A non-lethal projectile having a shear-thinning fluid within an interior cavity. The shear-thinning fluid having a greater apparent viscosity at low shear rates to spin-stabilize the non-lethal projectile during flight and a lower apparent viscosity at a high shear rate corresponding with the shear-thinning fluid shearing against the frangible cap upon the non-lethal projectile striking the target, with the low viscosity of the shear-thinning fluid allowing proper dispersal upon impact with the target. The shear-thinning fluid can comprise a marking media and be in the form of an emulsion with less than about 50% liquid by volume to effectively disperse upon impact with the target.

A non-lethal projectile having a shear-thinning fluid within an interior cavity. The shear-thinning fluid having a greater apparent viscosity at low shear rates to spin-stabilize the non-lethal projectile during flight and a lower apparent viscosity at a high shear rate corresponding with the shear-thinning fluid shearing against the frangible cap upon the non-lethal projectile striking the target, with the low viscosity of the shear-thinning fluid allowing proper dispersal upon impact with the target. The shear-thinning fluid can comprise a marking media and be in the form of an emulsion with less than about 50% liquid by volume to effectively disperse upon impact with the target.

A projectile such as a paintball including a ball-shaped capsule and a round-shaped disc capable of facilitating accuracy of projectile travel direction is disclosed. The ball-shaped or substantial ball-shaped capsule, in one embodiment, having a head and a tail is able to store and deliver colored markers upon an impact between the projectile and an object. The round-shaped disc is positioned at a place so that allowing a portion of the round-shaped disc to extend above outer surface of the capsule. The disc is able to catch at least airflow when the projectile is launched. The round-shaped disc, in one example, uses the direction of the airflow to facilitate travel direction of the projectile.

A projectile such as a paintball including a ball-shaped capsule and a round-shaped disc capable of facilitating accuracy of projectile travel direction is disclosed. The ball-shaped or substantial ball-shaped capsule, in one embodiment, having a head and a tail is able to store and deliver colored markers upon an impact between the projectile and an object. The round-shaped disc is positioned at a place so that allowing a portion of the round-shaped disc to extend above outer surface of the capsule. The disc is able to catch at least airflow when the projectile is launched. The round-shaped disc, in one example, uses the direction of the airflow to facilitate travel direction of the projectile.

The invention relates to a test and/or practice ammunition having at least one projectile with a projectile head and a fin which can be found at the end of the projectile for example or a projectile with a projectile base and a projectile ogive. A cartridge shell is used to receive a drive and has a shell base, wherein an interface is attached in or on the shell base. The test and/or practice ammunition is characterized by a programmable fuze which is arranged in the projectile head or the projectile ogive. The projectile head/projectile ogive is equipped with at least one fuze amplifier and an electronic fuze system and optionally a separating charge.

A cartridge incorporating a projectile assembly, the projectile assembly having a base, mid body component housing a marking powder and metallic nose cap. The projectile's mid-body component houses liquids in a cylindrical compartment, where set-back and rotation induce chemical mixing, and in flight allowing for a chemical reaction, and at impact the projectile undergoes wall failure in the mid body, resulting from shear and residual rotational momentum, the actions in combination releasing and expelling marking materials, the ejection suspended signature producing materials, including liquid, powdered metals or fine particles released into the atmosphere emit and reflect light, the signature materials producing an observable signature at the projectile's impact location.

A less-than-lethal kinetic impact projectile and an associated less-than-lethal ammunition round are provided. The projectile has a typically self-supporting, sealed cylindrical elastomeric bag with a particulate load therein and with a deformable hemispherical hollow nose cap forwardly attached to a front of the cylindrical elastomeric bag. The round has a cylindrical casing with an ignitable propellant powder charge disposed therein, and the projectile nested within the casing forwardly of the propellant powder charge. In operation, the polymer material of the cylindrical elastomeric bag with deformable hollow nose cap is such that the projectile will expand in diameter but remain intact when impacting against a soft or semi-soft target (e.g., the body of a human being or animal), but will tend to fragment, disintegrate, or open up at the back, upon impact with a hard or semi hard target (e.g., against concrete or wood).

A cartridge incorporating a projectile assembly, the projectile assembly having a base, mid body component housing a marking powder and metallic nose cap. The projectile's mid-body component houses liquids in a cylindrical compartment, where set-back and rotation induce chemical mixing, and in flight allowing for a chemical reaction, and at impact the projectile undergoes wall failure in the mid body, resulting from shear and residual rotational momentum, the actions in combination releasing and expelling marking materials, the ejection suspended signature producing materials, including liquid, powdered metals or fine particles released into the atmosphere emit and reflect light, the signature materials producing an observable signature at the projectile's impact location.

The invention provides an automatic launching system for simulated training ammunition. It can mimic the effect of explosive detonation in close quarters battles without causing any casualties, and can ignite the fuze and launch the simulated training ammunition without gunpowder involved. The technical solution of the invention is that: the automatic launching system for simulated training ammunition comprises a launcher, a controller and a simulated training ammunition loaded inside the launcher. The Simulated training ammunition comprises an outer shell, a core and a fuze structure at the bottom of the simulated training ammunition. The piston cylinder of the launcher comprises vents in the cylinder sidewall for communicating the cylinder cavity with the launcher cavity. The lower part of the cylinder is connected to a high-pressure gas holder through a pipeline and a normally closed solenoid valve. This invention can automatically identify the target and ignite the fuze and launch the simulated training ammunition after identifying the target, and mimic explosion effects. It uses no gunpowder, thus has no potential safety risks, and is safe, reliable, easy to operate, simple in structure, and suitable for civil production and manufacturing.

The invention provides an automatic launching system for simulated training ammunition. It can mimic the effect of explosive detonation in close quarters battles without causing any casualties, and can ignite the fuze and launch the simulated training ammunition without gunpowder involved. The technical solution of the invention is that: the automatic launching system for simulated training ammunition comprises a launcher, a controller and a simulated training ammunition loaded inside the launcher. The Simulated training ammunition comprises an outer shell, a core and a fuze structure at the bottom of the simulated training ammunition. The piston cylinder of the launcher comprises vents in the cylinder sidewall for communicating the cylinder cavity with the launcher cavity. The lower part of the cylinder is connected to a high-pressure gas holder through a pipeline and a normally closed solenoid valve. This invention can automatically identify the target and ignite the fuze and launch the simulated training ammunition after identifying the target, and mimic explosion effects. It uses no gunpowder, thus has no potential safety risks, and is safe, reliable, easy to operate, simple in structure, and suitable for civil production and manufacturing.