Delayed action magazine-based self-loading firearm with gas piston action. Delay action prevents the movement of the self-loading firearm's slide and lock during the actual shot and will keep them closed. The construction of the delayed action stores the energy from the powder gas either mechanically or pneumatically, to be used later for the operation of the firearm's load-lock mechanism. The delayed action mechanism of a delayed action firearm consists of the body (E) and a guide (C) with its openings (D) placed inside it, through which the high-pressure powder gas escapes through the firearm's barrel (A) onward to the gas piston (F), which moves pierced by a pole (H), with the pole (H) being attached to the bottom piece (I). A spring (G) may be connected to the pole (H), with the pressure of the powder gas compressing either the spring (G) or alternatively the air by the gas piston (F) against the bottom piece (I). The retainer (K) stops the gas piston (F) into its back position leaving the spring (G) or air into compression. Through the action of the shooter or a separate automatic mechanism on the releaser (M) the bottom piece (I) is allowed to dash backwards with the help of the spring (G) or air. The bottom piece (I) is fixed to the firearm's slide (O), which uses the firearm's load and lock mechanism to perform the cartridge case removal and loading actions.

Delayed action magazine-based self-loading firearm with gas piston action. Delay action prevents the movement of the self-loading firearm's slide and lock during the actual shot and will keep them closed. The construction of the delayed action stores the energy from the powder gas either mechanically or pneumatically, to be used later for the operation of the firearm's load-lock mechanism. The delayed action mechanism of a delayed action firearm consists of the body (E) and a guide (C) with its openings (D) placed inside it, through which the high-pressure powder gas escapes through the firearm's barrel (A) onward to the gas piston (F), which moves pierced by a pole (H), with the pole (H) being attached to the bottom piece (I). A spring (G) may be connected to the pole (H), with the pressure of the powder gas compressing either the spring (G) or alternatively the air by the gas piston (F) against the bottom piece (I). The retainer (K) stops the gas piston (F) into its back position leaving the spring (G) or air into compression. Through the action of the shooter or a separate automatic mechanism on the releaser (M) the bottom piece (I) is allowed to dash backwards with the help of the spring (G) or air. The bottom piece (I) is fixed to the firearm's slide (O), which uses the firearm's load and lock mechanism to perform the cartridge case removal and loading actions.

An operating system for a firearm includes a forward bolt includes a forward bolt cavity, a carrier disposed on a rear side of the forward bolt, the carrier including a carrier cavity, a short cam pin including (i) a forward section that is at least partially disposed within the forward bolt cavity and (ii) a rear section that is at least partially disposed within the carrier cavity, a plurality of bearings that interface with the forward bolt, a retracted configuration where the short cam pin is in a rear position relative to the forward bolt, and a deployed configuration where the short cam pin is in a forward position relative to the forward bolt.

An operating system for a firearm includes a forward bolt includes a forward bolt cavity, a carrier disposed on a rear side of the forward bolt, the carrier including a carrier cavity, a short cam pin including (i) a forward section that is at least partially disposed within the forward bolt cavity and (ii) a rear section that is at least partially disposed within the carrier cavity, a plurality of bearings that interface with the forward bolt, a retracted configuration where the short cam pin is in a rear position relative to the forward bolt, and a deployed configuration where the short cam pin is in a forward position relative to the forward bolt.

A weapon system that includes a breechblock, which is formed at least by a breechblock carrier and a breechblock head, the breechblock carrier being designed so as to carry the breechblock head. To achieve the fact that forces acting upon the breechblock drive during the unlocking of the breechblock and the withdrawal of a cartridge casing are minimized or even eliminated, the breechblock head is freely movable relative to the breechblock carrier. To separate the breechblock with a breechblock drive of the weapon system during the recoil of the recoiling masses of the weapon system, a device is designed in such a way that a mechanical separation takes place between the breechblock and the breechblock drive during the recoil of the recoiling masses of the weapon system. During the forward motion of the recoiling masses, the mechanical connection between the breechblock drive and the breechblock is reestablished via the device.

A weapon system that includes a breechblock, which is formed at least by a breechblock carrier and a breechblock head, the breechblock carrier being designed so as to carry the breechblock head. To achieve the fact that forces acting upon the breechblock drive during the unlocking of the breechblock and the withdrawal of a cartridge casing are minimized or even eliminated, the breechblock head is freely movable relative to the breechblock carrier. To separate the breechblock with a breechblock drive of the weapon system during the recoil of the recoiling masses of the weapon system, a device is designed in such a way that a mechanical separation takes place between the breechblock and the breechblock drive during the recoil of the recoiling masses of the weapon system. During the forward motion of the recoiling masses, the mechanical connection between the breechblock drive and the breechblock is reestablished via the device.

A pressure controlled inertia system for automatic fire weapons is provided. The system enabling a lock, especially in automatic rifles, to be opened by using a kinetic energy of a mechanism and a sliding handle block, wherein the kinetic energy is lost by hitting a case, after an empty cartridge is fired.

A pressure controlled inertia system for automatic fire weapons is provided. The system enabling a lock, especially in automatic rifles, to be opened by using a kinetic energy of a mechanism and a sliding handle block, wherein the kinetic energy is lost by hitting a case, after an empty cartridge is fired.

A semiautomatic or fully automatic firearm that includes a barrel, the rear barrel end whereof is in the form of a cartridge chamber into which a cartridge can be inserted, a breech body which is arranged such that it can move in the longitudinal direction between an open position, which releases the cartridge chamber for the reloading of a cartridge, and a closed position which closes the cartridge chamber, wherein the breech body closes the cartridge chamber at the rear in the closed position and is used as a support for the cartridge case of the cartridge, wherein the firearm has a mass simulation body which is in force-fitting engagement with the breech body, in particular a mass simulation body which is rigidly connected to the breech body, the mass simulation body being formed at least in part from a magnetizable or a magnetic material.

A semiautomatic or fully automatic firearm that includes a barrel, the rear barrel end whereof is in the form of a cartridge chamber into which a cartridge can be inserted, a breech body which is arranged such that it can move in the longitudinal direction between an open position, which releases the cartridge chamber for the reloading of a cartridge, and a closed position which closes the cartridge chamber, wherein the breech body closes the cartridge chamber at the rear in the closed position and is used as a support for the cartridge case of the cartridge, wherein the firearm has a mass simulation body which is in force-fitting engagement with the breech body, in particular a mass simulation body which is rigidly connected to the breech body, the mass simulation body being formed at least in part from a magnetizable or a magnetic material.