HU197088B - Gas exhausting device for firearms - Google Patents

Abstract

A gas extraction system for a firearm, in which a piston 15 which can be moved parallel to the barrel axis and is provided with an aperture 16, 18 is mounted in a chamber 14 which is connected by a gas extraction opening 19 to the inside 20 of the barrel of the firearm. In its rest position, the piston 15 is arranged at the end of the chamber 14 facing the barrel nozzle, with the aperture 16, 18 of the gas extraction opening 19 being located immediately opposite. On the other side, the aperture 16, 18 opens into the chamber 14, which has a gas outlet 30 which is released when the piston 15 moves and vents into the open air. The aperture 16, 18 is expanded by a predetermined amount, in the direction of the barrel nozzle, at its end associated with the gas extraction opening 19. The piston 15 interacts with the firearm breech locking system via an operating rod 23. A dead movement which acts in the barrel direction and corresponds to the predetermined amount, as well as a damping device which counteracts the movement of the piston 15 towards that end of the chamber 14 which faces away from the barrel nozzle are provided in the kinematic chain between the piston 15 and the breech operating system. The gas extraction opening 19 is closed by the piston 15 when this piston 15 has been moved by the amount of the dead movement. <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to a gas discharge device for firearms, in particular automatic and semiautomatic firearms, wherein a chamber that is slidable parallel to the axis of the chamber passageway is embedded in a chamber at the end of the chamber cooperates with its locking system, while the chamber comprising the piston is provided with an open gas outlet.

Similar gas discharge devices for automatic and semiautomatic firearms are known. Depending on the removable nozzle disks, such firearms are capable of firing either sharp or practice projectiles.

In these structures, after firing, the pressure of the flue gas flowing into the chamber through the gas venting holes acts on the piston, which retracts the locking valve of the locking system through the impact rod, accelerating against the spring action of the locking spring and impinging on whereby elements of the locking system, such as support caps, are placed in a position to release the locking catch. Further, the damper opens fully against the force exerted by the locking spring. The chamber is then vented through gas outlets.

Such locking devices form a mass lock, in which, for impulse operation, it is advisable to create a lock mass ratio of 1: 1 by the impulse rate.

The disadvantage of the above locking mechanism is that the trigger! the process starts as soon as the projectile crosses the line of the gas outlet, so it is still moving in the projectile passage. At this point, the rearward acceleration of the piston, the ram, and the lock piston begins, resulting in eccentric forces in the projectile that significantly and adversely affect the firearm's hit safety.

A further disadvantage of the solution is that the mass of the sled, which has to be absorbed as impact energy, rests on the support of the firearm.

It is an object of the present invention to overcome the above shortcomings and to provide a gas outlet structure which is simple in design, economical in space utilization, yet highly reliable in operation, highly insensitive to fluctuating gas pressures, and design for different calibers.

SUMMARY OF THE INVENTION This object is solved by providing a gas outlet structure in which a piston which is slidably disposed at the end of the chamber, It cooperates with a gas outlet opening on the wall of the chamber. According to the invention, the gas outlet bore is formed at a predetermined distance between the ends of the piston in its resting position at a predetermined distance from the chamber proximity to the barrel mouth, the piston having an opening which extends into the chamber and the gas outlet in the resting position. - a kinematic relationship between the piston and its cooperating latching mechanism is provided in the form of a projectile deadlock, - a damping mechanism at least at the end of the piston opening which acts against the displacement of the piston away from the mouth of the chamber, widened in the direction of the muzzle barrel to match the clearance, - the system is designed to close the gas drain hole when the plunger is offset the.

Λ The above design results in a gas discharge structure that can be used in pistols, hunting and military weapons. Jelentős It is a significant advantage of the invention that the opening process begins only after the bullet has left the bullet passage, so that the gas outlet cannot affect the trajectory of the bullet. This effect is achieved by the fact that after the firing powder gas has penetrated the chamber through the gas inlet bore and after the piston has been widened or the clearance has been displaced at a distance corresponding to the clearance, the gas discharge bore is closed. the gas pressure shall not exceed a specified value independent of the gas pressure in the projectile. In this way, automatic control of the gas pressure can be achieved, where practically the same gas pressure is produced in the chamber to control the release, irrespective of the projectile configuration.

As the piston and transducers traverse the bullet passage in the structure of the present invention, the impact rod is moved only slightly, depending on the design. The trap itself releases only when the bullet has left the bullet passage.

Due to the above effects, the firearms implemented by the gas discharge device according to the invention allow a more accurate firing of the prior art.

Λ In the structure of the invention, the locking mechanism preferably consists of ball or annular locking members which are in forced release engagement with the actuator member.

The damping mechanism acting against the displacement of the piston away from the chamber's orifice mouth is preferably designed as an auxiliary spring, but can also be implemented, for example, by means of a hydraulic or pneumatic cylinder-piston assembly.

The damping mechanism delays the initiation of the latch release process so that it can begin only after the bullet has flown from the lane.

According to the invention, it is expedient to form the piston in a tubular manner and to arrange the closed end of the piston facing the landing gear in its resting position at a distance from the impact rod to the clearance. At the opposite end of the piston, however, there is a fixed block which extends into the open end of the plunger at a depth corresponding to the clearance when the plunger is at rest, and a gas throttle is provided between the plunger and the plunger.

Preferably, the billet is formed or secured with a cap screwed into the chamber.

The auxiliary spring, which acts as a damping device, is preferably disposed between the end of the piston facing the shock rod and the end of the shock rod facing the piston.

Preferably, the piston is of annular cross-section and is embedded around the projectile passage, the aperture of the piston being formed by an annular groove formed in the inner wall of the piston and at least one axial bore communicating with the annular groove.

The latter design is especially suitable for space utilization and is therefore particularly useful for pistols.

In this latter embodiment, the auxiliary spring is preferably coupled to a firearm locking mechanism with an axially displaceable sleeve which cooperates with the projecting portion of the impact bar extending into the locking mechanism.

In this case, the trigger bar preferably reaches the range of the cock of the firing device of the firearm, while the damper springs of the cock serve as a damping mechanism.

As mentioned above, the locking mechanism may be formed of ball or annular locking elements. The locking elements are disposed radially movable in the slots of the fire barrel of the firearm and, in the locked position, both lie in a circumferential annular groove formed by a suitable cross-section and secondly slidably embedded in the barrel and connected to the shock bar. Preferably, the end of the control mouth facing the gun barrel narrows.

The invention will be described in more detail with reference to the drawing. In the drawing it is

Figure 1 is a longitudinal sectional view of an exemplary embodiment of the gas outlet device of the present invention; the

Figure 2 is a sectional view II-II of the structure of Figure 1; the

Figure 3 is a longitudinal sectional view of a further embodiment of the gas outlet device according to the invention; the

Figure 4 is a sectional view A-A of the structure of Figure 3.

As shown in Figures 1 and 2, the gas outlet device of the present invention is incorporated into a weapon housing 1 associated with a firearm support (grip) not shown in the drawing, which also includes a weapon barrel for a pistol. The projectile passage 20 in the barrel 2 is sealed by a barrier 4 on the side 3 on the cot bed side. The trap 4 can be locked by means of a locking element 5 formed as a torus segment delimited by two parallel surfaces (Fig. 2). The locking member 5 is movably housed in a slit 6 formed obliquely relative to the longitudinal axis of the trap 4 and, when locked (in the position shown in Figures 1 and 2), protrudes into the circumferential annular groove 7 formed in the housing. The annular groove 7 has a cross section corresponding to the torus segments of the locking member 5.

Within the hatch 4, a control member 8 is displaceably embedded in the longitudinal direction, the piston-shaped front portion 9 of which is supported by the locking member 5 in the locked position. The front portion 9 of the control member 8 has a conical profile 10 at its free end. The actuator member 8 further has an internal axial bore for receiving a pin 11 and a spring 12.

At the mouth of the barrel 2, it is secured to the barrel 13 on its mouth dampers 13. A chamber 14 is formed in the area of the gun mouth, which is bordered and substantially sealed by a barrel 1, a bullet wall 20, a mouth damper 13, and a piston 15 which is displaceably embedded around the bullet 20. The axial length of the annular piston 15 is relatively large. The annular plunger 15 is provided with a connecting aperture formed as an annular groove 16 in the region of its opposite end to the barrel flange, which is formed as an annular groove 18 towards the projectile barrel. The axial width of the annular groove 16 is to be dimensioned according to the aspects described below. The annular groove 16 is connected to the projectile passage 20 at a gas discharge hole 19 near its opposite end to the barrel mouth. '

The annular piston 15 is secured by a locking spring 22 resting on a support surface 21 in the region of the tank bed when the piston 15 is at rest. In Figure 1, the annular piston 15 is shown in this resting position.

The annular piston 15 is rigidly connected to the ram 23 arranged parallel to the projectile passage 20, and the opposite end of the piston 15 extends to the trap 4 and is provided with a transverse projection 24. The protrusion 24 extends through an orifice cutout 25 and a cutout 26 in the control member 8 to an axially displaceable sleeve 27 in the hinge member 8, wherein the sleeve 27 is supported by a spring-loaded end 28 disposed at its opposite end.

As shown in Figure 2, the locking member 5 is provided with a rectangular cutout 29 on its upper part for better space utilization, which allows the guide bar 23 to be guided.

At a certain distance from the support surface 21, at a distance corresponding to the combined lengths of the locking spring 22 in its compressed state and the annular piston 15, a gas outlet 30 is provided on the wall of the cylinder 1 to ensure perfect ventilation of the chamber.

The above structure works as follows:

After the cartridge is fired, the pressure of the firing powder exerts a pressure on the impact plate 4, while the lock 4 is locked by the locking element 5 which protrudes into the annular groove 7. The locking plate 5, on the other hand, exerts a radial compression force on the front part 9 of the control member 8, which exerts a frictional force acting on the control member 8. After the projectile has passed through the gas discharge bore 19, a portion of the firing gas passes through the gas discharge bore 19 and is passed through the annular groove 16 and the axial bore 18 of the annular piston 15 in the chamber 14. As a result, a compression force exerted on the annular face 17 of the annular plunger 15 is exerted backward by the force exerted by the prestressed locking spring 22 and by the tensioning force exerted by the prestressing spring 28 on the sleeve 27 affects the 15 pistons. The piston 15 is pushed back by the pressure of the firing gas, while the piston 15, after having traveled the width of the annular groove 16, closes the gas discharge holes 19, thus preventing the flow of further quantities of fired powder into the chamber 14.

At the same time, it extends with the projection 24 of the ram 23 at a distance equal to the displacement of the piston 15. The cutout 26 formed in the guide member 8 should be formed at a width at least corresponding to this displacement, thereby ensuring that the initial displacement of the piston 15 does not affect the position of the guide member by its displacement at the aforementioned distance. In this way, a kinematic relationship between the piston and the control member results in a play which causes the opening process of the shutter 4 to begin only when the chamber 14 is closed towards the projectile passage 20. The chamber 14 then has a precise gas pressure.

Apart from the aforementioned initial displacement of the piston 15 and the ram 23, no other mass acceleration occurs during the process and thus, until the projectile has left the projectile passage 20, its disturbing forces do not act as a firearm.

After the projectile leaves the projectile passage 20, the projecting portion 24 of the impact bar 23, at its rear end, collides with the cutout 26 of the control member 8 and pushes the control member backward. As a result, the front portion 9 of the control member 8 slides away from the locking member 5 and releases it. The locking member 5 is then moved inwardly in the slot 6 by the radial component of the locking member mediated by the annular groove 7 and releases the lock 4. The shutter 4 opens due to the pressure of the firing powder. The control member 8, on the other hand, rests on a stop plate 32 which is fixed on the rear wall of the trap 4.

The locking mechanism then moves backward against the force of the locking spring 22 until the piston 15 strikes the support surface 2a and completely compresses the locking spring 22. In this position, the projectile passage 20 is completely vented through the gas outlet 30.

The locking spring 22 then returns the locking mechanism to its stationary position, whereby the protruding portion 23 of the strut 23 advances the control member 8 and pushes the locking member 5 into the annular groove 7 with its conical profile 10 of the front member 9.

Λ the firing of the firearm, the disposal of the hollow cartridge and the loading of a new cartridge are carried out in a known manner.

The above firearm may be designed in a variant in which the auxiliary spring 28 acting directly on the sleeve 27 takes over the impact spring of the firing gun's cock. In this case, as shown in the right part of Figure 1, the bumper 23 must be extended to the cock 33, and the cock 33 must be provided with an overlay cooperating with the bumper 23.

In the embodiment shown in Figs. 3 and 4, the locking of the trap 4 is secured by a ball (Fig. 3) or by two torus segments (Fig. 4) 5. The locking elements 5 are movably housed in the bore holes of the trench 4 and extend into a circumferential annular groove 7 which is fixed relative to the projectile passage 20. In this embodiment, it should be borne in mind that the use of larger cartridges requires greater masses and greater travel paths for the locking mechanism components.

The chamber 14, connected to the projectile passage 20 through the gas outlet bore 19, is formed in a cylinder 34 fixed on the barrel 2. Further, in the cylinder 34 the hollow piston 15 is slidably mounted. The ram 23 is aligned with the piston 15 such that a gap corresponding to the clearance is maintained between the piston 15 and the piston 15 at rest (in the position shown in Figure 3). At the end of the ram 23 facing the piston 15 is an annular shoulder 36 which is supported by a supporting spring 28 which is pulled to the end of the ram 23 and depressed on the face of the piston 15 facing the ram 23.

The hollow piston 15 is tubular in shape with a closed front face facing the impact rod 23 and an open opposite face face. From the open end of the piston 15, a stump 37 protrudes into the interior of the piston 15. The billet 37 is formed in a cap 38 threaded onto the roller 34. The axial extension of the billet 37 corresponds to the distance between the piston 15 and the ram 23 at rest.

A circumferential cutout 39 is formed on the mantle 37 to form a gas choke between the stub 37 and the piston 15. The piston 15 thus functions as a differential piston.

In the region of the gas discharge bore 19 of the projectile passage 20, the piston 15 is provided with an opening formed by a gap 40 formed from the gas discharge bore 19 in the direction of the funnel mouth parallel to the piston axis. The width of the gap 40 corresponds to the distance between the piston 15 and the ram 23 at rest.

-4Ί

The gas outlet 30 is spaced from the end of the gap 40 to the barrel.

The ram 23 passes through the opening of a projection 21 forming a support surface 21 downstream of the barrel, where the locking spring 22 is pressed against the support surface 21. The other end of the locking spring 22 rests on the annular shoulder 36 of the strut 23. At the distal end of the bar 23, the barrel is provided with a protruding portion 24, the end of which is engaged by the control member 8 in a form-locking manner. The protrusion 24 has a handle 41 and is thus designed as a tensioning valve. As in the previous embodiment, the control member 8 is disposed axially displaceable inside the trench 4 and has a conical profile 10 at the end of its front part 9.

The protruding portion 24 of the ram 23 is guided through the cutout 25 in the trap 4. The cutout 25 must be dimensioned such that its axial width ensures that the control member 8 can be displaced to allow the locking members 5 to move freely.

All impact pins 12 are arranged inside the control member 8 with a spring 12.

The above structure works as follows:

When the cartridge is fired, the projectile gases exert pressure on the 31 blades of the 4 shutters. The impact plate 31, on the other hand, is in the locked position by the locking elements 5, which are located in the circumferential annular groove 7 - balls or torus segments. Due to the forces exerted on the annular groove 7, the locking elements 5 exert a force on the control member 8 which prevents the control member 8 from moving.

As the projectile passes over the gas discharge hole 19, the firing powder gases flow into the chamber 14 through the gas discharge hole 19 and the gap 40 of the tubular piston 15. The pressure of the firing powder gas entering the chamber 14 first exerts a force on the front surface 17a of the piston 15, whereby the piston 15 is displaced against the end of the thrust bar against the force exerted by the auxiliary spring 28. After the piston 15 has moved at a distance corresponding to the clearance, the overlap between the slot 40 and the gas outlet bore 19 is eliminated, thereby preventing the introduction of firing powder gases into the chamber 14.

No further movement or mass acceleration occurs until the projectile has flown out of the 20 projectile passages, so that the firearm is not subject to disturbing forces.

After the projectile leaves the projectile passage 20, the gas pressure acting on the front face 17 of the shutter 4 is reduced, which also reduces the retaining force exerted by the latch members 5 on the control member 8. The fired powder gas enclosed in chamber 14 flows through the gas throttle formed between the bulge 37 and the piston 15 to the annular surface 17 of the piston 15, thereby exerting increased pressure. This pressure pushes the piston 15 together with the ram 23 and the control member 8 until the conical profile 10 is formed at the beginning of the front end 9 of the control member 8 and then the front part 9 is at the height of the locking elements 5. The locking elements 5 can then move inward in a radial direction and the shutter 4 becomes lockable with a lockable lock. Trigger 4 is triggered by forces acting in the annular groove 7; which push the locking elements 5 in their holes or guides radially inward.

The trap 4 then moves backwardly from the projection 24 at the rear end of the cutout 25 to the stop plate 32 as a result of the firing gases enclosed in the chamber 14. The empty cartridge can be removed from the firearm in a known manner using a ejector. The piston 15 is located at an end position defined by the collision shoulder 35, at which end the gas in the chamber 14 may be discharged through the gas outlet 30.

At the end of the process, the locking mechanism returns to its resting position by the force exerted by the locking spring 22. As the damper 4 moves forward until it rests on the cartridge bed 3, the locking members 5 slide upwardly radially outward on the conical profile 10 of the hinge member 8 and engage in the annular groove 7. The shutter 4 is then locked again. The piston 15 is pushed back into its resting position by the force exerted by the auxiliary spring 28.

As shown in the drawing, the plunger 15 can be removed from the chamber 14 after unscrewing the cap 38.

The gas outlet device of the present invention, even with a deviation of ± 30% of the nominal value of the gas pressure, provides flawless, reliable operation and allows the use of different types of cartridges.

Pistons 15 and chambers 14 of various shapes and sizes may be used in the structure of the present invention and may be easily replaced if necessary. The cap 37 formed on the cap 38 is also interchangeable as required. The invention thus enables the gas outlet device to be constructed according to a building block. The structures of the invention can therefore be easily fitted to a variety of weapon caliber and cartridge types.

The use of cartridges used in conventional weapons is eliminated by the present invention.

Hydraulic or pneumatic shock absorber systems may be used in place of the auxiliary spring 28 or the cock spring spring of the cock 33 in the structure of the invention. The degree of damping must be dimensioned such that the piston 15 closes the gas outlet bore 19 when sufficient gas pressure is created in the chamber 14 to displace the control member 8, so that the movement of the control member 8 begins only after the projectile leaves the projectile passage 20. . This ensures that the firing range of the firearm is not affected by interfering side effects from the gas outlet.

Claims

Claims (9)

A gas discharge device for firearms, wherein a piston is displaceable in a chamber connected to the firearm's firing passage through a gas discharge bore, parallel to the firing passage axis, at its resting position by a firing barrel extending close to the firing barrel. -510 only, wherein the chamber is provided with an open gas outlet, characterized in that the gas outlet (19) is spaced from the end of the chamber (14) at a distance between the ends of the plunger (15) at rest; configured, wherein the piston (15) has an opening connecting the piston (15) to the gas outlet (19) at rest and the kinematic relationship between the piston (15) and the latching mechanism in the projectile direction and a damping mechanism for moving the piston (15) away from the barrel mouth, and the opening (g) of the piston (15) at least at the end of the gas outlet (19) at the gun port is widened to an extent appropriate to the play, and the piston (15) in its offset position closes the gas outlet (19). 20 Gas outlet device according to Claim 1, characterized in that the damping mechanism acting against the displacement of the piston (15) in the direction of the distal end of the chamber (14) is formed as an auxiliary spring (28). Gas outlet device according to Claim 1 or 2, characterized in that the closed end of the piston (15), which faces the stroke bar (23), is located at a distance from the stroke bar (23) which corresponds to the play, and the stump (37) fixed at the opposite end of the plunger (15) extends into the resting position of the plunger (15) at a depth corresponding to the play, wherein a gas choke is formed between the stump (37) 35 and the plunger (15). Gas outlet device according to claim 3, characterized in that the billet (37) is arranged on the cap (38) fixed to the chamber (14). 40 Gas outlet device according to Claim 3 or 4, characterized in that the auxiliary spring (28) is arranged at the opposite ends of the impact rod (23) and the piston (15). Gas outlet device according to Claim 1 or 2, characterized in that the piston (15) is of annular cross-section and is embedded around the projectile passage (20), wherein the opening of the piston (15) is arranged inside the piston (15). and an at least one axial bore (18) communicating with the annular groove (16). Gas outlet device according to Claim 6, characterized in that the auxiliary spring (28) is provided with a sleeve (27) which is displaceable axially within the locking mechanism of the firearm, and the sleeve (27) protrudes into the locking mechanism (23). 24) in a power transmission relationship. Gas outlet device according to Claim 6, characterized in that the shock bar (23) extends to the region of the firearm's firing cock (33) and the damping rock is formed by the shock spring of the cock (33). 9. Figures 1-8. Gas outlet device according to any one of claims 1 to 4, characterized in that it has a rigid locking mechanism made of ball or annular locking elements (5), wherein the locking elements (5) are displaceably disposed radially in the slots (6) of the fire barrel (4). on the other hand, they are supported by a guide member (8) slidably embedded in the impeller (4) and having a decreasing diameter at its end facing the barrel of the barrel.