An ammunition reloading system is configured to be operatively coupled with an ammunition reloading press to enable automated operation of the press. The reloading system includes a motor and a power transmission assembly that enables rotational power in a single direction from the motor to drive the ammunition reloading press. A controller is communicatively coupled to the motor and to one or more press position sensors to determine a position of the press within a press stroke cycle and increase or decrease the speed of the motor accordingly.

A novel castable frangible projectile and techniques for manufacturing such are provided. A cartridge system includes a case defining a volume, a propellant disposed in the volume of the case, and a projectile coupled to the case. The projectile includes a body disposed at least partially within the case and configured to enclose the propellant within the volume of the case. The body is formed of a castable eutectic mixture, the castable eutectic mixture configured to be melted and cast, wherein the body is configured to break into a plurality of fragments upon impact with a target.

A small arms form factor munition may package a control section with a deployment section in a munition case. The control section can have a first drag mechanism and a second drag mechanism. Firing the munition case from a firearm propels the load from the munition case and barrel of the firearm towards a target. A drag mechanism is selected and activated by the control section in response to a detected distance to the target while the load is in flight. The drag mechanism alters a flight characteristic of the load.

A small arms form factor munition may package a control section with a deployment section in a munition case. The control section can have a first drag mechanism and a second drag mechanism. Firing the munition case from a firearm propels the load from the munition case and barrel of the firearm towards a target. A drag mechanism is selected and activated by the control section in response to a detected distance to the target while the load is in flight. The drag mechanism alters a flight characteristic of the load.

Systems, methods and apparatus are provided through which in some implementations an ammunition cartridge includes a cartridge casing having a longitudinal center axis, a powder pocket positioned adjacent to the cartridge casing, a piston bore positioned adjacent to the powder pocket, a piston in the piston bore, and a payload bay positioned adjacent to the payload bay, wherein the piston is not coupled to the cartridge, wherein the piston is in direct contact with the payload bay wherein a diameter of the powder pocket is less than an inside diameter of the cartridge casing to provide a reduced velocity to the payload.

Systems, methods and apparatus are provided through which in some implementations an ammunition cartridge includes a cartridge casing having a longitudinal center axis, a powder pocket positioned adjacent to the cartridge casing, a piston bore positioned adjacent to the powder pocket, a piston in the piston bore, and a payload bay positioned adjacent to the payload bay, wherein the piston is not coupled to the cartridge, wherein the piston is in direct contact with the payload bay wherein a diameter of the powder pocket is less than an inside diameter of the cartridge casing to provide a reduced velocity to the payload.

An intelligent munition can position circuitry in a 12 gauge form factor that detects the distance from a target in real-time in order to deploy a parachute to slow the munition to a speed that is conducive to accurate, but non-lethal, deployment of at least one electrode toward the target. The munition can intelligently discharge electrical charge into the target via an electrode to disable the target. The munition may further monitor the target and deliver a subsequent electrical discharge in response to detected target movement.

An intelligent munition can position circuitry in a 12 gauge form factor that detects the distance from a target in real-time in order to deploy a parachute to slow the munition to a speed that is conducive to accurate, but non-lethal, deployment of at least one electrode toward the target. The munition can intelligently discharge electrical charge into the target via an electrode to disable the target. The munition may further monitor the target and deliver a subsequent electrical discharge in response to detected target movement.

An intelligent munition can position circuitry in a 12 gauge form factor that detects the distance from a target in real-time in order to deploy a parachute to slow the munition to a speed that is conducive to accurate, but non-lethal, deployment of at least one electrode toward the target. The munition can intelligently discharge electrical charge into the target via an electrode to disable the target. The munition may further monitor the target and deliver a subsequent electrical discharge in response to detected target movement.

An intelligent munition can position circuitry in a 12 gauge form factor that detects the distance from a target in real-time in order to deploy a parachute to slow the munition to a speed that is conducive to accurate, but non-lethal, deployment of at least one electrode toward the target. The munition can intelligently discharge electrical charge into the target via an electrode to disable the target. The munition may further monitor the target and deliver a subsequent electrical discharge in response to detected target movement.