RU152000U1 - AUTOMATIC SNIPER RELEASE ARMS “SELECTION” MECHANISM (OPTIONS) - Google Patents

Abstract

1. The reloading mechanism of automatic small arms, comprising a muzzle brake compensator configured to be mounted on the muzzle of the barrel, a piston with a hole for a bullet located inside the barrel of the muzzle brake compensator and configured to move along its central axis, traction, the first end connected to the piston, and the second end connected to the pusher bolt frame, and a spring for returning thrust, characterized in that the spring is located inside the muzzle brake compensator, when that the first end of the spring interacts with the piston, and the second end of the spring abuts against the front wall of the housing muzzle brake-kompensatora.2. The reloading mechanism of automatic small arms according to claim 1, characterized in that the piston is made in the form of a glass, while the hole for the bullet is made in its bottom, with the glass wall protruding towards the muzzle of the barrel. 3. The reloading mechanism of automatic small arms according to claim 2, characterized in that the first end of the spring interacts with the outer surface of the bottom. The reloading mechanism of an automatic small arms according to claim 2, characterized in that the first end of the rod is screwed into the threaded hole of the tide made on the inner surface of the glass wall, while the hole through which the rod passes through the piston is made. The reloading mechanism of automatic small arms according to claim 2, characterized in that the first end of the rod is connected to a protrusion in the form of a tide made on the outer surface of the glass wall, and a slot is made in the side wall of the muzzle brake compensator for

Description

A group of utility models relates to the field of automatic small arms, namely, to mechanisms for reloading automatic small arms.

Currently, in the Russian and global design practice of building military sniper rifles, two types of sniper rifle systems are used: automatic sniper rifles (use part of the energy of the powder gases of the cartridge to start the automatic reloading of weapons) and sniper rifles with manual reloading with a longitudinally-sliding bolt (using muscular power arrow for carrying out the process of reloading weapons after each shot is fired).

Both types of rifles have very serious design flaws that adversely affect the tactical relevance of the weapon.

The most important tactical drawback of manual reloading sniper rifles is the very low rate of fire (8-10 rounds per minute), which does not allow for the high-quality fulfillment of the combat missions of short-lived modern shooting combat against numerous advancing infantry targets of the enemy. In addition, the process of manually reloading a self-loading rifle with a sniper generates undesirable in battle, very high unmasking signs of a sniper firing position, which leads to its quick detection and destruction by the enemy.

A known mechanism for reloading automatic small arms (RU 2046265 C1, 10.20.1995), comprising a muzzle, a gas outlet and a gas cylinder with a piston, and the gas outlet is made in the form of a channel in a muzzle and a gas pipe connecting the channel in a muzzle with a gas cylinder, while the muzzle is equipped with a gas stopper with a cutout mounted for rotation and blocking the channel, and the gas cylinder with a piston is displaced to the breech of the barrel by the length of the gas tube.

Known reloading mechanisms, the principle of which involves the use of energy of the powder gases discharged through an opening in the bore (RU 2168142 C2, 05.27.2001, US 8640598 B1, 02/04/2014). The mechanisms differ in the design of valves and gas systems.

Automatic small arms with a mechanism that works according to the aforementioned well-known principle, has insufficient firing accuracy, which does not allow to fully perform the combat tasks of modern combined arms combat at medium and long ranges. This is due to the inevitable receipt of "arms" weapons, objectively arising during the process of reloading self-loading automatic weapons. They are due to the beginning of the backward movement of the relatively heavy parts of the moving parts of the bolt group produced until the bullet leaves the bore. This has a very negative effect on the retention of the initial accurate aiming systems set by the shooter.

The closest analogue to the options for reloading automatic small arms according to 1, 7 of the formula is the decision RU 23195 U1, 05.27.2002, in which the mechanism for reloading automatic small arms containing a muzzle (a muzzle brake compensator with perforation made in the front and an exhaust device in the form of a pipe in the back) is disclosed, traction associated with the lock of the shutter, a piston with a central hole located inside the fixed muzzle, a spring return thrust, and the thrust at one end connected with the lock of the shutter, and the other directly with the piston, while the muzzle has a perforation in front walkie-talkie, and in the back - the exhaust device.

A serious operational drawback of the design of the reloading mechanism disclosed in the closest analogue is the exit of the muzzle piston in the process of completing the working cycle outside the muzzle cylinder. During military operation, when firing while lying down, this will inevitably lead to a high degree of clogging with dust and dirt that is lifted from the ground from the outflow of powder gases from the barrel bore. In a combat situation, this circumstance will contribute to frequent weapon failures and the inability to perform combat missions.

The problem to which the proposed group of utility models is directed is to eliminate the above-mentioned drawbacks of the known solutions and provide high accuracy and accuracy indicators in combination with a high rate of fire.

The technical result achieved by the proposed group of utility models is to increase the reliability of the mechanism for reloading automatic small arms during operation.

The achievement of the technical result is due to the fact that the piston operates in the internal cavity of the muzzle brake compensator (the piston does not extend beyond the muzzle brake compensator body). This eliminates the possibility of dust and dirt, and provides an increased resource of operational reliability of the weapon in battle and a large total resource of work without repair.

The technical result according to the first embodiment is achieved by the fact that the reloading mechanism of automatic small arms contains a muzzle brake compensator made with the possibility of mounting on the muzzle of the barrel, a piston with an opening for a bullet located inside the barrel of the muzzle brake compensator and made to move along its central axis, rod, the first end connected to the piston, and the second end connected to the pusher bolt frame, and a spring to return the thrust, and the spring is located inside the case of the muzzle brake compensator, while the first end of the spring interacts with the piston, and the second end of the spring abuts against the front wall of the body of the muzzle brake compensator.

The piston is made in the form of a glass, while the hole for the bullet is made in its bottom, and the wall of the glass protrudes toward the muzzle of the barrel.

The first end of the spring interacts with the outer surface of the bottom.

The first end of the rod is screwed into the threaded hole of the tide, made on the inner surface of the glass wall, while in the piston a hole is made through which the rod passes.

The first end of the thrust can be connected to the protrusion in the form of a tide made on the outer surface of the glass wall, and a slot for the protrusion is made in the side wall of the muzzle brake compensator body.

In the side wall of the housing of the muzzle brake compensator, holes are made for the expiration of the compensation reactive flows of powder gases.

The technical result according to the second embodiment is achieved in that the reloading mechanism of the automatic small arms comprises a muzzle brake compensator configured to be mounted on the muzzle of the barrel, a piston with an opening for a bullet located inside the barrel of the muzzle brake compensator and made to move along its central axis, traction, the first end connected to the piston, and the second end connected to the pusher of the bolt frame, and a spring for returning traction, and the muzzle brake The nocator contains at least two successive sections, with the piston and spring installed in the first section in communication with the barrel, the first end of the spring interacts with the piston, and the second end of the spring abuts against the wall of the muzzle brake compensator separating the first and second sections .

The piston is made in the form of a glass, while the hole for the bullet is made in its bottom, and the wall of the glass protrudes toward the muzzle of the barrel.

The first end of the spring interacts with the outer surface of the bottom.

The first end of the rod is screwed into the threaded hole of the tide, made on the inner surface of the glass wall, while in the piston a hole is made through which the rod passes.

The first end of the rod can be connected to the protrusion in the form of a tide, made on the outer surface of the wall of the glass, and in the side wall of the housing of the muzzle brake compensator, in the first section, a slot for the protrusion is made.

In the side wall of the housing of the muzzle brake compensator, in the first section, holes are made for the expiration of the compensatory reactive flows of powder gases.

In the side wall of the second section of the muzzle brake compensator, windows for the exit of powder gases are made.

FIG. 1 - reloading mechanism of automatic small arms according to the first embodiment (the first end of the rod is screwed into the threaded hole of the tide, made on the inner surface of the glass wall);

FIG. 2 is a section Α-A according to FIG. 1 (muzzle brake compensator not shown);

FIG. 3 - reloading mechanism of automatic small arms according to the first embodiment (the first end of the rod is connected to the protrusion in the form of a tide made on the outer side surface of the piston).

FIG. 4 - reloading mechanism of automatic small arms according to the second embodiment (the first end of the rod is screwed into the threaded hole of the tide made on the inner surface of the glass wall).

FIG. 5 - reloading mechanism of automatic small arms according to the second embodiment (the first end of the rod is connected to the protrusion in the form of a tide made on the outer side surface of the piston).

According to the first embodiment, the reloading mechanism of automatic small arms includes a muzzle brake compensator, configured to be mounted on the muzzle of the barrel 1, a piston 2 with an opening 3 for a bullet located inside the housing 4 of the muzzle brake compensator and made to move along its central axis 5 , rod 6, the first end connected to the piston 2, and the second end connected to the pusher 7 of the bolt frame (not shown), and the spring 8 to return the rod 6. The spring 8 is located inside the barrel 4 of the muzzle compensator brake, while the first end of the spring interacts with the piston 2, and the second end of the spring abuts against the front wall 9 of the muzzle brake compensator body.

Rod 6 is connected by the second end to the pusher 7 of the bolt frame through the beam 10.

The muzzle brake compensator is mounted on the muzzle of the barrel 1 by means of a sleeve 11 having a threaded central hole for screwing on the muzzle of the barrel 1, on the outer surface of which a mating thread is made, and a thread on the side surface for screwing the housing 4 of the muzzle brake compensator having mating surface with mating thread. The sleeve 11, in fact, is the rear wall of the housing 4 of the muzzle brake compensator.

The piston is made in the form of a glass, while the hole for the bullet is made in its bottom 12, and the wall 13 of the glass protrudes toward the muzzle of the barrel 1.

The rod 6 can be connected to the piston 2 by screwing its first end into the threaded hole of the tide 14, made on the inner surface of the wall 13 of the glass (see Fig. 1, 2).

The first end of the rod 6 can be connected to the protrusion 15 in the form of a tide made on the outer surface of the glass wall 13, and a slot 16 for the protrusion 15 is made in the side wall of the muzzle brake compensator (see Fig. 3). The slot 13 is made by milling the side wall of the housing 4 of the muzzle brake compensator along its length.

In the side wall of the housing of the muzzle brake compensator can be made holes (not shown) for the expiration of the compensation reactive flows of powder gases.

Long military practice revealed a serious operational shortcoming of the Dragunov sniper rifle (SVD), expressed in injuries to the shoulder of a sniper during firing. This is due to the design feature having a small mass of weapons when using an excessively powerful 7.62 × 54 mm rifle cartridge arr. 1908 \ 30 years. Already when 30 rounds are fired, serious collarbone bruises occur with persistent pain symptoms, which significantly distract the shooter's attention from the aiming process. In this regard, it is necessary to use a muzzle brake compensator, having two or more sections, separated by partitions with holes for the bullet.

According to a second embodiment, the reloading mechanism of automatic small arms comprises a muzzle brake compensator configured to be mounted on the muzzle of the barrel 17, a piston 18 with a bullet hole 19 located inside the muzzle brake compensator housing 20 and arranged to move along its central axis 21 , thrust 22, the first end connected to the piston 18, and the second end connected to the pusher 23 bolt frame (not shown), and a spring 24 to return the thrust 22. The muzzle brake compensator contains at least two consecutive sections. In FIG. 4, 5, an embodiment with three sections 25, 26, 27 is shown. A piston 18 and a spring 24 are installed in the first section 25, which communicates with the bore 17. The first end of the spring 24 interacts with the piston 18, and the second end of the spring 24 abuts against the wall 28 housing muzzle brake compensator, separating the first 25 and second 26 sections.

The piston 18 is made in the form of a glass, while the hole for the bullet 19 is made in its bottom 29, and the wall 30 of the glass protrudes toward the muzzle of the barrel.

The first end of the rod 22 can be screwed into the threaded hole of the tide 31, made on the inner surface of the wall 30 of the glass (see Fig. 4).

The first end of the rod 22 can be connected to the protrusion 32 in the form of a tide, made on the outer surface of the wall 30 of the glass, and in the side wall of the first section 25 of the muzzle brake-compensator is made a slot 33 for the protrusion 32 (see Fig. 5).

In the side wall of the first section 25 of the muzzle brake-compensator holes are made (not shown) for the expiration of the compensation reactive flows of powder gases.

In the side wall of the second 26 and third 27 sections of the muzzle brake-compensator made windows (not shown) for the exit of powder gases.

The rod 22 is connected by the second end to the pusher 23 of the bolt frame through the beam 34.

The muzzle brake compensator is mounted on the muzzle of the barrel 17 by means of a sleeve 35 having a threaded central hole for screwing on the muzzle of the barrel 17, on the outer surface of which a mating thread is made, and a thread on the side surface for screwing the housing 20 of the muzzle brake compensator having mating surface with mating thread. The sleeve 35, in fact, is the rear wall of the housing 20 of the muzzle brake compensator.

The principle of operation of the reloading mechanisms of automatic small arms according to the proposed group of utility models. After the shot is fired, the bullet, passing the hole of the movable piston, goes off. After the bullet leaves the bore, the expanded burnt powder gases under high pressure, breaking out of the bore into the barrel of the muzzle brake compensator (into the inner working chamber of the compensator brake), begin to act on the piston (to the bottom if the piston is made in the form of a cup), giving it forward forward movement to the stop in the extreme forward position. At the same time, the movable piston, making a forward movement, carries with it a mobile thrust, which transfers a powerful impulse of the reciprocating motion through the rocker arm to the shutter pusher. The slide frame pusher, pushing back the movable parts of the bolt group of the weapon, ensures the launch of the reloading process of the weapon, similar to the SVD reloading mechanism. Those. the barrel channel is unlocked, the spent cartridge case is extracted (ejected), the bolt frame transitions to its extreme rear position, and under the action of the return spring, translational forward movement is made with the next cartridge being sent into the barrel channel and locked by turning the bolt to the right around the axis for the combat protrusions chamber. The weapon is ready for another shot. Since the start of the automation process (moving the moving parts to the rear position) is carried out only after the bullet leaves the bore, high accuracy and accuracy of the weapon are ensured in combination with a high rate of fire.

In an embodiment of the mechanism with a muzzle brake-compensator having two or more sections, when the powder gases flow out of the bore, the gas jet striking step by step into each of the partitions creates the effect of mutual leveling of forces acting in the direction opposite to the recoil force on the butt of the weapon in shot time. This achieves the effect of partial (by 40% or more) compensation of the longitudinal energy of the recoil of the weapon to the butt.

The mechanisms according to the proposed group of utility models have a simple design, can be used on the muzzle of the barrel in the form of a universal separate local device, compatible with any types of military weapons produced in the Russian Federation (AK, SVD, with locking the barrel channel by turning the bolt around its axes; 7.62 mm SCS with wedge locking; locking the shutter by moving it to the side, similar to the design of the 12.7 mm NSVT machine gun, CORD), are fundamentally new local devices that can fundamentally They can change the accuracy and accuracy of firing of automatic sniper rifles of the Armed Forces of the Russian Federation, and they are also able to provide extremely important tactical advantages to a sniper rifle: effective damping of the energy of longitudinal recoil of the weapon; leveling the negative effect of tossing a cut of the barrel during each shot; elimination of high unmasking signs of the firing position of the shooter due to the extinguishing of the muzzle brake-compensator for the flash of the shot and the dispersion of the sound of the shot inside the muzzle.

The principle of operation of the automation of the proposed mechanisms is promising and eliminates the need to use sniper rifles with manual reloading.

Due to the absolute versatility and compatibility with the designs of all sniper rifles currently manufactured by the Russian industry, the mechanisms can be recommended for mass use on all manufactured serial automatic military sniper rifles of the RF Armed Forces, all calibres 7.62 mm, 12.7 mm, 14.5 mm and can be applied without fundamentally changing the proven industrial technologies.

Claims (13)

1. The reloading mechanism of automatic small arms, comprising a muzzle brake compensator configured to be mounted on the muzzle of the barrel, a piston with a hole for a bullet located inside the barrel of the muzzle brake compensator and configured to move along its central axis, traction, the first end connected to the piston, and the second end connected to the pusher bolt frame, and a spring for returning thrust, characterized in that the spring is located inside the muzzle brake compensator, when that the first end of the spring interacts with the piston, and the second end of the spring abuts against the front wall of the housing muzzle brake canceller. 2. The reloading mechanism of automatic small arms according to claim 1, characterized in that the piston is made in the form of a glass, while the hole for the bullet is made in its bottom, and the glass wall protrudes toward the muzzle of the barrel. 3. The mechanism for reloading automatic small arms according to claim 2, characterized in that the first end of the spring interacts with the outer surface of the bottom. 4. The reloading mechanism of automatic small arms according to claim 2, characterized in that the first end of the rod is screwed into the threaded hole of the tide, made on the inner surface of the glass wall, while the hole through which the rod passes through the piston. 5. The reloading mechanism of automatic small arms according to claim 2, characterized in that the first end of the rod is connected to the protrusion in the form of a tide made on the outer surface of the glass wall, and a slot for the protrusion is made in the side wall of the muzzle brake compensator body. 6. The reloading mechanism of automatic small arms according to claim 1, characterized in that compensation holes are made in the side wall of the barrel of the muzzle brake compensator. 7. A reloading mechanism for automatic small arms, comprising a muzzle brake compensator configured to be mounted on the muzzle of the barrel, a piston with an opening for a bullet located inside the barrel of the muzzle brake compensator and configured to move along its central axis, traction, the first end connected to the piston, and at the second end connected to the pusher of the bolt carrier, and a spring for returning traction, characterized in that the muzzle brake compensator contains at least two sequentially o located sections, with the piston and spring installed in the first section communicating with the bore of the barrel, the first end of the spring interacts with the piston, and the second end of the spring abuts against the wall of the muzzle brake compensator separating the first and second sections. 8. The reloading mechanism of automatic small arms according to claim 7, characterized in that the piston is made in the form of a glass, while the hole for the bullet is made in its bottom, and the glass wall protrudes toward the muzzle of the barrel. 9. The reloading mechanism of automatic small arms according to claim 8, characterized in that the first end of the spring interacts with the outer surface of the bottom. 10. The reloading mechanism of automatic small arms according to claim 8, characterized in that the first end of the rod is screwed into the threaded hole of the tide made on the inner surface of the glass wall, while the hole through which the rod passes in the piston is made. 11. The reloading mechanism of automatic small arms according to claim 8, characterized in that the first end of the rod is connected to a protrusion in the form of a tide made on the outer surface of the glass wall, and a slot for the muzzle brake compensator is made in the first section for protrusion. 12. The reloading mechanism of automatic small arms according to claim 7, characterized in that the compensation holes are made in the side wall of the muzzle brake compensator body in the first section. 13. The reloading mechanism of automatic small arms according to claim 7, characterized in that in the side wall of the second section of the muzzle brake-compensator there are windows for the exit of powder gases.

Images