^• return of weapons by moving during the shot into the projectile space of the air in the barrel channel in front of the bullet, which is passed between the surface of the leading part of the bullet and the surface of the barrel channel through various forms of recesses (slots, grooves) in it, for example, longitudinal and / or oblique-longitudinal grooves made in the fields between the grooves and / or oblique longitudinal grooves cut into parts or all grooves by increasing the cross-sectional area of the groove, and in the bore with a pore pressure gas in the projectile space exceeding the pressure of compressed air at the bullet’s shoulder, the compressed air is moved into the projectile space in intermittent recesses, into which, using the overlap-opening of the air passage into the recess, the leading part of the bullet in the process of its movement in the barrel channel, blow air through the pointed peak of the bullet when moving the shoulder of the bullet along the recess, stop pumping after the recess is completely blocked by the leading part of the bullet, and, after opening the recess with further movement of the bullet and, they transfer air into the slug space, and in the section of the barrel channel with the pressure of the powder gases less than the pressure of compressed air at the bullet’s shoulder, the compressed air is moved into the slug space through intermittent recesses and / or through continuous oblique longitudinal recesses, and intermittent recesses are located after section of the barrel channel, on which the process of cutting the bullet into the rifling during the shot is completed, and until the point when the tip stops the injection of compressed air into the recesses at the end of the barrel, and the continuous inclined - longitudinal recesses are located after the section starting from which the pressure of the powder gases at supersonic speed of the bullet can become lower than the air pressure at the bullet’s shoulder, and to the same place at the muzzle end as intermittent recesses increase the initial speed, decreasing the drag force of the air by moving it into the shell space after completion of the process of cutting a bullet into rifling, reducing the friction force between the bullet and the barrel channel due to the reduction of the surface friction in the places of recesses, and, when the pressure of the powder gases is less than the pressure of compressed air at the bullet’s shoulder, slowing down the pressure drop of powder gases in the projectile space due to the supply of compressed air from the barrel, the sound level of the shot is reduced, and the accuracy of the battle is increased, preventing the formation of a “ballistic wave cotton” upon departure, the temperature of the powder gas and heating of the barrel are reduced by moving less heated than powder into the projectile space after the process of cutting the bullet into the rifling gases, air, characterized in that the reduction of the drag of the air, as well as the temperature of the powder gases and the heating of the barrel are carried out after the process of cutting the bullet into the rifling, or start earlier, letting air into the projectile space during the cutting of the bullet into the rifling, in intermittent recesses increase the air pressure to a pressure exceeding the pressure of the powder gases, and after opening the recess, release air into the projectile space, slowing the pressure drop of the powder gases and additional but increasing the initial velocity of the bullet, or, to reduce the recoil of the weapon and further reduce the heating of the barrel, the air is compressed in part or in all intermittent recesses to a pressure lower than in the projectile space, which allows the entrance into the recess of the powder gases, their expansion with decreasing temperature, and also, a dynamic impact on the wall of the recess used as a muzzle brake, and different air pressure in the recesses blocked by the bullet is obtained by performing a rifled barrel with recesses of different volumes, and in the grooves, performed on the cuts, in addition, the air pressure is additionally increased in the process of overlapping the grooves by the leading part of the bullet, the movement of compressed air into the projectile space is carried out through discontinuous longitudinal and / or oblique-longitudinal and / or transverse recesses located in the fields between the grooves and / or intersecting grooves and / or adjacent to grooves, and / or carried out through slanted longitudinal grooves cut through grooves, and grooves adjacent to grooves or intersecting grooves should not deteriorate y of grooves, and discontinuous oblique-longitudinal grooves made in the fields between the grooves or intersecting grooves are positioned in the direction of the grooves and / or against, preventing or reducing the action on the weapon of the torque that occurs when the bullet rotates along the grooves, as well as formed by the reaction of the air stream or powder gases during their entering the groove, provide obturation of the powder gases throughout the bore, positioning continuous and discontinuous recesses to the point where the tip stops pumping compressed air into the recesses at the end of the barrel, or, to further reduce the sound level of the shot, some of the powder gases are released earlier bullets emanating from it, passing them through intermittent or continuous grooves made immediately before the muzzle end, and the length of these intermittent grooves does not depend on the length of the leading part of the bullet .

2. The barrel of a rifled weapon with helical rifling on the inner surface of the bore, with intermittent grooves, longitudinal and / or oblique-longitudinal in the fields between the rifling and / or longitudinally inclined, cut into parts or all rifling by increasing the cross-sectional area of the rifling, located after the site of completion of the process of cutting the bullet into the rifling during firing and to the point where the tip of the bullet stops compressed air into the grooves at the end of the barrel, or, with continuous longitudinally inclined grooves, made in the fields between the rifling and / or rifling similarly intermittent, and located after the bullet exceeded the supersonic speed and to the same place at the muzzle as the intermittent grooves, or with the intermittent grooves located before the continuous grooves, and the projection of the length intermittent grooves on the longitudinal axis of the gun barrel is less than the length of the leading part of the bullet, characterized in that the intermittent grooves are made longitudinal and / or oblique-longitudinal and / or transverse in the fields between the rifle mi and / or adjacent to the rifling from the side of the wall, on which the leading part of the bullet has less impact and / or intersecting the rifling and / or inclined longitudinal grooves are grooved or, in this case, intermittent grooves are made in the bore from the incision section of the bullet into grooves, intermittent oblique longitudinal grooves made in the fields between the grooves or intersecting grooves are located in the direction of the grooves and / or in the opposite direction, and the volume of the intermittent grooves must ensure movement in the core space of all the oncoming air and its compression in the groove to the pressure necessary to obtain the required technical result, to ensure continuous and intermittent grooves throughout the length of the barrel bore of the powder gas obturation, are made up to the point of termination forcing the top of the bullet of compressed air into the grooves at the end of the barrel, or, to further reduce the sound level of the shot by releasing powder gases from the barrel bore before the bullet takes off, intermittent or continuous grooves are made immediately before the muzzle, and the length of these intermittent grooves does not depend on the length of the leading parts of the bullet.

3. The barrel of the rifled weapon according to claim 2, characterized in that the discontinuous longitudinally inclined grooves intersecting the rifling are made continuously intersecting them, and the depth of part or all of the intersections of the groove with the rifling is equal to the depth of the rifling, and the section of the groove between the two intersections with the above depth to ensure the obturation of powder gases must overlap the leading part of the bullet.

4. The barrel of a rifled weapon according to claim 2, characterized in that at the end of the barrel there are made intermittent recesses located on the fields between the rifling, the walls of which from the muzzle end, performing the function of a muzzle brake, are perpendicular to the direction of the stream of powder gases.