RU2319921C1 - Breechblock drive of automatic firearm - Google Patents

Abstract

FIELD: firearm, in particular, mechanisms used a breechblock drive of automatic firearm or artillery weapon using the energy of powder gases.

SUBSTANCE: the breechblock drive of automatic firearm has a bushing installed at the end of the barrel for longitudinal motion relative to the barrel and is mechanically linked with the breechblock components. The bushing has the front wall in which an opening is made with a center located in the barrel axis, the size of the opening exceeds the size of the weapon caliber. An expansion forming the gas chamber is made in the front part of the bushing. At least two rods coupling the bushing to the breechblock components are fastened to the rear part of the bushing. A spiral return spring resting with the front end on the stop made on the barrel is installed on the barrel, and with the rear end it rests on the breechblock components. The bushing, rods and return spring are provided with a protective housing enveloping them. An opening for projection of the projectile and outlet of the powder gases is made in the front part of the protective housing.

EFFECT: simplified construction and enhanced reliability of operation of the breechblock drive.

8 cl, 2 dwg

Description

The invention relates to firearms, and in particular to mechanisms used as a shutter actuator for automatic small arms or artillery weapons using the energy of powder gases.

Known drive automatic firearms described in patent DE 19739451, class. F41A 5/18, March 11, 1999 [1] containing a gas chamber, which communicates through a special hole with the bore. A spring-loaded piston is installed in the gas chamber, the stem of which is mechanically connected to the shutter parts.

The power pulse transmitted at the time of the shot from the piston to the rod causes high compression stresses in the rod. Such a stress state makes it necessary to strengthen the rod by increasing its diameter to avoid longitudinal bending, which leads to an increase in the mass of the drive. In addition, when fired, the barrel "leads" to the side, because the resultant of the forces imparted to the piston by the powder gases does not coincide with the geometrical axis of the bore. To prevent this phenomenon, one also has to increase the weight of the weapon.

From the description of patent RU 2150062, cl. F41A 5/18, publ. May 27, 2000 [2], a shutter drive of an automatic firearm is known, comprising a gas chamber made in a piston and mounted with the possibility of longitudinal movement at the front end of the barrel.

The design of the shutter drive [2] has the following disadvantages.

As in the device [1], the elements transmitting the operating force to the shutter are subjected to pulsed compression forces.

In the case of the embodiment of the invention in which the piston partially covers the barrel, there is a tendency to "pull" towards the barrel of the weapon during firing, and in the case of the variant in which the piston completely covers the barrel, the entire drive structure is excessively heavier.

The closest analogue of the invention is an automatic firearm shutter drive, known from US Pat. No. 2,3331,347, n.c. 8.9-192, 12.10.43 g [3], containing a sleeve mounted on the end of the barrel with the possibility of longitudinal movement relative to the barrel and mechanically connected with the shutter parts, the sleeve has a front wall in which a hole is made with a center located on the axis of the barrel, the size of the hole exceeds the size of the caliber of the weapon.

The shutter drive [3] is characterized by the presence of long rods working during compression shot under pulsed loading conditions. This type of load is associated with the risk of breakage of parts due to longitudinal bending. In addition, gear racks are used in this complex design, the teeth of which are subjected to shock loads when fired, causing critical contact stresses. The surface of the barrel end and the bushing surface in contact with it are subject to abrasion during firing due to the ingress of solid particles (e.g. sand) from the environment into the gap between the bushing and the barrel.

The noted design flaws of the prototype drive [3] adversely affect its operational reliability.

The technical result of the invention is to simplify the design and increase the reliability of the shutter drive.

The specified technical result is achieved in the known automatic shutter drive of a firearm containing a sleeve mounted on the end of the barrel with the possibility of longitudinal movement relative to the barrel and mechanically connected with the shutter parts, the sleeve has a front wall in which a hole is made with a center located on the axis of the barrel, the size of the hole exceeds the size of the caliber of the weapon. A distinctive feature of the proposed shutter drive is that an extension forming the gas chamber is made in the front part of the sleeve, at least two rods are attached to the rear part of the sleeve connecting the sleeve with the shutter parts, a spiral return spring is installed on the barrel, abutting the front end against an emphasis made on the barrel, and the rear end abutting against the shutter parts, the sleeve, the rods and the return spring are provided with a protective cover covering them mounted on the barrel in front of the protective casing in A hole has been made for the bullet or projectile to escape and the release of powder gases.

The invention has the following particular cases.

The gas chamber can be additionally equipped with a shutter pivotally mounted in its front part having an opening for a bullet or projectile to pass through it, on the back side the shutter is equipped with a stop restricting its deflection back, and on the front side its deflection is limited by the inner surface of the front wall of the sleeve, the hole the shutter is located so that the shutter, being in the extreme rear position, provides when firing the ability to move a bullet or projectile through the hole made in it, and being in the edge In the front position, the shutter completely covers the hole in the front wall of the sleeve, a longitudinal through slot is made in the sleeve wall at the place of hinging the shutter to it; the portion of the shutter located at this place has a curved elongated element that protrudes through the longitudinal through slot from the gas chamber, giving the damper is a two-shouldered lever type, and an emphasis is made on the inner surface of the protective casing for interacting with said curved damper element. In this particular case of the invention, an emphasis located on the surface of the protective casing and designed to interact with the end of the curved elongated element of the damper protruding from the gas chamber is made in the form of an annular stiffener.

Ventilation openings may be made in the side walls of the protective casing.

Openings for the exit of powder gases can be made in the back wall of the gas chamber.

The inner surface of the side walls of the protective casing may have guiding protrusions that enable longitudinal movement of the sleeve between them.

The back of the sleeve can be made in the form of a flange designed to perform the function of a piston in the cavity between the sleeve and the protective casing.

An emphasis against which the front end of the return spring abuts can be made in the form of a flange attached to the barrel and to the protective casing.

The invention is illustrated by the following drawings.

Figure 1. General view of the drive before firing, longitudinal section.

Figure 2 The same, at the time after departure from the barrel of a bullet or projectile.

As shown in FIGS. 1 and 2, a movable metal sleeve 2 is installed at the end of the weapon barrel 1, which is bounded in front by a wall 3. A circular hole 4 is made in the front wall 3 of the sleeve 2, the center of which is located on the axis of the barrel 1. The diameter of the hole 4 exceeds size caliber weapons. The sleeve 2 in its front end ends with a bulge forming a gas chamber 5. Two rods 6 are attached to the back of the sleeve 2, connecting it with the details of the shutter 7. In the drawings, the shutter 7 is shown schematically in the form of a rectangle. The design options for the shutter 7 may be different depending on the type of weapon. A spiral return spring 8 is installed on the barrel 1 in front of the shutter 7. The front end of the return spring 8 abuts against a stop 9 mounted on the surface of the barrel 1. The rear end of the return spring 8 abuts the shutter parts 7. Sleeve 2 with a gas chamber 5, traction 6 and a return the spring 8 is provided with a protective casing 10 covering them, which is rigidly fixed to the barrel 2. In its front part, the protective casing 10 has an opening 11 for the release of a bullet or projectile and for the exit of powder gases. The inner surface of the protective casing 10 may have guide protrusions 12, allowing longitudinal movement of the sleeve 2 between them.

The gas chamber 5 may be further provided with a shutter 13, which is attached to the gas chamber 5 by a hinge 14. The shutter 13 has an opening 15 for passage of a projectile or bullet. On the rear side of the shutter 13, an emphasis 16 is fixed in the gas chamber 5, and the front part of the shutter 13, as a result of rotation on the hinge 14, can abut against the inner surface of the front wall 3 of the sleeve 2. The hole 15 in the shutter 13 is located so that the shutter 13 is in the extreme rear position, provides when firing the ability to move a bullet or projectile through the hole 15 made therein (see Fig. 1). Being in the extreme forward position, the shutter 13 completely covers the hole 4 in the front wall 3 of the sleeve 2 (see figure 2).

The part of the shutter 13, located at the place of its attachment to the hinge 14, has a curved elongated element 17 that protrudes from the gas chamber 5 through a longitudinal through slot made in the wall of the gas chamber 5. On the inner surface of the protective casing 10, an emphasis is made 18, interacting with the end of the protruding from the gas chamber 5 of the curved elongated element 17 of the valve 13.

Ventilation openings 19 are made in the side walls of the protective casing 10, and openings 20 for the exit of powder gases are made in the back wall of the gas chamber 5. The back of the sleeve 2 is made in the form of a flange 21 and plays the role of a piston when the sleeve 2 moves in the cavity of the protective casing 10.

The stop 9, which abuts the front end of the spring 8, can be made in the form of a flange attached to the protective casing 10.

The shutter drive operates as follows.

Before firing, the sleeve 2 with the gas chamber 5, held by rods 6, are in the extreme rear position (see figure 1). The spring 8 is in a state of minimal compression (its compression force is sufficient to reliably hold the sleeve 2 with the gas chamber 5 in its extreme rear position). The damper 13 is pressed against the stop 16 and is in the extreme rear position (relative to the gas chamber 5). The geometric axis of the hole 4 made in the front wall 3 of the gas chamber 5, the axis of the hole 15 in the shutter 13 and the axis of the hole 11 made in the front of the protective casing 10, coincide with the axis of the barrel 1.

When fired after the moment of departure from the bore 1 of the bullet or projectile under the influence of the pressure of the powder gases, the sleeve 2, carried away by the gas chamber 5, moves to its extreme forward position (see figure 2). The return spring 8 as a result of the forward movement of the sleeve 2 is subjected to maximum compression. Under the influence of the pressure of the powder gases, the shutter 13 passes from the extreme rear position to the extreme forward position (relative to the gas chamber 5) and, tightly pressing in the front wall 3 of the gas chamber 5, closes the hole 4 made in this wall (see figure 2).

At the final stage of the process of exit from the bore of the barrel 1 of the powder gases, when their effect on the gas chamber 5 is weakened, the sleeve 2 with the gas chamber 5 by the force of the spring 8 is transferred to its extreme rear position. At the same time, the shutter 13 under the action of the stop 20, located on the protective casing 10, is also transferred to its extreme rear position with respect to the gas chamber 5 (see figure 1).

When the sleeve 2 with the gas chamber 5 moves from the position in FIG. 1 to the position in FIG. 2 and back as a result of the interaction of the rods 6 with the shutter parts 7, the spent sleeve can be removed from the chamber, the new cartridge is sent in and the striker spring is cocked.

The supply of the gas chamber 5 with a shutter 13 allows you to increase the force exerted by the powder gases on the chamber 5 after the bullet or projectile leaves the barrel 1. This makes it possible to reduce the transverse dimensions of the gas chamber 5 and, therefore, to facilitate the design of the drive.

The implementation of the holes 20 on the back wall of the gas chamber 5 provides a reduction in the recoil force of the weapon due to the reactive action on the gas chamber 5 exiting the holes 20 of the powder gases.

The presence of the valve 13 elongated curved element 17, protruding from the gas chamber 5 outward through a longitudinal slot of the front wall of the chamber 5, after the bullet or projectile leaves the barrel 1, it accelerates the forward movement of the sleeve 2 with the gas chamber, because the short shoulder of the two shoulders of the lever (which can be considered the shutter 13) as it pushes the gas chamber 5 forward. At the final stage of the movement of the sleeve 2 with the chamber 5 to the extreme rear position, the elongated curved element 17 allows the shutter 13 to be moved from the extreme front position to the extreme rear position with respect to the gas chamber 5 and held in this position until the next shot.

The presence of ventilation holes 19 in the side walls of the protective casing 10, as well as the execution of the back of the sleeve 2 in the form of a flange 21 accelerates the cooling process of the barrel 1, the gas chamber 5 and the protective casing. This ensures stabilization of the temperature regime of the drive parts, which is especially important when shooting in long bursts.

The implementation of the stop 18 in the form of an annular stiffener not only enhances the protective casing 10, but also prevents the radial displacement of the gas chamber 5 when firing.

Tests of prototypes made in accordance with this description of the invention showed high reliability of the proposed design of the drive of the shutter during the operation of weapons in the field.

Claims (8)

1. The shutter drive of an automatic firearm containing a sleeve mounted on the end of the barrel with the possibility of longitudinal movement relative to the barrel, mechanically connected with the shutter parts and having a front wall in which a hole is made with a center located on the axis of the barrel, and the size of which exceeds the size of the caliber weapons, characterized in that in the front of the sleeve there is an expansion forming the gas chamber, at least two rods attached to the back of the sleeve connecting the sleeve with parts the shutter, a spiral return spring is installed on the barrel, abutting the front end against the abutment made on the barrel, and the rear end abutting against the shutter details, the sleeve, rods and the return spring provided with a protective cover covering them mounted on the barrel, and in the front part of the protective casing hole for the departure of the projectile and the exit of powder gases. 2. The shutter drive according to claim 1, characterized in that the gas chamber is provided with a shutter pivotally mounted in its front part having a hole for passing a projectile through it, on the back side the shutter is provided with an abutment limiting its deflection backward, from the front side its deflection is limited the inner surface of the front wall of the sleeve, the hole of the shutter is located so that the shutter in its extreme rear position provides a shot when the bullet or projectile can be moved through the hole made in it, and in the extreme In its current position, the shutter completely covers the hole in the front wall of the sleeve, a longitudinal through slot is made in the sleeve wall at the place of hinge fastening of the shutter to it; two shoulders of the lever, and on the inner surface of the protective casing made emphasis designed to interact with the aforementioned curved elongated element of the shutter. 3. The drive according to claim 2, characterized in that the emphasis located on the surface of the protective casing and designed to interact with the end of the curved elongated element of the damper protruding from the gas chamber is made in the form of an annular stiffener. 4. The shutter drive according to claim 1 or 2, characterized in that the ventilation holes are made in the side walls of the protective casing. 5. The shutter drive according to claim 1 or 2, characterized in that openings for the exit of powder gases are made in the back wall of the gas chamber. 6. The shutter drive according to claim 1 or 2, characterized in that the inner surface of the side walls of the protective casing has guiding protrusions that enable longitudinal movement of the sleeve between them. 7. The drive according to claim 1 or 2, characterized in that the back of the sleeve is made in the form of a flange designed to perform the function of a piston in the cavity between the sleeve and the protective casing. 8. The drive according to claim 1 or 2, characterized in that the emphasis, which abuts the front end of the return spring, is made in the form of a flange attached to the barrel and to the protective casing.

Images