RU2165577C2 - Automatic firearm - Google Patents

Abstract

FIELD: armaments, may be applicable in automatic firearm. SUBSTANCE: the automatic firearm has a fixed barrel and a movable bolt. The bolt consists at least of two separate parts made for engagement with one other and for movement relative to each other. The first part of the bolt is made for coupling to the barrel after the cartridge case has partially come out of the barrel chamber. The first part of the bolt is made for direct engagement with the cartridge case, and the second part of the bolt is made for engagement with the cartridge case by means of the first part of the bolt. The second part of the bolt is made for uncoupling and coupling of the first part of the bolt with the barrel. EFFECT: enhanced reliability of operation, reduced mass of firearm. 4 cl

Description

 The invention relates to automatic devices and relates, in particular, to automatic weapons, such as handguns.

 The prior art.

 Among the currently known automatic weapons, the simplest, by design, is an automatic weapon, the principle of automation of which is based on the return of a free (unconnected with the barrel) shutter.

 The advantage of an automatic weapon with a free shutter: automatic reloading of weapons is carried out due to the energy of powder gases, and at the same time there is no gas engine (as a separate automation unit), the function of which is performed by the barrel chamber and cartridge case. This greatly simplifies the design of automatic weapons, reduces its size and weight.

 Disadvantages of automatic weapons with a free bolt: allows the use of only cartridges of relatively low power with a short sleeve, which limits the ballistic properties of weapons of this type; the leading link of the automation (free shutter) is informed of all the recoil energy, which in many cases is more than necessary for the automatic reloading of weapons - this increases the level of shock loads acting on the moving parts of the automation, which reduces the resource of the above automation parts.

 Closest to the claimed invention is an automatic pistol M-51, produced in the 20th century by the American company Remington, known from (Hogg J. All pistols of the world. M: Eksmo, 1997, pp. 239-240, [1]) . This gun has a barrel fixedly attached to the frame of the gun, which has a combat ledge, and a movable bolt, consisting of two separate parts - from the bolt itself and from the casing. The bolt has a combat supporting surface, made with the possibility of interaction with the combat projection of the pistol frame. The shutter is made with the possibility of direct interaction with the cartridge sleeve, which at the time of the shot performs the function of a piston of a gas engine of automation. The shutter is made to engage the barrel (by skewing the shutter) after it (the shutter) at the time of the shot moves away from its extreme forward position by a distance of 0.17 inches (4.3 millimeters (mm)) and after the sleeve the cartridge will come out of the barrel chamber by the same amount. The casing, which is the leading link in automation, is configured to interact with the shutter and to move relative to the shutter. The casing is configured to interact with the cartridge sleeve by means of a shutter. The casing is configured to provide clutch and disengage of the bolt from the barrel. There is also a return spring, made with the possibility of interaction with the casing and the frame of the gun.

 The work of the prototype is as follows.

 Until the start of the propellant charge, the shutter and the casing are pressed by the return spring to their extreme forward positions, and the next cartridge is located in the barrel chamber. At the same time, there is a distance of 4.3 mm between the combat support surface of the bolt and the combat projection of the pistol frame.

 After the start of the action of the propellant charge, its pressure begins to act on the bottom of the sleeve and the latter begins to come out of the barrel chamber. In this case, the cartridge sleeve acts on the shutter, and he, in turn, acts on the casing. Thus, immediately after the start of the propellant charge, the cartridge sleeve, the shutter and the casing move back together and with equal linear speeds (motionless relative to each other). Essentially, at a given point in time, the shutter and casing behave like a regular free shutter, consisting of two separate parts.

 After moving away from its extreme forward position to a distance of 4.3 mm, the bolt abuts against the piston frame’s combat projection with its combat supporting surface and thereby ceases its movement relative to the barrel (i.e., the bolt engages with the barrel). At this point in time, the cartridge case has also left the barrel chamber by the same amount as the bolt from its extreme forward position. In this case, until the bolt engages with the barrel, the cartridge sleeve (piston of the gas engine of automation), through the shutter, informed the casing (the driving link of the automation) of the amount of kinetic energy necessary for automatic reloading of the weapon and the required linear speed.

 After the bolt engages with the barrel, the casing continues its inertia movement in the same direction (in the direction of its extreme rear position), compressing the return spring in the direction of its movement (that is, the casing starts to move freely).

 Then, after some time, the free movement of the casing ends and it disengages the bolt from the barrel (unlocks the bore) and, in the course of its further movement in the same direction, carries the bolt along with it. Then the cartridge case is removed beyond the arms, and the bolt and casing in the direction of their movement from their extreme rear positions to the extreme front positions feed the next cartridge into the barrel chamber, and when they reach their extreme front positions, they occupy the same position as described above . In the future, everything is periodically repeated (with each shot).

 Advantages of the prototype: the lower weight of the moving parts of the automation, and therefore the weight of the weapon as a whole (for example, compared with a weapon with a free shutter), since due to the possibility of coupling (at a certain point in time) the shutter with the barrel to the moving parts of the automation, not all recoil energy; lower level of shock loads acting on moving parts of automation and on parts interacting with them (since not all recoil energy is communicated to moving parts of automation); lower (according to the description of the pistol) recoil force, in comparison with weapons of other types.

 The disadvantages of the prototype: the low resource of the combat supporting surface of the shutter and the interacting combat protrusion of the pistol frame due to their shock loading at the moment of coupling of the bolt with the barrel (at the moment of coupling of the bolt with the barrel, the shutter has a speed relative to the barrel of 6-7 meters per second - such a linear speed must have the leading link of automation (casing) so that reliable operation of the automation is ensured - and until the bolt engages with the barrel, the shutter and casing move with equal linear speeds); This automation scheme, apparently, cannot be used for automatic (and more powerful) ammunition, since it is hardly possible to release shells of such cartridges of this magnitude from the barrel chamber (due to the possibility of breaking the walls of the shell with a propellant charge, since at this point the barrel chamber has already come out sections of the liner with thin walls). All this under the assumption that the cartridge sleeve should go out of the barrel chamber exactly at such a value in order to inform the automation leader that the amount of energy necessary for automatic reloading is required. If the cartridge case is released from the barrel chamber by a smaller amount, which guarantees that there is no rupture of the cartridge case walls with a propellant charge, then, apparently, the amount of kinetic energy insufficient for automatic reloading will be reported to the leading link of the automation.

 SUMMARY OF THE INVENTION

 The task of the invention is to eliminate the disadvantages of the prototype.

 Obviously, if such a problem can be solved, then this is a "non-obvious" solution for a specialist versed in the field of automatic weapons, since the prototype has not solved it.

 The claimed invention as an automatic pistol, in one of the possible variants of its execution, has the following essential features common with the prototype: fixed barrel; movable shutter, consisting of two separate parts; the second shutter part is movable relative to the first shutter part; the second shutter part is configured to interact with the cartridge sleeve by means of the first shutter part; the first shutter member is capable of engaging with the barrel after it has moved a certain distance from its extreme forward position and after the cartridge sleeve has partially come out of the barrel chamber; the second shutter part is configured to disengage the first shutter part from the barrel.

 A distinctive feature of the prototype is: until the first shutter part engages with the barrel, the second shutter part is configured to accelerate relative to the first shutter part.

 The presence in the claimed invention of the above essential feature allows him to have the following. Due to the accelerated movement of the second part of the shutter relative to the first part of the shutter (from the moment the propellant starts to act until the first part of the shutter engages with the barrel), which, for example, can be carried out like the famous German assault rifle G3 ([2]) (that is , due to the use of a deceleration mechanism in the weapon), the driving link of the automation (the second shutter part), the cartridge sleeve (piston of the gas engine of the automation) will be informed of the amount of kinetic required for automatic reloading of the weapon of energy, but no more, and at the same time, the landing of the protrusions of the first shutter part on the pistol frame stops (at the moment of the first shutter part engaging with the barrel) will be carried out at a several times lower linear speed (compared to the prototype) ( which is ensured by the action of the deceleration mechanism). This will several times reduce the level of shock loads acting on the combat protrusions of the first shutter part and on the stops of the pistol frame, and therefore, increase the resource of the above weapon parts (compared to the prototype).

 Due to the accelerated movement of the second shutter part relative to the first shutter part (at the above time point) in the claimed invention, the moving parts of the automation will have less mass than the prototype, and therefore, the claimed invention will have a smaller mass of weapons as a whole. Due to the above accelerated movement of the second shutter part relative to the first shutter part of the claimed invention, the cartridge sleeve, by the moment the first shutter part engages with the barrel, will come out several times smaller from the barrel chamber (as compared with the prototype), which will make it possible to use in the claimed invention more powerful (compared to the prototype) ammunition.

 Thus, the claimed invention has the following advantages compared with the prototype: less weight of moving parts of automation and less weight of weapons in general; greater resource of moving parts of automation; better ballistic properties (due to the possibility of using more powerful ammunition).

 In the claimed invention, as its propellant charge, any of its type (gunpowder, compressed gas, etc.) can be used. The shutter may consist of more than two separate parts (for example, the second shutter part may consist of at least two separate parts, made with the possibility of interaction between each other and made with the possibility of movement relative to each other). The first and second shutter parts can interact with each other either directly or by means of intermediate parts - rigidly or resiliently (for example, by means of a spring). The second shutter part can interact with the cartridge sleeve either by means of the first shutter part (and / or by other parts) or directly.

 The first (and / or second) shutter part in the claimed invention can move along the axis of the bore or at some (not equal to zero) angle to it, for example, as is the case with the Finnish Jati-Matic submachine gun [2].

 The engagement of the first shutter part with the barrel in the claimed invention can be carried out in any suitable way (by turning the first shutter part around its longitudinal axis, by skewing the first shutter part, using a wedge, etc.). At the same time, this clutch can be implemented either by acting on the first shutter part of the second shutter part or by acting on the other shutter part of other parts (for example, due to the action of a spring).

 In the claimed invention, the interaction of the first part of the shutter with a propelling charge can be carried out either by means of a cartridge sleeve (for example, a cartridge sleeve of a conventional unitary metal cartridge) or by means of a pallet (which is, for example, the bottom of the cartridge case with a part of the cartridge case) or by means of a piston (for example firmly attached to the first shutter part). Thus, obturation (preventing gas breakthrough into the shutter mechanism) in the claimed invention can be carried out either with a cartridge sleeve or with a pallet or piston.

 An embodiment of the claimed invention is possible when it has several chamber, for example, made in the form of a drum. In this case, the energy of the leading link of automation is used to rotate the drum.

 Information confirming the possibility of carrying out the invention.

 In the embodiment of an automatic pistol, in one of the possible variants of its design, the claimed invention is as follows.

 There is a table fixedly attached to the frame of the pistol, which has combat stops (ledges), and a movable shutter, consisting of two separate parts. The first part of the shutter has combat projections made with the possibility of interaction with the stops of the pistol frame. The first shutter part is designed to interact with the cartridge sleeve, which at the time of the shot serves as a piston of a gas engine of automation. The second shutter part, which is the leading link in the automation, is configured to interact with the first shutter part by means of a retardation mechanism (for example, a roller retardation mechanism or a retardation lever) and can be moved relative to the first shutter part. The second shutter part is configured to interact with the cartridge sleeve by means of the first shutter part. The first part of the shutter is made with the possibility of coupling with the barrel after it has moved a certain distance from its extreme forward position and after the cartridge sleeve has partially come out of the barrel chamber. The second shutter member is configured to provide engagement and disengagement of the first shutter part from the barrel. There is also a return spring, made with the possibility of interaction with the second part of the shutter and with the frame of the gun.

 The above gun works as follows. Until the powder charge is ignited in the cartridge located in the barrel chamber, the return spring presses the second shutter part to its extreme forward position, and it, by means of the retardation mechanism, acts on the first shutter part, which is pressed by the edges of its cup to the breech section of the barrel. Thus, before ignition of the powder charge, the first and second shutter parts are in their extreme forward positions, are stationary relative to the barrel (and are not engaged with the barrel). Between the combat protrusions of the first shutter part and the stops of the pistol frame there is a distance equal to ≈2 mm (the combat protrusions are located opposite the stops).

 After ignition of the powder charge in the cartridge located in the chamber of the barrel, the bullet (due to the action of the pressure of the powder gases on its bottom part) starts moving along the barrel channel in the direction of its muzzle end, and the cartridge case (due to the action of the pressure of powder gases on its bottom part ) begins to exit the chamber of the barrel in the direction opposite to the movement of the bullet. The cartridge sleeve with its bottom part acts on the first shutter part, and it, in turn, acts through the retardation mechanism on the second shutter part.

 Thus, after ignition of the powder charge of the cartridge case, the first and second shutter parts move in the same direction (along the axis of the barrel channel), that is, they move in the direction from their extreme forward position to their extreme rear position. In this case, the cartridge sleeve and the first shutter part move with equal linear speeds, and the second shutter part moves (due to the action of the deceleration mechanism) accelerated relative to the first shutter part.

 After the first shutter part has moved away from its extreme forward position by a distance of ≈2 mm (the cartridge sleeve from the barrel chamber has reached the same distance), its combat protrusions abut against the stops of the gun frame and thereby stop its movement relative to the barrel (i.e., the first shutter part engages with the barrel). In this case, the cartridge case also stops its movement relative to the barrel. Prior to the moment of engagement of the first shutter part with the barrel by the cartridge sleeve (piston of a gas engine of automation), the second shutter part (the driving link of automation) the amount of kinetic energy necessary for automatic reloading of the weapon was reported, but nothing more.

 After the first part engages with the barrel, the second shutter part continues its inertia movement in the same direction (compressing the return spring in the direction of its movement), that is, the free movement of the second shutter part begins. At this time, the bullet continues its movement along the bore, and the bore is still locked (in the sense that there are no leakages of powder gases through the breech of the barrel).

 After a bullet leaves the barrel channel, the free movement of the second shutter part ends and it unlocks the barrel channel (disengages the first shutter part from the barrel) and, in the course of its further movement in the same direction, carries the first shutter part and cockes the trigger.

 In the future, everything happens in the same way as with an automatic weapon with a locked bore. The cartridge case is removed beyond the limits of the weapon. The first and second shutter parts along the course of their movement from the extreme rear to the extreme front positions feed the next cartridge into the barrel chamber. When it comes to its extreme forward position, the second shutter part thus acts on the first shutter part so that its combat protrusions are installed opposite the pistol frame stops (at a distance of ≈2 mm from the frame stops) - the barrel channel is locked. Then, with the next shot, the first shutter detail with its combat protrusions (after it moves away from its extreme forward position ≈ 2 mm) again rests against the pistol frame stops, and then everything will repeat (as described above).

 Thus, due to the interaction of the first shutter part with the second shutter part by means of the deceleration mechanism, the second shutter part (the driving link of the automation) communicates with the cartridge sleeve (piston of the gas engine of automation) the amount of kinetic energy necessary for automatic reloading of the weapon, but nothing more. At the same time, the cartridge case, until the first bolt part engages with the barrel, leaves the barrel chamber by an acceptable value of ≈2 mm, when the thin walls of the cartridge case have not yet come out of the barrel chamber, and the fighting protrusions of the first shutter part are mounted on the frame stops from several times lower linear speed (compared with the linear speed of the second shutter part at the moment of engagement of the first shutter part with the barrel). This allows you to: reduce the mass of moving parts of automation (in comparison with the case when, before the first part of the shutter engages with the barrel, the first and second shutter parts move with equal linear speeds); increase the resource of the combat protrusions of the first shutter part and the pistol frame stops (as compared with the case when the combat protrusions of the first shutter part on the pistol frame stops are at the same linear speed that the second shutter part has at the moment of engagement of the first shutter part with the barrel) ; use in the claimed invention ammunition of theoretically any power (since the use of a retardation mechanism (with any power of the ammunition used in it) will allow the cartridge sleeve to exit the barrel chamber (until the first bolt part engages with the barrel) by the required amount, eliminating wall rupture sleeves with a throwing charge).

 Thus, the claimed invention (in comparison with the prototype) will have: less weight of the moving parts of the automation, and therefore, less weight of the weapon as a whole; greater resource of moving parts of automation; allows you to use ammunition in it theoretically of any power, which increases its ballistic properties.

 A possible embodiment of the claimed invention, when it has a second shutter part, consists of at least two separate parts, made with the possibility of interaction between each other and with the possibility of moving relative to each other. In this case, the disengagement of the first shutter part from the barrel provides another part of the second shutter part.

 An embodiment of the claimed invention is possible when it has no first shutter part (as such), and the second shutter part interacts directly with the cartridge sleeve. In this embodiment, at the moment of the shot, the cartridge case leaves the barrel chamber and reports the amount of kinetic energy of the second shutter part necessary for automatic reloading and then, after partial exit from the barrel chamber, rests against the wedge with its bottom part and thereby stops its movement relative to the barrel (the wedge is stationary relative to the trunk). In this case, the wedge has a special cutout through which the second shutter part passes. Otherwise (in principle) everything happens the same way as in the case considered above. Namely, at the required moments of time, the second shutter part moves the wedge (when unlocking and locking the bore), removes the sleeve from the barrel chamber and removes it outside the weapon.

 An embodiment of the claimed invention is possible when it has a shutter made stationary (for example, made in the form of a single part), and the barrel is made to move forward (for example, under the action of friction from the side of a bullet moving in the barrel channel, that is, in the same way as with a well-known automatic weapon with a forward-moving barrel). Moreover, there is an additional inertial body made with the possibility of interaction (rigid or elastic) with the barrel and made with the possibility of movement relative to the barrel and relative to the shutter. The inertial body is configured to interact with the propellant charge through the barrel. The inertial body serves to disengage the barrel from the bolt at the right time — when the bullet has already left the barrel. The barrel engages with the bolt after the cartridge sleeve (or the pallet or piston), which is made interacting with the bolt, partially leaves the barrel chamber (i.e., the barrel and bolt engage after the barrel moves to some (not equal to zero) ) the distance from its extreme rear position - will move a certain distance from the fixed shutter). From the moment the propellant charge begins to act until the barrel engages with the bolt, the barrel and inertial body move with equal linear speeds and are motionless relative to each other (however, it is possible that at the given moment the inertial body moves accelerated relative to the barrel (for example, by using the retardation mechanism used by the German assault rifle G3 [2]). After the barrel is engaged with the bolt, the inertial body continues its inertia movement in the same direction through For some time, it disengages the barrel from the bolt and then carries the barrel along with it. Otherwise, the automation works in the same way as conventional automatic weapons with a forward-moving barrel. The barrel can be engaged with the bolt by acting on the barrel or an inertial body or otherwise weapons details, while this clutch itself can be carried out in any acceptable way (for example, by turning the barrel around its longitudinal axis). In this embodiment, the cartridge sleeve (or pallet or piston), after the barrel engages with the bolt, stops moving relative to the barrel. A variant is possible when the barrel (after a partial exit of the cartridge case from the barrel chamber) does not engage with the shutter, but slows down its movement relative to the shutter (otherwise, the automation works unchanged (in principle)).

 In the embodiment of the claimed invention, when its barrel is stationary, and the shutter, consisting of two separate parts, is movable, it is also possible that after a partial exit of the cartridge case from the barrel chamber the first shutter part does not engage with the barrel, but slows down its movement relative to the trunk (ceteris paribus).

 The claimed invention can be used as any automatic weapon (not only a firearm), both manual and as an artillery weapon (for example, as a gun). It can be automated with him as all the processes associated with reloading weapons, and only a part of them.

 In the claimed invention, in the embodiment with a fixed barrel and a movable shutter, the first shutter part can interact with the cartridge sleeve (or pan or piston) either directly or by means of an intermediate part (or parts).

 In the claimed invention, the choice of the path length traveled by the first shutter part (in the version with a movable shutter) or the barrel (in the variant with a forward-moving barrel) until they engage (or slow down) with the barrel or shutter, respectively (this path may not be equal ≈2 mm, as in the case considered above), it is possible to tell the leading link of the automation the necessary amount of kinetic energy (necessary for automatic reloading of the weapon), but no more.

References
1. Hogg I. All pistols of the world. M .: Eksmo, 1997, p. 239-240.

 2. Murakhovsky V.I., Fedoseev S.L. Weapons of infantry. M .: Arsenal-Press, 1997, p. 152, 228.

Claims (4)

 1. Automatic weapons containing at least one barrel and bolt, cartridge case, or pan or piston, the possibility of stopping movement relative to the barrel or the possibility of slowing down relative to the barrel after they partially come out of the barrel chamber, due to that the barrel is stationary and the shutter is movable, while the shutter consists of at least two separate parts made with the possibility of interaction with each other, and the second shutter part is made with the possibility of per room relative to the first part of the shutter, which is made with the possibility of interaction with the sleeve of the cartridge, or pallet, or piston and with the possibility of adhesion to the barrel or with the possibility of slowing down relative to the barrel after it moves a certain distance from its extreme forward position and after , like a cartridge sleeve, or a pallet, or a piston partially come out of the barrel chamber, while the second shutter part is configured to ensure that the first shutter part is disconnected from the barrel and ozhnostyu interaction with a sleeve or cartridge pan or piston means of the first shutter parts, characterized in that before the coupling the first part with the barrel or deceleration until the first shutter parts relative motion of the barrel the second item gate configured to accelerated motion relative to the first valve part.  2. The automatic weapon according to claim 1, characterized in that the second shutter part consists of at least two parts configured to interact with each other and to move relative to each other.  3. An automatic weapon containing at least one barrel and a bolt, characterized in that the cartridge sleeve, or pallet, or piston is provided with the ability to stop movement relative to the barrel or the ability to slow down relative to the barrel after they partially come out of the barrel chamber due to the fact that the barrel is made to move forward, and the shutter is stationary, while there is an additional inertial body made with the possibility of interaction with the barrel and with the possibility of movement both relative to the barrel and relative to the shutter, the barrel is adapted to engage with the shutter or to slow down relative to the shutter after the barrel has moved a certain distance from its extreme rear position and after the cartridge sleeve or pallet or piston partially come out of the barrel chamber, the inertial body is made with the possibility of disengaging the barrel from the shutter and with the possibility of interaction with the propellant charge through the barrel.  4. The automatic weapon according to claim 3, characterized in that until the barrel engages with the bolt or until the barrel slows down relative to the bolt, the inertial body is capable of accelerated movement relative to the barrel.