An over barrel muzzle device attachment system including at least some of a gas block nut having a first externally threaded portion and a second externally threaded portion formed at a spaced apart location from the first externally threaded portion; a lock collar having a first internally threaded portion and a second internally threaded portion; a gas block lock ring having an at least partially internally threaded gas block lock ring aperture formed within at least a portion of a gas block lock ring aperture; a muzzle device adapter having a conical taper portion extending from an adapter muzzle end and a threaded portion extending along a portion of the muzzle device adapter, between the adapter muzzle end and an adapter barrel end; and an over barrel muzzle device having an externally threaded portion.

An over barrel muzzle device attachment system including at least some of a gas block nut having a first externally threaded portion and a second externally threaded portion formed at a spaced apart location from the first externally threaded portion; a lock collar having a first internally threaded portion and a second internally threaded portion; a gas block lock ring having an at least partially internally threaded gas block lock ring aperture formed within at least a portion of a gas block lock ring aperture; a muzzle device adapter having a conical taper portion extending from an adapter muzzle end and a threaded portion extending along a portion of the muzzle device adapter, between the adapter muzzle end and an adapter barrel end; and an over barrel muzzle device having an externally threaded portion.

System for a delayed-opposed-piston gas action assembly. Specifically, the system is comprised of a bolt, a bolt carrier, a gas block, a bolt piston, and a vent piston. Each piston will have a corresponding piston cup that will act on the piston from the gas discharged from the round. Each piston will also have a corresponding spring to bring the piston back to its original position after the gas has dissipated from the system. During the process of the firearm being discharged, the two pistons will act on the bolt carrier, causing the casing of the round to be ejected from the firearm, and a new round to be loaded into the firearm, so that the firearm can be discharged again.

System for a delayed-opposed-piston gas action assembly. Specifically, the system is comprised of a bolt, a bolt carrier, a gas block, a bolt piston, and a vent piston. Each piston will have a corresponding piston cup that will act on the piston from the gas discharged from the round. Each piston will also have a corresponding spring to bring the piston back to its original position after the gas has dissipated from the system. During the process of the firearm being discharged, the two pistons will act on the bolt carrier, causing the casing of the round to be ejected from the firearm, and a new round to be loaded into the firearm, so that the firearm can be discharged again.

A recoil assembly for a rifle includes a barrel assembly, a bolt, bolt actuator, and a buffer assembly. The barrel assembly includes a barrel secured to a barrel extension. The barrel assembly is configured to be movably received through the fore end of a receiver and to move axially relative to the upper receiver when the rifle is fired. The barrel extension is coupled to a hydraulic buffer assembly located below the barrel extension and counteracts recoil forces acting on the barrel extension when the rifle is fired. An op-rod spring is coupled to an op rod extending from a gas piston assembly on the barrel. The op-rod spring counteracts recoil forces acting the bolt actuator when the rifle is fired.

The invention relates to a firearm (100) comprising a barrel (101) comprising a gas opening, and a gas system (10), which gas system (10) comprises a gas block (11), a gas piston (12), a force transmitter assembly (13), an indexing part (21) and an indexing counterpart (22), gas openings (18). The gas block (11) is fixedly attached to the barrel and the gas piston (12) is positioned by the indexing part (21; 22). In the gas system (10) gas is configured to pass through the gas opening of the barrel (101) via the gas openings (18) of the gas system into the gas block (11) and to set the gas piston (12) to movement. In the gas system (10) the gas piston (12) during its movement backwards is configured to close the gas opening of the barrel (101) for a defined time period and the gas piston (12) is not transmitting power/energy from combustion gas to the force transmitter assembly (13) unless the gas opening/-s (18) is/are closed.

A fixture for use with AR15/M16 type firearms is provided herein. The fixture is made up of several parts that when used in conjunction with one another mitigate the transfer of torque from the barrel nut to the firearms receiver during barrel installation. The fixture affords the user a method and apparatus that holds the barrel in alignment with the firearm receiver and secures the barrel against rotational movement during installation of a barrel nut or similar device. The fixture may be configured to work with the legacy AR15/M16 type barrel nut, as well as other designs as disclosed herein.

A fixture for use with AR15/M16 type firearms is provided herein. The fixture is made up of several parts that when used in conjunction with one another mitigate the transfer of torque from the barrel nut to the firearms receiver during barrel installation. The fixture affords the user a method and apparatus that holds the barrel in alignment with the firearm receiver and secures the barrel against rotational movement during installation of a barrel nut or similar device. The fixture may be configured to work with the legacy AR15/M16 type barrel nut, as well as other designs as disclosed herein.

An improved gas impingement system including an upper receiver incorporating a barrel. A gas block is secured to a forward location of the barrel and includes a rearward extending portion shrouding a forward portion of a gas tube connected to the gas block. The gas tube is in communication with a gas port defined in the gas block extending to an interior of the barrel. The gas tube extends rearwardly from the gas block and communicates at a rear end with a key of a bolt carrier positioned within a firing chamber of the upper receiver. Upon discharging a ballistic from a cartridge contained within the chamber, pressurized gas resulting from the discharge is diverted through the gas port, gas block, and gas tube to the key, causing the bolt carrier to move rearward, with the rearward extending portion of the gas block both structurally supporting the gas tube and externally sinking heat from the gas tube.

A recoil assembly for a rifle includes a barrel assembly, a bolt, bolt actuator, and a buffer assembly. The barrel assembly includes a barrel secured to a barrel extension. The barrel assembly is slidably received in the receiver and the barrel extension is coupled to a hydraulic buffer assembly located below the barrel extension. The hydraulic buffer assembly is configured and arranged to arrest rearward movement of the barrel assembly when the rifle is fired. An op-rod spring is coupled to an op rod extending that can be actuated by a gas piston assembly on the barrel. The op-rod spring is configured and arranged to arrest rearward movement of the bolt assembly.