In a method for electrochemical ammunition disposal and material recovery, ammunition cartridges are placed in an acidic aqueous solution that is in contact with a cathode and an anode. The ammunition cartridges have a casing that includes an alloy of copper and zinc. The ammunition cartridges are agitated in the acidic aqueous solution as a voltage is applied between the anode and the cathode. The applied voltage is effective to oxidize and dissolve zinc from the copper-zinc alloy. Copper metal derived from the alloy can be recovered as a solid, and zinc ion derived from the alloy can be recovered as a solution.

In a method for electrochemical ammunition disposal and material recovery, ammunition cartridges are placed in an acidic aqueous solution that is in contact with a cathode and an anode. The ammunition cartridges have a casing that includes an alloy of copper and zinc. The ammunition cartridges are agitated in the acidic aqueous solution as a voltage is applied between the anode and the cathode. The applied voltage is effective to oxidize and dissolve zinc from the copper-zinc alloy. Copper metal derived from the alloy can be recovered as a solid, and zinc ion derived from the alloy can be recovered as a solution.

The disclosed technology includes a bumper system for use with an Explosive Ordnance Disposal disruptor. The bumper system can include a bumper stop configured the slidably engage the disruptor, and a bumper configured to receive at least a portion of an initiation system of the disruptor. The bumper may be configured to receive at least a portion of the initiation system such that the bumper is attached to the at least a portion of the initiation system by friction.

The disclosed technology includes a bumper system for use with an Explosive Ordnance Disposal disruptor. The bumper system can include a bumper stop configured the slidably engage the disruptor, and a bumper configured to receive at least a portion of an initiation system of the disruptor. The bumper may be configured to receive at least a portion of the initiation system such that the bumper is attached to the at least a portion of the initiation system by friction.

Methods for disposing of munition components may include separating propellants from heavy metal penetrators and disposing of those separated components into different types of geological formations. The initially solid form propellants may be converted into a stable liquified propellant form, by a particular disclosed process, that may be injected within salt water (injection) disposal wells, where distal portions of such salt water disposal wells may be located in a geological formation of substantially at least one salt. The separated heavy metal penetrators (with or without their associated projectile jackets) may be disposed of within human-made caverns, where such human-made caverns may be located within a deep geological formation that is often 2,000 feet or more below the Earth's surface. The heavy metal penetrators may include uranium (depleted uranium). Portions of a given munition, to be disposed of, may be radioactive.

Methods for disposing of munition components may include separating propellants from heavy metal penetrators and disposing of those separated components into different types of geological formations. The initially solid form propellants may be converted into a stable liquified propellant form, by a particular disclosed process, that may be injected within salt water (injection) disposal wells, where distal portions of such salt water disposal wells may be located in a geological formation of substantially at least one salt. The separated heavy metal penetrators (with or without their associated projectile jackets) may be disposed of within human-made caverns, where such human-made caverns may be located within a deep geological formation that is often 2,000 feet or more below the Earth's surface. The heavy metal penetrators may include uranium (depleted uranium). Portions of a given munition, to be disposed of, may be radioactive.

A method for destroying pyrotechnic materials including providing an apparatus having an inlet and an outlet and configured to mechanically destroy pyrotechnic materials and discharge pyrotechnic debris through the outlet, feeding water and pyrotechnic materials to the inlet of the apparatus so that the apparatus mechanically destroys the pyrotechnic materials and discharges pyrotechnic debris and water through the outlet, introducing the discharged pyrotechnic debris and water to a reservoir of water so that water-soluble components of the pyrotechnic debris dissolve into the water of the reservoir, light-density water-insoluble components float to the top of the reservoir and high-density water-insoluble components settle at bottom of the reservoir, and filtering the reservoir of water to separate water from the water-insoluble components.

A method for destroying pyrotechnic materials including providing an apparatus having an inlet and an outlet and configured to mechanically destroy pyrotechnic materials and discharge pyrotechnic debris through the outlet, feeding water and pyrotechnic materials to the inlet of the apparatus so that the apparatus mechanically destroys the pyrotechnic materials and discharges pyrotechnic debris and water through the outlet, introducing the discharged pyrotechnic debris and water to a reservoir of water so that water-soluble components of the pyrotechnic debris dissolve into the water of the reservoir, light-density water-insoluble components float to the top of the reservoir and high-density water-insoluble components settle at bottom of the reservoir, and filtering the reservoir of water to separate water from the water-insoluble components.

A method for biopassivating an ordnance magazine containing explosive ordnance includes introducing microorganisms into the ordnance magazine and controlling the environmental conditions in the ordnance magazine to facilitate growth of the microorganisms. In this way, the ordnance magazine can be operated as a bioreactor to passivate the explosive ordnance inside.

An inertia bullet remover and associated methods for removing a bullet from an ammunition casing. The inertia bullet remover includes a carriage for carrying the ammunition casing. The carriage is movable with respect to a base between a first position and a second position. Movement of the carriage is guided by a guide. Movement of the carriage is stopped by a stop, which causes the bullet to exit the ammunition casing via inertia.