RU136879U1 - SMOOTHING WEAPONS (OPTIONS) - Google Patents

Abstract

1. Smoothbore weapons containing a barrel mounted rotatably in the receiver, in which are located the means for locking the barrel and initiating a shot, as well as the breech of the barrel and its rotation mechanism, characterized in that the barrel is made separately from the breech, which is made in the receiver, while the barrel rotation mechanism is made in the form of an annular gas chamber mounted on it in its rear part with a radial internal partition, and the barrel has a piston and a gas channel communicating inside the barrel cavity and the gas chamber between the baffle and the piston in contact with each other in the initial position, in addition, the weapon has a device for damping the rotational movement of the barrel and the mechanism for returning the barrel to its original position after the shot, made in the form of a tension spring mounted in the receiver along the trunk and the flexible power element in the form of a steel cable, one end of which is connected to the spring, and the other is passed through the block in the receiver and screwed to the trunk around the circumference for at least one turn and fastened with it, while on the outside the barrel has an annular stop mounted between two thrust bearings in the receiver. 2. Smoothbore weapon according to claim 1, characterized in that the annular gas chamber is fixed relative to the receiver with a pin made on the outer surface of the chamber. Smoothbore weapon according to claim 1, characterized in that on the baffle of the gas chamber from the side of the piston of the barrel a reflective bevel is made, into which the gas channel of the barrel opens. Smoothbore weapon according to claim 1, characterized

Description

The proposed utility model relates to smooth-bore weapons, namely smooth-bore firearms and pneumatic throwing devices, where the barrel is rotated to give axial rotation to the projectile to stabilize its translational movement within the external ballistics and can be used in any smooth-bore weapons.

It is known from the prior art that all modern smooth-bore guns, mortars and other types of this type of weapon have a drawback, specifically, the projectile is stabilized in flight due to the complexity and cost of the shells themselves, which also worsens the accuracy of the weapon due to deterioration of aerodynamic characteristics of the shells themselves. As a rule, in smooth-bore weapons, all shells - to give them axial rotation - are equipped with aerodynamic planes, turbine elements and turbines for these purposes, which work from gunpowder gas in firearms or compressed gas - in pneumatic weapons. Also, the spinning of shells in smooth-bore weapons is carried out by rotating the barrel, creating conditions for stabilizing shells within the external ballistics.

In this case, the rotation of the barrel, as a rule, is carried out using the recoil energy of the barrel or the reciprocating motion of the shutter, as well as using drives with the consumption of additional energy, including electricity.

The execution of the barrel rotating allows to exclude helical cutting in the barrel, to overcome which a significant proportion of the energy of the projectile is absorbed, and also allows to exclude and simplify the aerodynamic and other additional elements in the design of the shells to stabilize the flight and its axial twist.

Known Automatic gun "Vladimir", RU 2342618 C2, F41A / 06, 06/15/2006, where the barrel with the shutter is made rotating about its longitudinal axis and is equipped with a drive that provides rotation. In this case, synchronously, relative to the rotating barrel, there is a drive for rotating the cartridge before it is sent to the breech of the barrel.

The disadvantage of this solution is the significant complication of weapons due to the use of volatile barrel rotation drives, cartridge rotation and an additional mechanism for removing a cartridge from a feed magazine or tape to reinstall it into a rotation drive, which makes the weapon unreliable due to the complexity of additional drives and barrel rotation synchronization and drive rotation of the cartridge, and the lack of electricity leads to a complete disruption of weapons.

It is also known "Automatic small arms", RU 2064152 C1, F41A 5/06, 05/25/1992, which contains a barrel mounted with the possibility of rotation in the receiver, on which a sleeve with a curved groove is mounted. The shutter is made with reciprocal elements located in the groove to ensure reciprocating shutter movement from the rotation of the barrel, where, at the moment of shot from the pressure of the powder gases, the shutter begins to move backward, interacting with a curved groove of the barrel, while the barrel acquires a rotation pulse in the bearings of the receiver. Continuing the rotation by inertia, the barrel carries the bolt forward with a new cartridge, filed from the feeder-store. At the moment of the complete closure of the chamber shutter, the next shot occurs, and the cycle repeats.

Based on the totality of features, this technical solution was adopted as a prototype of the claimed utility model.

The disadvantage of this technical solution is that using recoil or moving the shutter to rotate the barrel and, accordingly, the projectile in it is inefficient, because the barrel is rotated through a curved groove that interacts with the counter element on the shutter; an impulse to rotate the barrel follows the impulse of the start of the shutter movement from the operation of the powder charge; the shutter begins to move after exiting the rest state; and a projectile in a smooth barrel always has a much greater rectilinear speed of movement than the speed of rotation of the barrel and the rectilinear movement of the shutter, connected by a curved groove, due to the difference in their total mass to the mass of the projectile. Therefore, by the time the shutter begins to move and, accordingly, the barrel rotates, the projectile will leave the barrel.

The objective of the utility model is to ensure the spin of the projectile simultaneously with the beginning of its movement in the barrel, and with an angular velocity of rotation of the barrel comparable to the velocity of the projectile in the barrel, as well as simplifying and facilitating the design of the barrel and the weapon as a whole.

The technical result from the use of the utility model is that for guaranteed twist of the projectile, about one turn of the barrel is enough, as well as the cessation of barrel rotation at the moment of leaving the projectile of the muzzle of the barrel, which generally ensures stability of the accuracy characteristics of the weapon.

In another embodiment, the model additionally created the possibility of firing with a spin and without spinning the projectile (if necessary).

Since the projectile in a smooth barrel always has a speed during a shot that is faster than in a rifled weapon, therefore it is enough to twist less “cool”, i.e. about one revolution of the barrel with an angular velocity comparable to the velocity of the projectile in the barrel is enough.

The specified technical result is achieved due to the fact that the smoothbore weapon in the first embodiment includes a receiver with a barrel mounted thereon on radial bearings. In this case, the barrel has an annular stop interacting with two thrust bearings in this receiver; the breech of the barrel with a shutter is made in the receiver; between the breech of the barrel and the barrel itself there is a labyrinth or other seal. An annular gas chamber mounted on the outer rear of the barrel is fixed with a trunnion relative to the receiver; in the cavity of the gas chamber there is a partition with a reflective bevel; there, in the cavity, there is a piston, made in conjunction with the barrel or mounted on it.

A gas channel is made from the inside of the barrel into the annular gas chamber. An annular gas chamber between its outer surface and the receiver has a gap that is connected to the atmosphere through drainage windows in the receiver; between the cavity of the gas chamber and the gap there are also drainage windows; there are gaskets between the barrel and the annular gas chamber. A flexible power element is wound on the barrel itself, fixed to it by one end; its other end is passed through the block on an axis in the receiver and secured with the end of the tension tensile spring which, in turn, is located in the receiver, along it and fastened to it by the other end. In the receiver there is a groove for the unhindered passage of a flexible power element that is wound on the barrel; on the rear side of the barrel, on the inside, there is a lead-in chamfer that allows the shell to freely enter the smooth barrel when loading a weapon. To exclude piston impacts on the baffle when the barrel is rotated in the cavity of the gas chamber, there are damper elements on them; for the manufacturability of the device, the receiver can be made of two halves with their subsequent fastening.

In the second embodiment, the smoothbore weapon comprises a receiver with a barrel mounted thereon on radial bearings. In this case, the barrel has an annular stop interacting with an axial clearance with two thrust bearings in the receiver; on the front side of the annular stop there are blind cylindrical windows in which pusher glasses with return springs are installed, compressing the annular stop with the barrel to the rear thrust bearing, forming a spring-loaded gap between the annular stop and the front thrust bearing; the breech of the barrel with a shutter is made in the receiver; however, between the breech of the barrel and the barrel itself there is a labyrinth or other sealant. On the trunk — outside the receiver — an annular bandage with a sear handle with a supporting surface is mounted and fixed; on the receiver mounted combat emphasis with a bevel; in the same place an emphasis limiter of combat rotation of the barrel with a damper.

A flexible power element is wound on the barrel itself, fixed to it by one end; its other end is passed through a block on an axis in the receiver and is fastened to the end of a tension tensile spring which, in turn, is located in the receiver, along it and fastened to it by the other end. At the rear end of the barrel there is, on the inside, a lead-in chamfer that allows the shell to freely enter the smooth barrel when loading a weapon.

For the manufacturability of the device - the receiver can be made of two halves with their subsequent fastening.

The technical result provided by the given set of features is to increase the accuracy of smooth-bore weapons by improving the aerodynamic characteristics and simplifying the design of shells and eliminating aerodynamic planes, turbines and other elements from them, designed to stabilize and axial spin in flight. Which leads to a decrease in the linear dimensions of these shells and, as a result, will lead to an increase in ammunition in armored vehicles and in other artillery systems.

The technical result is also to simplify the design of the barrel with a simultaneous decrease in its mass due to the execution of the breech of the barrel with a shutter in the receiver, and the barrel rotation options allow the proposed utility model to be used on various types of smooth-bore weapons, both firearms and pneumatic, including also classic mortars.

The device according to the first embodiment is illustrated by drawings, where in FIG. 1 shows a general view of a smooth-bore weapon before a shot in a section with indication of sections Α-A, BB; in FIG. 2 shows a section A-A according to FIG. 1, which shows a flexible power element on the barrel and on the block in the receiver; in FIG. 3 shows a section BB in FIG. 1, which shows an annular gas chamber with a baffle and a barrel piston, as well as a damper on the barrel piston and a baffle.

The proposed smoothbore weapon (Fig. 1) according to the first embodiment contains a receiver 1 with a barrel 2 installed therein with an axial axial stop 3. The barrel 2 is installed in the receiver 1 in radial bearings 4 and 5, as well as in ring thrust bearings 6. Treasury part 7 of barrel 2 is made in the receiver 1. From the inner smooth part 29 of barrel 2, a gas channel 8 is made into an annular gas chamber 9 with an internal cavity 31 and with a radial partition 13 (Fig. 3). The gas chamber 9 is attached to the receiver 1 by a pin 11. The cavity 31 of the gas chamber 9 has drainage windows 12 that are in communication with a gap 44 between the gas chamber 9 and the receiver 1. The gap 44 is connected to the atmosphere by drainage windows 17 in the receiver 1. Gas chamber 9 has a radial partition 13 in the cavity 31 (FIGS. 1, 3) with a reflective bevel 16 and a damper blind hole 15; on the outer part of the barrel 2 there is a piston 10 with a damper piston 14. Between the gas chamber 9 and the outer part of the barrel 2 there is a seal 18; between the barrel 2 and its breech 7, made in the receiver 1, a gasket 19 is installed. In the receiver 1 there is a service spring 20 (Fig. 1, 2) fixed in it by one end 26, and its other end has a fastening 25 s a flexible power element 21, which is passed through a block 23 on the axis 24 and screwed onto the barrel 2 with a mount 22 on it; to freely locate the power element 21 on the barrel 2 in the receiver 1, a groove 43 is made. In this case, before the shot, the projectile 27 with the sealing ring 28 is in the smooth initial part 29 of the barrel 2, where there is also an entry chamfer 30. When the receiver 1 is made of two parts (Fig. 2) there is a joint 32 of these parts and their fastening 33.

The device according to the second embodiment is illustrated by drawings, where in FIG. 4 shows a general view of a smooth-bore weapon - before a shot, in a section with the indication of sections B-B, D-D and type G; in FIG. 5 shows a cross-section BB in accordance with FIG. 4, which shows the handle-sear of the barrel on the combat support and the flexible power element, as well as the symbol of the handle-sear on the support-limiter, the arrow "Z" - the direction of combat rotation of the barrel and the arrow "I" - the direction of cocking the combat spring with the handle-sear ; in FIG. 6 shows a view D in accordance with FIG. 4, which shows the handle-sear of the barrel on the combat support and the stop-limiter of rotation of the barrel; section DD from FIG. 4 is shown in FIG. 7, which shows the annular emphasis of the barrel, in the receiver and the front flat parts of the spring-loaded pushers.

The proposed smoothbore weapon (Fig. 4) according to the second embodiment comprises a receiver 1 with a barrel 2 installed therein with an axial axial stop 3. The barrel 2 is installed in the receiver 1 on radial bearings 4 and 5, as well as on ring thrust bearings 6. Treasury part 7 of the barrel 2 is made in the receiver 1. In the annular emphasis 3 of the barrel 2 is made on the front side, blind holes with return springs 41 installed in them with push rods 42. On the barrel 2, outside the receiver 1, the handle-sear 36 is installed with support surface 39 (Fig. 5, 6), fastened to the barrel 2 by a bandage 34. On the receiver 1 there is a combat stop 35 with a bevel 40 and a stop-limiter 37 with a damper ring 38. In the receiver 1 (Fig. 4, 5) is installed a combat spring 20, fixed at one end 26 in it, and 25 a flexible power element 21, passed through a block 23 on the axis 24 and screwed onto the barrel 2 with a mount 22 on it, is fixed to the other end of the combat spring 20. At the same time, before firing, the projectile 27 with the sealing ring 28 is located in the smooth initial part 29 of the barrel 2, where there is also a lead-in facet 30, and a sealant 19 is installed between the barrel 2 and its breech 7, made in the receiver 1. the receiver 1 of two parts (Fig. 7) on it there is a junction 32 of these parts and their fastening 33.

The mechanisms of shutter, opening and closing it, firing a shot, absorbing recoil energy, sending and extracting cartridges of propellant charges, or a pneumatic shot valve in a pneumatic version of a weapon - in FIG. 1, FIG. 2, FIG. 3, FIG. 4, FIG. 5, FIG. 6, FIG. 7 - not shown and partially located in the breech of the barrel, made in the receiver, and the missile itself is fed into the initial part of the smooth barrel (Fig. 1, 4).

Smoothbore weapons in the first embodiment (Fig. 1, Fig. 2, Fig. 3), works as follows. To load weapons, it is necessary to introduce a projectile 27 with a propelling charge into the breech 7 of the barrel 2.

The projectile 27 (Fig. 1) with a sealing ring 28, located in the initial smooth part 29 of the barrel 2, after triggering a propellant powder charge, or pneumatic valve, in a pneumatic weapon, which are located in the breech of the barrel, made in the receiver (not shown) , begins to move from a state of rest to the muzzle of the barrel 2. At the initial stage of dispersal of the projectile 27, gas, powder or compressed, enters through the gas channel 8, in the wall of the barrel 2 (Fig. 1, 3) into the cavity 31 of the gas annular chamber 9, mounted on barrel 2 and fastened This trunnion 11 with the receiver 1, and, reflected from the bevel-reflector 16 on the radial baffle 13 in the annular gas chamber 9, exerts pressure on the piston 10, made on the barrel 2. The barrel 2 - together with the piston 10 - turns into gas pressure of radial bearings 4 and 5, in the receiver 1, as well as in the thrust bearings 6, with which the annular stop 3 of the barrel 2 interacts. As the projectile 27 moves along the smooth surface 29 of the inner part of the barrel 2, the barrel rotates and turns onto its outer part fixed 22 on her power g a large element 21, pulls the mainspring 20, which is fixed at one end 26 in the receiver 1 and its other end 25 is attached to the power flexible element 21, which through the block 23, on the axis 24 in the receiver 1 around the circumference of the outer part of the barrel 2 not less than one turn (Fig. 12). The barrel, continuing to rotate, from the gas pressure on the piston 10, continues to cock the war spring 20, winding on itself a flexible power element 21.

As the barrel 2 with the piston 10 rotates, air from the cavity 31 of the gas chamber 9 is displaced through the drainage windows 12, (Figs. 1, 3) in the gas chamber, while air from the drainage windows 12 enters the gap 44 between the gas chamber 9 and the receiver 1 and, airing this gap, is released into the atmosphere through the drainage windows 17 in the receiver 1.

When the projectile 27 reaches the muzzle end of the barrel 2, the rotation of the barrel is stopped, and the piston 10 of the barrel 2 with its damper piston 14 (Fig. 1, 3) enters the window of the damper 15 on the partition 13 of the gas chamber 9, thereby eliminating the impact of the piston 10 on the partition 13. At the same time, the projectile 27, having received axial rotation from the rotation of the barrel 2, leaves its muzzle. The gas pressure in the barrel drops, and the pressure drops on the piston 10 of the barrel 2, the mainspring 20 through the power flexible element 21, mounted on the barrel 2, rotates it to its original position, i.e. the barrel 2 with the piston 10 rotates in the opposite direction and abuts with its working surface against the partition 13 in the gas chamber 9. At the same time, atmospheric air is sucked into the cavity 31 of the gas chamber 9 through the drainage windows 12 and 17 (Figs. 1, 3), ventilating and cooling the gas chamber 9, and the powder gases are displaced by the piston 10 into the barrel 2 through the gas channel 8, which also dampens the rotation of the barrel to its original position.

To eliminate the loss of working gas during a shot between the gas chamber 9 and the barrel 2, it is possible to install seals 18, and between the rear end of the barrel 2 and its breech 7, made in the receiver 1, it is possible to install a seal 19 (Fig. 1).

For free winding and reeling on the barrel 2 of the flexible power element 21, the combat spring 20, in the receiver 1 is made of an annular inner bore 43.

For the next shot, the smoothbore weapon is reloaded. In the breech 7 of the barrel 2, made in the receiver 1, is introduced the following missile with a propelling charge. In this case, after loading, the projectile 27 should be in the initial smooth part 29 of the barrel 2, and the propellant or pneumatic valve should be in the pneumatic weapon, in the breech of the barrel. For high-quality entry missile projectile in the initial part 29 of the smooth barrel 2 when loading inside the barrel, from the side of the rear end made a chamfer 30.

After triggering a propellant charge, or pneumatic valve, and at the beginning of the movement of the projectile 27 in the barrel 2, the process of rotation of the barrel, and hence the spin of the projectile, is repeated.

Smoothbore weapon according to the second embodiment (Fig. 4, Fig. 5, Fig. 6, Fig. 7) works as follows. To load a weapon, it is necessary to introduce a missile projectile 27 with a propelling charge into the breech 7 of the barrel 2. For the handle-sear 36, which is located at the stop-limiter 37 (Fig. 5) with damper 38, turn (in the direction of arrow - I) manually or another the way the barrel 2, before the handle-whispered for the stop 35 (Fig. 5, 6), while the spring is pulled (cocked) 20 (Fig. 4) through the flexible power element 21.

The projectile 27 (Fig. 4) with a sealing ring 28, located in the initial part 29 of the smooth barrel 2, after triggering a propellant powder charge, or pneumatic valve, in pneumatic weapons, which are located in the breech part 7 of the barrel, made in the receiver 1 (not shown), starting from a standstill to a muzzle end due to friction against the inner surface of the projectile barrel 27 and its sealing ring 28, causes the barrel 2 to move in the direction of the projectile movement within the gap between the ring stop 3 of the barrel 2 and the bottom thrust bearing 6, compressing the return springs 41 of the plunger cups 42 located in the blind windows of the front of the annular stop 3 of the barrel 2. The barrel 2, passing the gap between its annular stop 3 and the front thrust bearing 6, compressing the return springs 41 of the plunger 42 shifts the annular bandage 34 fixed on it with the handle-sear 36 from the combat stop 35 (Figs. 4, 5, 6). The barrel 2 begins to rotate (in the direction of the arrow - 3) in the radial bearings 4 and 5 and the thrust bearings 6 due to the pre-cocked war spring 20 (Fig. 4), which is fixed at one end 26 in the receiver 1 and attached to the other end 25 a flexible power element 21, which, through a block 23 on the axis 24, in the receiver 1, surrounds the circumference of the outer part of the barrel 2 with at least one turn and is attached 22 to it. Therefore, when removing the handle-sear 36 from the support 35 with its support surface 39, the combat spring 20, being cocked (tensioned), rotates the barrel 2 (Fig. 5) through a flexible power element mounted on it.

At the time of the projectile 27 exit from the muzzle of the barrel 2, the rotation of the barrel stops, and the handle-sear rests on the stop-limiter 37 (Fig. 5, 6) of the combat rotation of the barrel 2, on which there is a damper 38. Projectile 27, having received axial rotation due to rotation of the barrel 2, leaves it.

For the next shot smoothbore weapons (Fig. 4) is recharged. In the breech 7 of the barrel 2, made in the receiver 1, is introduced the following missile with a propelling charge. Moreover, after loading, the projectile 27 should be in the initial smooth part 29 of the barrel 2, and the propellant, or pneumatic valve, in pneumatic weapons, in the breech of the barrel. If the twist of the projectile is necessary, the barrel 2 by the handle-sear 36 (Fig. 5) is rotated (in the direction of the arrow - I) manually or in another way from the stop-limiter 37 towards the combat stop 35 (Fig. 5, 6), while on the barrel 2, a flexible power element 21 mounted on it is wound, pulling (cocking) a war spring 20 fastened with it (Fig. 4). Continuing to rotate the barrel 2 with the handle-sear 36 until it contacts the bevel 40 (Fig. 6) on the support 35, where it slides along the inclined surface of the bevel 40, moving the barrel 2 forward, while the return springs 41 (Fig. 4) are compressed pushers 42 (Fig. 4, 7). After passing through the handle-sear 36 for the combat stop 35, it, with its supporting surface 39 (Fig. 5, 6), is mounted on the combat stop 35, and the return springs 41 of the pusher glasses 42 shift the barrel towards its breech-end - to the end of the ring stop 3 of the barrel 2 into the rear thrust bearing 6 in the receiver, leaving the handle-whisper 36 on the cocking cock, and the mainspring 20 cocked (tensioned).

After triggering a propellant charge, or pneumatic valve, the process of turning the barrel, and therefore - the twist of the projectile will repeat.

If the spin of the projectile is not required, then the handle-sear 36 is not cocked and remains at the stop-limiter 37 (Fig. 5).

To eliminate the loss of working gas during firing, it is possible to install a seal 19 (Fig. 4) between the breech portion 7 of the barrel, made in the receiver 1, and the rear end of the barrel 2 itself. And for high-quality entry of the projectile into the initial part 29 of the smooth barrel 2 when loading inside the barrel from the side of the rear end is made an entry chamfer 30.

The utility model according to the first and second options allows axial spin of the projectile by rotating the barrel on any type of smoothbore weapon, including classic mortars, and the absence of external drives for rotating the barrel, consuming electric energy or recoil force, including the movement of a movable bolt, makes it possible to have a weapon more reliable and simpler, as well as simplified and lightened barrel design and weapons in general. At the same time, shells according to the utility model are simplified in design due to the possible elimination of aerodynamic and other elements of projectile stabilization in flight and, accordingly, the cost of shells and their linear dimensions are reduced, which will improve firing accuracy by improving their aerodynamic shapes, which will also increase ammunition to artillery systems, including armored vehicles.

Claims (12)

1. Smoothbore weapons containing a barrel mounted rotatably in the receiver, in which are located the means for locking the barrel and initiating a shot, as well as the breech of the barrel and its rotation mechanism, characterized in that the barrel is made separately from the breech, which is made in the receiver, while the barrel rotation mechanism is made in the form of an annular gas chamber mounted on it in its rear part with a radial internal partition, and the barrel has a piston and a gas channel communicating inside the barrel cavity and the gas chamber between the baffle and the piston in contact with each other in the initial position, in addition, the weapon has a device for damping the rotational movement of the barrel and the mechanism for returning the barrel to its original position after the shot, made in the form of a tension spring mounted in the receiver along the trunk and the flexible power element in the form of a steel cable, one end of which is connected to the spring, and the other is passed through the block in the receiver and screwed to the trunk around the circumference for at least one turn and fastened with it, while on the outside the barrel has an annular stop mounted between two thrust bearings in the receiver. 2. Smoothbore weapon according to claim 1, characterized in that the annular gas chamber is fixed relative to the receiver with a pin made on the outer surface of the chamber. 3. Smoothbore weapon according to claim 1, characterized in that on the baffle of the gas chamber from the side of the piston of the barrel a reflective bevel is made into which the gas channel of the barrel opens. 4. Smoothbore weapon according to claim 1, characterized in that the device for damping the rotational movement of the barrel is made in the form of a blind bore on the baffle of the gas chamber and a reciprocal cylindrical piston on the piston of the barrel. 5. Smoothbore weapon according to claim 1, characterized in that the non-working part of the cavity of the gas chamber is communicated by drainage windows with a gap between the gas chamber and the receiver, which is connected to the atmosphere by additional drainage windows in the receiver. 6. Smoothbore weapon according to claim 1, characterized in that between the barrel and its breech there is a seal, for example, a labyrinth. 7. Smoothbore weapon according to claim 1, characterized in that at the entrance to the barrel from the inside there is an entry chamfer for projectile entry. 8. Smoothbore weapon according to claim 1, characterized in that the piston of the barrel is made integral with it. 9. Smoothbore weapons containing a barrel mounted rotatably in the receiver, in which are located the means for locking the barrel and initiating a shot, as well as the breech of the barrel and its rotation mechanism, characterized in that the barrel is made separately from the breech, which is made in the receiver, and the barrel rotation mechanism is made in the form of a tension spring installed in the receiver along the barrel and a flexible power element in the form of a steel cable, one end of which is connected to the spring, and d the coal was passed through the block in the receiver and rotated around the circumference by at least one turn and fastened with it; in addition, the barrel has an annular stop on the outside, mounted between two thrust bearings in the receiver, and relative to the front bearing, with a clearance axial movement of the barrel during firing, while on the front side, blank cylindrical windows are made in support along the barrel, in which pusher glasses are installed with return compression springs installed in them, pressing open to the rear thrust bearing, in addition, an annular bandage with a sear handle is fixed on the barrel outside the receiver, and a combat emphasis with an entry bevel is installed on the receiver, as well as an emphasis limiter for the combat rotation of the barrel, while the gap between the annular emphasis and the front thrust the bearing is selected from the condition of the descent of the handle-sear in combat support with its minimum forward movement during firing. 10. Smoothbore weapon according to claim 9, characterized in that the pusher glasses are made with flat outer ends. 11. Smoothbore weapon according to claim 9, characterized in that the stop-limiter is made in the form of a cylindrical rod equipped with a damper, in the form of a ring of elastic material mounted on it. 12. Smoothbore weapon according to claim 9, characterized in that the gap between the front thrust bearing and the annular stop of the barrel is made equal to 1.5-3 mm.

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