A boron steel high pressure cartridge case and method of manufacturing the same is provided. The method includes cold forming a cartridge case into a drawn blank or a tubular component; annealing the cartridge case using a belt furnace, flame furnace, induction furnace, or a batch furnace; performing a machine ejector slot and trim on the cartridge case; forming the shoulder and neck of the cartridge case; performing a heat treatment of the cartridge case; and tempering the cartridge case. The cartridge case is fabricated of boron steel including ≤1.0% boron.

The present invention provides a method of coding polymer ammunition cartridges by providing a first colored polymer forming a polymeric bullet-end upper portion comprising a bullet-end coupling element extending to a bullet-end aperture to engage a bullet; providing a second colored polymer forming a polymeric middle body comprising a first coupling end connected to the bullet-end coupling element and a second coupling end connected to a primer insert to form a propellant chamber that connects the bullet-end aperture to the primer insert; and coding the first colored polymer, the second colored polymer or both to identify a projectile type, an ammunition type, a propellant charge, or a combination thereof.

The present invention provides a method of coding polymer ammunition cartridges by providing a first colored polymer forming a polymeric bullet-end upper portion comprising a bullet-end coupling element extending to a bullet-end aperture to engage a bullet; providing a second colored polymer forming a polymeric middle body comprising a first coupling end connected to the bullet-end coupling element and a second coupling end connected to a primer insert to form a propellant chamber that connects the bullet-end aperture to the primer insert; and coding the first colored polymer, the second colored polymer or both to identify a projectile type, an ammunition type, a propellant charge, or a combination thereof.

The present invention provides a method of coding polymer ammunition cartridges by providing a first colored polymer forming a polymeric bullet-end upper portion comprising a bullet-end coupling element extending to a bullet-end aperture to engage a bullet; providing a second colored polymer forming a polymeric middle body comprising a first coupling end connected to the bullet-end coupling element and a second coupling end connected to a primer insert to form a propellant chamber that connects the bullet-end aperture to the primer insert; and coding the first colored polymer, the second colored polymer or both to identify a projectile type, an ammunition type, a propellant charge, or a combination thereof.

The present invention provides a method of coding polymer ammunition cartridges by providing a first colored polymer forming a polymeric bullet-end upper portion comprising a bullet-end coupling element extending to a bullet-end aperture to engage a bullet; providing a second colored polymer forming a polymeric middle body comprising a first coupling end connected to the bullet-end coupling element and a second coupling end connected to a primer insert to form a propellant chamber that connects the bullet-end aperture to the primer insert; and coding the first colored polymer, the second colored polymer or both to identify a projectile type, an ammunition type, a propellant charge, or a combination thereof.

A boron steel high pressure cartridge case and method of manufacturing the same is provided. The method includes cold forming a cartridge case into a drawn blank or a tubular component; annealing the cartridge case using a belt furnace, flame furnace, induction furnace, or a batch furnace; performing a machine ejector slot and trim on the cartridge case; forming the shoulder and neck of the cartridge case; performing a heat treatment of the cartridge case; tempering the cartridge case; and coating the cartridge case with a zinc nickel plating. The cartridge case is fabricated of boron steel including 1.0% boron.

A boron steel high pressure cartridge case and method of manufacturing the same is provided. The method includes cold forming a cartridge case into a drawn blank or a tubular component; annealing the cartridge case using a belt furnace, flame furnace, induction furnace, or a batch furnace; performing a machine ejector slot and trim on the cartridge case; forming the shoulder and neck of the cartridge case; performing a heat treatment of the cartridge case; tempering the cartridge case; and coating the cartridge case with a zinc nickel plating. The cartridge case is fabricated of boron steel including 1.0% boron.

A bullet for ammunition, in particular with a caliber of at most 20 mm or at most 13 mm, may include a metallic bullet body and a surface coating with a thickness of more than 100 m forming at least sectionally an outer skin of the bullet.

A bullet for ammunition, in particular with a caliber of at most 20 mm or at most 13 mm, may include a metallic bullet body and a surface coating with a thickness of more than 100 m forming at least sectionally an outer skin of the bullet.

A method of sealing an ammunition cartridge during an ammunition manufacturing process. The method including providing a cartridge case having a projectile receiving mouth with an inner surface and applying a thin circumferential film of a liquid light curable sealant to the inner surface. A cured thin circumferential film is formed by curing the thin circumferential film of liquid light curable sealant using an effective curing light from an optical light spectrum. A projectile is inserted into the mouth of the cartridge case with the cured thin circumferential film forming an air and moisture impermeable seal between the inner surface and the projectile.