The invention relates to a countermass propulsion system for shoulder-launched munitions, recoilless rifles, rockets and similar class weapon systems, fired from an enclosure and utilizing a Davis Gun propulsion system by accelerating a projectile in one direction and a countermass in the opposing direction to minimize recoil, light signature and acoustic signature of the weapon system.

Apparatus for electromagnetic launching system for the linear acceleration of macro particles. The apparatus disclosed is autonomously-powered, compact, and lightweight. The apparatus disclosed has low recoil force, low acoustic report, and low visible and infra-red signature. The apparatus disclosed is capable of automatic operation and the maximum particle velocity can be adjusted. The apparatus disclosed includes a trigger, controller, component power source, particle container, particle loader, propellant container, propellant loader, igniter, combustion chamber, sound suppressor, linear electrical generator, linear electrical motor, and thermal barrier.

An electromagnetic system coupled to a firearm, the firearm including a bolt movable rearward and frontward along a rear-to-front axial direction between a forward position and a rearward position, includes a first electromagnet unit. The first electromagnet unit includes at least one electrically-conductive coil and at least one magnet. The magnet or magnets are movable jointly with the bolt in the axial direction with respect to the at least one electrically-conductive coil. The at least one electrically-conductive coil is configured to generate at least one magnetic field that opposes a rearward movement of the at least one magnet in the axial direction and thereby reduces a rearward recoil of the bolt.

An electromagnetic system coupled to a firearm, the firearm including a bolt movable rearward and frontward along a rear-to-front axial direction between a forward position and a rearward position, includes a first electromagnet unit. The first electromagnet unit includes at least one electrically-conductive coil and at least one magnet. The magnet or magnets are movable jointly with the bolt in the axial direction with respect to the at least one electrically-conductive coil. The at least one electrically-conductive coil is configured to generate at least one magnetic field that opposes a rearward movement of the at least one magnet in the axial direction and thereby reduces a rearward recoil of the bolt.

A weapon system includes a rotatable part having a plurality of barrels arranged in an array, a drive motor connected to the rotatable part so as to drive the barrels in rotation, a static part positioned rearwardly of the rotatable part, a magazine positioned rearwardly of the static part, and an ammunition feed mechanism cooperative with projectiles in the magazine so as to move the projectiles from the magazine to a position adjacent to the end of the plurality of barrels. The static part has a plurality of combustion chambers communicating with the plurality of barrels and with the end of the plurality of barrels. The combustion chambers are adapted to ignite a gaseous fuel therein so as to drive a projectile outwardly through the barrels. A plurality of actuators are adapted to load the projectiles into the end of the plurality of barrels.

An artillery configured to propel a projectile, the artillery comprising a firing mechanism, a barrel, and a helical electromagnetic recoil mechanism. The firing mechanism fires the projectile in a first direction toward a target. The barrel has an open-ended bore that guides the projectile in the first direction. The helical electromagnetic counter recoil mechanism includes an electrical energy source, a stator, and a helical electromagnetic armature. The electrical energy source provides electrical energy when the firing mechanism fires the projectile. The stator and armature generate an electromagnetic force via the electrical energy. The helical electromagnetic armature moves in a second direction opposite the first direction via the electromagnetic force when the firing mechanism fires the projectile in the first direction to minimize recoil of the artillery.

An artillery configured to propel a projectile, the artillery comprising a firing mechanism, a barrel, and a helical electromagnetic recoil mechanism. The firing mechanism fires the projectile in a first direction toward a target. The barrel has an open-ended bore that guides the projectile in the first direction. The helical electromagnetic counter recoil mechanism includes an electrical energy source, a stator, and a helical electromagnetic armature. The electrical energy source provides electrical energy when the firing mechanism fires the projectile. The stator and armature generate an electromagnetic force via the electrical energy. The helical electromagnetic armature moves in a second direction opposite the first direction via the electromagnetic force when the firing mechanism fires the projectile in the first direction to minimize recoil of the artillery.

A recoil controller is disclosed whose body 1 incorporates a strategically designed inner surface or surfaces 2. A moving countermass 6 impacts one or more times against one or more inner surfaces 2. During this process momentum is transferred from the countermass 6, to the inner surfaces 2, and then to the body 1 of the recoil controller, and then to anything to which it is attached or against which it is braced. The distributions, over time, of the momenta resulting from this transfer of momentum will depend on various factors including the composition, geometry and placement of the inner surfaces 2. A given recoil controller is designed such that the distributions, over time, of the momenta resulting from its use, are preferable to the distributions, over time, of the original momenta. The countermass 6 shown in FIG. 1 is the countermass 6 shown after one impact.

An extendable slide member on a pistol slide action, providing leverage and a gripping base for a user to pull back or rack the slide along guides on a pistol frame, in a longitudinal motion relative to the pistol frame. The slide member facilitating racking the slide when in an extended position the slide member rotates either laterally outwards from a side surface of the slide or vertically upwards from a top surface of the slide, and presents a gripping or holding segment for the user to pull the slide towards the breech end of the pistol.

A cartridge (20) has a cartridge case (22) extending along an axis (500) from a base (104) to a mouth (102) and having an interior. A projectile (24) is mounted in the case. A propellant (26) is contained within the case. The propellant has an annular grain encircling the axis.