RU2578466C2 - Non-cartridge automatic firearm - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to weapons, particularly, to automatic cartridge-free arms. Cartridge-free automatic arms comprise barrel, box with gas discharge channel, pre-barrel part, breech frame, locking wedge, chamber gate, wedge seat, powder cartridge and bullets magazine charger. Bullets and powder are loaded into gun separately in different parts of weapon. Bullets are loaded from bullet magazine charger in pre-barrel part, from where they then moved to barrel. Powder is loaded from powder cartridge in powder receiving chamber, from where then it moves to gunpowder combustion chamber, from where powder gases they enter barrel through chamber gate gas conducting piston where they drive bullet.

EFFECT: possibility to use various ammunition in gun is achieved.

9 cl, 36 dwg

Description

The invention relates to automatic weapons and can be used in all types of automatic weapons: submachine guns, machine guns, light and heavy machine guns, heavy machine guns.

In modern weapons, a unitary cartridge is used. The main disadvantage of a unitary cartridge is the need for a sleeve having a very significant weight (up to 2/3 of the cartridge), requiring a capsule, laborious to manufacture and material intensive. Therefore, the rejection of a metal sleeve promises quite obvious benefits.

Known examples of sleeveless weapons. For example: G11 - a promising assault rifle for shellless ammunition; Italian submachine gun SV-M2 under the caseless cartridge AUPO; automatic sleeveless gun Gerasimenko VAG-73.

All of these systems used shellless ammunition, essentially a shellless cartridge, which is a single construction of gunpowder and bullet.

The well-known 5.56-mm “sleeveless” rifle C30R designed by C. Biordish, the Australian company Armcourt, in which the bullet and powder charge were not integral. The rifle is built according to the “bullpup” scheme with the location of a plastic disk magazine inside the butt. The store itself served as a "sleeve", or rather, a "chamber" for several cartridges: in its 30 sectors radial chambers were made, in which bullets were placed, surrounded by charges of granular powder, and a capsule was placed at the bottom of each bullet. The drummer was located at the axis of the disk, the disk was rotated by a weapon automation system or from the trigger mechanism. Automatic rifle operated due to the recoil of the barrel with a short stroke.

In this system, each bullet, a portion of gunpowder and capsules are located together in a separate sector-chamber, therefore, this system, in principle, could not realize all the advantages that the principle of separation of a powder charge and a bullet in automatic weapon-free weapons gives.

The invention presented here is an automatic cartridge-free weapon with separate loading of gunpowder and bullet into the weapon, which allows to maximize the benefits that this principle gives, and which are fundamentally unattainable for systems that use cartridge-case, cartridge-free cartridges, or batch placement of ammunition elements, namely, the possibility of one weapon to use different in length, and, consequently, the mass of bullets, buckshot and powder charges different in mass.

FIG. 1, FIG. 2 are diagrams showing the main parts and components of an automatic weapon mechanism and the relationship of these parts and components with each other.

FIG. 3, FIG. 4, FIG. 5 are diagrams showing the shape, structure, and relationships of each other, the receiver, flange, barrel and duct of the exhaust channel, in different angles and sections, and the relationship with the receiver of the wedge socket, holders of the powder cartridge and spring-loaded movable wedges used to rotate the shafts powder cartridge.

FIG. 6, FIG. 7, FIG. 8 are diagrams showing the shape, structure and relationship between the parts of the shutter of the chamber in different angles and sections.

FIG. 9, FIG. 10 are diagrams showing parts and assemblies of a mechanism and a relationship between parts and assemblies of a mechanism of a powder cartridge.

FIG. 11, FIG. 12, FIG. 13 are diagrams showing the shape and relationship of the main parts of the powder cartridge from different angles.

FIG. 14, FIG. 15 are diagrams showing sections of a powder cartridge and revealing the relationships between the main parts of its mechanism.

FIG. 16, FIG. 17 are diagrams showing the shape and relationship of the spring-loaded movable wedges used to rotate the shafts of the powder cartridge and the gears at the end of the shafts that drive the piston-stops of the powder cartridge, and the principle of rotation of the gears when the powder cartridge moves up and down.

FIG. 18 is a diagram showing the elements and nodes of the mechanisms of the wedge nests, the relationship of these elements and nodes with each other, with the receiver and the shutter chamber.

FIG. 19, FIG. 20 are diagrams showing the main parts and components of an automatic weapon mechanism and the relationship of these parts and components with each other at the time of combustion of the powder gases in the chamber and at the beginning of the movement of the bullet in the barrel.

FIG. 21, FIG. 22 are diagrams showing the main parts and components of the automatic weapon mechanism and the relationship of these parts and components with each other at the moment of pressure of the powder gases discharged from the barrel through the gas outlet channel to the chamber shutter and the chamber shutter movement backward under the pressure of these gases.

FIG. 23, FIG. 24 are diagrams showing the main parts and assemblies of the automatic weapon mechanism and the relationship of these parts and assemblies with each other, at the moment the shutter of the chamber moving backward under the pressure of the powder gases comes into contact with the shutter wedge, which, under the pressure of the shutter of the chamber, lowers down into the wedge socket.

FIG. 25, FIG. 26 are diagrams showing the main parts and components of the automatic weapon mechanism and the relationship of these parts and components with each other, at the moment the shutter reaches the chamber, when moving backward, to the extreme position.

FIG. 27, FIG. 28 are diagrams showing the main parts and assemblies of an automatic weapon mechanism and the relationship of these parts and assemblies with each other, during the return movement of the chamber shutter, under the influence of a return spring.

FIG. 29, FIG. 30 are diagrams showing the main parts and assemblies of the automatic weapon mechanism and the relationship of these parts and assemblies with each other, at the moment the shutter reaches its extreme position during the return movement under the influence of the return spring.

FIG. 31 is a diagram showing the elements and components of the mechanisms of the wedge nest that provide automatic weaponry, the ratio of these elements and components with each other, with the receiver and the camera shutter, to the position when the camera is filled with gunpowder and the bullet is in the barrel, that is, in the ready position fire.

FIG. 32 is a diagram showing the elements and components of the mechanisms of the wedge nest, providing automatic weapons, the ratio of these elements and nodes with each other, with the receiver and the shutter chamber, in the position when the ignition and combustion of gunpowder in the chamber.

FIG. 33 is a diagram showing the elements and components of the mechanisms of the wedge nest, providing automatic weapons, the ratio of these elements and components with each other, with the receiver and the shutter chamber, in a position where under the pressure of the powder gases discharged from the barrel through the gas channel, the shutter chamber moves back.

FIG. 34 is a diagram showing the elements and nodes of the mechanisms of the wedge nest, providing automatic weapons, the ratio of these elements and nodes with each other, with the receiver and the shutter chamber, in a position where under the pressure of the powder gases discharged from the barrel through the gas channel, the shutter chamber when moving back reaches the extreme position.

FIG. 35 is a diagram showing the elements and nodes of the mechanisms of the wedge nest, providing automatic weapons, the ratio of these elements and nodes with each other, with the receiver and the shutter, in the position when the shutter moves forward by the action of the return spring.

FIG. 36 is a diagram showing the possibility of using bullets of different lengths or buckshots in one weapon.

Automatic weapon-free weapons consist of:

1. Barrel 1 with duct duct 2 on top of it.

2. Entrance 3 - parts of the barrel, or a separate part adjacent to the barrel, with an internal channel of a larger diameter than the caliber of the barrel, located on the same axis with the barrel channel, and with a bullet-receiving slot for supplying bullets from a cage that is joined to the front wall of the receiver .

3. The bullet clip 4, which is joined with the camera.

4. The receiver 5, with the front wall of which is joined: the forehead and the exhaust channel 2; on top of the powder cartridge 6; the back is a plug with a return spring 7. The receiver is the bottom and the cover of the powder chamber 8, in which the shutter of the chamber 9 moves. The bottom, cover and side walls 10 of the receiver create a piston chamber in which powder gases from the exhaust channel press against the shutter of the chamber 9. In the receiver cover there is: on top a slot for supplying gunpowder from the powder cartridge 11; bottom slot for the shutter handle of the cam 12; bottom slot for the movement of the bolt wedge 13; cuts from the sides, for the release of powder gases from the piston chamber 14, when the shutter chamber reaches its extreme position when reversing. In the front of the receiver there is an opening 15 for the entrance of the gas-in piston of the shutter chamber 16 in the front part and an opening for the entry of powder gases into the piston chamber 17 from the super-barrel exhaust channel 2. In the cover and bottom of the receiver there are cutouts 18 for guiding the shutter of the chamber 19. On top of the receiver the boxes have spring holders of the powder cartridge 20 and spring-loaded movable wedges 21 for turning the shafts of the powder cartridge 22, for driving the pistons that limit the powder cartridge 23.

5. The shutter chamber 9, moving inside the receiver 5 and consisting of: a gas piston 16 coming out of the front wall of the shutter chamber, which extracts the bullet from the holder in the front 4 and pushes the bullet further into the barrel 1; front, beveled inward, wall 24; the rear wall with a movable spring-loaded wedge 25, blocking the bolt wedge 13 in its highest position; side walls 26; frame 27, opening and locking the powder cartridge 6; guides 19 and the handle of the shutter chamber 28.

6. A powder cartridge 6, consisting of: a housing 29 with a cutout from above 30, for turning and fixing the movable hollow cylinder 31 with cutouts (slots) of different widths 31.1, 31.2, 31.3, which allow controlling the amount of gunpowder supplied to the chamber; a bottom cut-out 32 through which gunpowder is fed into the chamber; movable piston-limiters 23 with a tooth 46 included in the groove 45 of the shafts 22, limiting, compressing the powder mass inside the cartridge as it decreases during firing; shafts 22 driving the pistons-limiters 23, with gears at the ends 44 having teeth 43 having a spiral groove 45 into which a tooth 46 of the pistons of the limiters 23 is inserted.

7. The bolt wedge 13, supported by a return spring 32, in the extreme upper position entering the chamber and locking it, in the extremely low position coming out of the chamber so that it does not interfere with the movement of the chamber shutter; spark bolt plates 43 are provided on the gate wedge and wedge nest; in the bolt wedge there are slots for entry of the spring-loaded wedges: 13.1 for the spring-loaded wedge 34; 13.2 for a spring-loaded blade 25; 13.3 for a spring-loaded blade fuse 36; 13.4 for a spring-loaded blade 37; 13.3 for a spring-loaded trigger blade 39.

8. A wedge nest 33 of the box in which there is: a bolt wedge 13; return spring bolt wedge 32; spring-loaded wedges, fixing the bolt wedge in the lowermost position 34, located on the rear wall of the wedge socket; lever drive spring-loaded wedge, locking bolt in the extreme lower position 35; a spring-loaded wedge of the fuse 36, located on the rear wall of the wedge socket, fixing the bolt in the extreme lower position; spring-loaded wedges in front of the wedge nests 37, fixing the bolt in the extreme upper position; a drive lever 38 with a spring-loaded lock of a spring-loaded wedge fixing the bolt in the extreme upper position 42; spring-loaded wedges of the trigger 39, fixing the bolt in the extreme lower position; fuse drive 40; whispered the trigger 41.

9. The rear plug with a return spring 7, put on the receiver 5, so that the return spring is inside the receiver, pressed against the rear wall of the shutter chamber 9, inside its guides (Fig. 1).

10. The principle of operation of automatic weapons-free weapons (duty cycle) is as follows:

10.1. FIG. 29, FIG. 30. The shutter chamber 9 is in the extreme right position. The gas piston 16 is fully included in the stand, the bullet is placed in the barrel. The shutter chamber 9 and the receiver 5 formed a powder chamber, which is limited by the rear, front and side walls of the shutter chamber and the upper and lower walls of the receiver. The shutter frame of the chamber 27 closes the powder cartridge. The bolt wedge 13 is in an extremely low position, held by the wedges of the fuse 36 and / or trigger 39 (Fig. 18).

10.2. FIG. 19, FIG. 20. When the trigger and fuse are pressed, the bolt wedge 13 ceases to be held by the wedges 36 and 39 (Fig. 18) and, pushed by the return spring, begins to move up. Reaching an extremely high position, he carves sparks with spark-cutting plates 43. The gunpowder in the chamber ignites and powder gases, through the channel of the gas-piston of the shutter chamber 16, expire into the barrel and push the bullet. The bolt wedge is fixed in its highest position by the wedges 37 and 25. The pressure of the powder gas in the chamber on the front wall of the shutter chamber 9 and the shutter wedge 13 reliably locks the shutter chamber.

10.3. FIG. 21, FIG. 22. When the bullet moves, the powder gases penetrate into the gas outlet channel 2 and begin to put pressure on the front wall of the shutter chamber 9. Under pressure of the powder gases, the shutter chamber 9 rolls back inside the piston chamber formed by the upper, lower and side walls of the receiver 5. The shutter wedge remains in place, in the highest position, held by the wedge 37. The frame of the shutter chamber 27, moving together with the shutter chamber 9 back, opens the powder cartridge and gunpowder from it through the cutout 11 (Fig. 3) in the top panel of the receiver is absorbed into the expandable porohopriemnuyu chamber defined lower and upper panel of the receiver 5, the rear and side walls of the chambers 9 and the shutter gate 13. The gate wedge wedge 13 separates the powder entering the porohopriemnuyu chamber from the combustion chamber.

10.4. FIG. 23, FIG. 24. The shutter chamber 9, moving back, the front wall is in contact with the bolt wedge 13 and lowers it down. All combustion products are removed. Moving back, the frame of the shutter chamber 27 opens wider the powder cartridge, the size of the powder chamber increases

10.5. FIG. 25, FIG. 26. The shutter chamber 9 reaches its extreme position when rolling back. The frame of the chamber 27 no longer holds the powder cartridge 6. Under the influence of the springs 20, it drops down, shaking the powder, which contributes to the extraction of powder from the powder cartridge. Gears 44 at the ends of the shafts of the powder cartridge interact with the movable spring-loaded wedges 21 and rotate, pushing the pistons stops 23 in the powder cartridge (Fig. 16, Fig. 17). The shutter chamber 9 leaves the piston chamber and powder gases flow out through the side cutouts in the receiver 14 (Fig. 5).

10.6. FIG. 27, FIG. 28. The return spring 7, straightening, pushes the shutter chamber 9 back. The frame of the shutter chamber 27 when moving forward raises the powder cartridge 6, shaking it again. The shutter of the chamber 9, moving forward, pushes the powder extracted from the powder cartridge forward. The bolt wedge 13 is held in its lowest position by the wedge 34 and does not interfere with the movement of gunpowder. The gas piston of the shutter of the chamber 16, moving forward on the stand 3, removes the bullet from the holder and pushes the bullet into the barrel 1.

When the return spring 7 is fully extended, the system will be in the position described in paragraph 10.1, and the cycle will be repeated until the bolt wedge 13 is locked in the lower position by the fuse blade 36 and / or the trigger blade 39 (Fig. 18).

11. The principle of operation (duty cycle) of the slide wedge is as follows:

11.1. FIG. 31. The bolt wedge 13 is in the lowest position, held by the fuse blade 36 and / or the trigger blade 39. The spring-loaded wedges that lock the bolt in the lowest position 34 are recessed into the wedge socket 33. The drive lever of the spring-loaded blade 35 that locks the bolt into extreme lower position, lowered down and fixed by the rear wall of the chamber shutter pushed over it. A spring-loaded wedge in the front of the wedge socket 37, which fixes the bolt in the highest position, is pulled forward, its spring is straightened, its drive lever 38 is raised up and locked by the lock 42.

11.2. FIG. 32. When the trigger and fuse are pressed, the bolt wedge 13 ceases to be held by the wedges 36 and 39 (Fig. 18), pushed by the return spring, it begins to move up. A spring-loaded wedge that fixes the bolt in the lowest position 34 is recessed into the socket and does not interfere with its movement. In the extreme upper position, the gate wedge 13 is fixed by the wedges 25 and 37 and is held by them in the extremely upper position during the explosion of powder gases in the chamber.

11.3. FIG. 33. When the camcorder shutter rolls back 9, the wedges 25, rolling back together with the back wall of the camcorder shutter, leaves the slot of the shutter wedge 13. In the highest position, the shutter wedge 13 is fixed by the wedge 37 and is held in the extremely high position when the shutter is rolled back . The back wall of the chamber shutter, when rolling back, stops holding the drive lever 35 of the spring-loaded wedge 34, which fixes the bolt wedge in its lowest position, and the wedges 34 are ready to fix the bolt wedge in its lowest position. As you move back, the front wall of the chamber shutter begins to shift the spring-loaded lock 42 of the drive lever 38 of the spring-loaded wedge 37, fixing the bolt wedge 13 in its highest position.

11.4. FIG. 34. Moving back, the shutter of the chamber 9 shifts the spring-loaded lock 42 of the drive lever 38 of the spring-loaded wedge 37, which fixes the bolt wedge in its highest position, then presses on the drive lever 38, which recesses the spring-loaded wedges 37, which fixes the bolt wedge 13 in its highest position, into the wedge socket 33. Under the pressure of the backward shutter of the chamber 9, the slide wedge 13 is lowered.

11.5. FIG. 35. When reaching the extreme position, when rolling back, the shutter of the chamber 9, the slide wedge 13 lowers to the lowermost position, and it is fixed in this position by the spring-loaded wedges 34. The drive of this wedge 35 is then extruded from the wedge socket upward. The shutter of the chamber 13 with its front wall ceases to press on the drive lever 38, its lock 42 is released, and under the influence of a spring, the lock 42 moves forward and fixes the lever 38 in its highest position, the lever 38 ceases to press on the spring-loaded wedges 37, which leaves the wedge socket 33 under the influence of its spring.

11.6. FIG. 31. When the shutter chamber 9 reaches the extreme right position, the back wall of the shutter chamber presses on the drive lever 35, it lowers and recesses the spring-loaded wedges 34, the locking wedge 13 is in the lowermost position, and the gate wedge starts to rise, the wedges 37 coming out of the wedge nest 33 is ready to fix the bolt wedge 13 in its highest position, the lock 42 will not allow the drive 38 to squeeze the wedges 37 under the influence of powder gases in the explosion of gunpowder in the chamber. Rising, the bolt wedge 13 cuts out a spark that ignites the gunpowder, and the cycle is repeated until the bolt wedge 13 is locked in the lower position by the fuse blade 36 and / or the trigger blade 39 (Fig. 18).

Claims (9)

1. Cartridge-free automatic weapons containing a barrel, a box with a gas outlet channel, a front side, a receiver, a slide wedge, a chamber shutter, a wedge socket, a powder cartridge, a bullet clip, characterized in that the bullets and gunpowder are loaded separately into different parts of the weapon, bullets from the bullet cage in the pre-fire, from where they then move to the barrel, the powder is loaded from the powder cartridge into the powder reception chamber, from where it then moves to the chamber, where the powder is combusted, from where the powder gases through the gas rshen the chambers shutter fall into the barrel where the lead bullet to move. 2. The weapon according to claim 1, characterized in that the powder chamber and the chamber are successively formed by movement in the receiver of the chamber shutter and the bolt. 3. The weapon according to claim 2, characterized in that the chamber shutter moves backward under the pressure of the powder gases discharged from the barrel through the gas outlet channel to the chamber shutter, which acts as a piston moving inside the receiver, which acts as a piston chamber. 4. The weapon according to claim 2, characterized in that, moving inside the receiver, the cam lock opens and closes the powder cartridge, forms a powder reception chamber and chamber inside the receiver, pushes the powder from the powder reception chamber into the chamber, removes the bullet from the holder in the cradle, pushes a bullet from the stand into the barrel, passes powder gases from the chamber into the barrel through the gas piston. 5. The weapon according to claim 4, characterized in that when the chamber shutter moves back, the bolt wedge remains in the raised position and separates the powder-receiving chamber and the chamber, preventing the powder entering the powder-receiving chamber from contacting the products of the combustion of the powder in the chamber, being sunk into the wedge socket only when the shutter reaches the chamber when moving backward to the extreme position, and in this position does not prevent the propellant from pushing gunpowder into the chamber when the shutter moves backwards. 6. The weapon according to claim 4, characterized in that when the shutter reaches its extreme position when moving forward, the slide wedge leaves the wedge socket in the receiver, completes the formation of the chamber and ignites the powder in a fully formed chamber. 7. The weapon according to claim 4, characterized in that during the combustion of the powder gases in the chamber, the gate wedge closes the back wall of the chamber shutter inside the chamber, blocking the pressure of the powder gases on it and thereby ensures the stability (locking) of the chamber shutter by the pressure of the powder gases only on the front the shutter wall of the chamber inside the chamber. 8. The weapon according to claim 1, characterized in that the portion size of the powder extracted from the powder cartridge into the powder chamber is controlled by the width of the slit of the powder cartridge through which the powder enters the powder chamber. 9. The weapon according to claim 1, characterized in that the region in the powder cartridge where the powder is located is reduced as the powder is consumed, concentrating the remaining powder in the region of the powder loading from the powder cartridge into the powder receiving chamber.

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