The invention provides a simulated training ammunition automatic launching system. It can mimic the effect of explosive detonation in close quarters battles without causing any casualties, and can ignite the fuze and launch the practice bomb without gunpowder involved. The technical proposal of the invention is that: the simulated training ammunition automatic launching system comprises launchers, controls, simulated training ammunition. Simulated training ammunition comprises shells, bomb cores and fuze. The cylinder sidewall is equipped with air inlet ports which connect the cylinder cavity and the launcher cavity. The lower part of the cylinder is connected to a high pressure gas holder by a windpipe and a normally closed electrical magnetic valve. The invention can automatically recognize the targets, fire and detonate ammunition. It uses no gunpowder, gives no security risks, and is safe, reliable, and easy to operate. It is suitable for mass civilian production.

Provided is a non-pyro cartridge for military training devices. The cartridge has a refillable compressed gas compartment fitted with a refill valve, which allows for quick reuse of the cartridge. The cartridge further has a blast compartment that receive a rush of compressed air from the gas compartment when the cartridge is triggered/detonated. Also provided is an activation device for the cartridge. The cartridge and activation device can generate physical and digital effects on the battlefield that safely and realistically simulate anti-tank weapon signatures, mortar weapon signatures, landmines signatures, improvised explosive device weapon signatures, artillery point of impact signatures, hand grenade signatures, weapon impact signatures on vehicles, weapon impact signatures on buildings, multiple types of battlefield effects, weapon signatures, impact signatures with a single device type.

A weapon training system including a magnetic sensor system is described. The magnetic sensor system is insertable into or integrated with a round of an indirect firing weapon and includes at least one magnetic sensor and a microcontroller communicatively coupled to the at least one magnetic sensor. The microcontroller is configured to perform operations including receiving at least one proximity signal from the at least one magnetic sensor indicating a proximity of at least one magnet of at least one charge to the at least one magnetic sensor, determining, based on the at least one proximity signal, that the at least one charge is removably attached to the round, generating an output signal indicating that the at least one charge is removably attached to the round, and wirelessly transmitting the output signal to an electronic device.

A weapon training system including a magnetic sensor system is described. The magnetic sensor system is insertable into or integrated with a round of an indirect firing weapon and includes at least one magnetic sensor and a microcontroller communicatively coupled to the at least one magnetic sensor. The microcontroller is configured to perform operations including receiving at least one proximity signal from the at least one magnetic sensor indicating a proximity of at least one magnet of at least one charge to the at least one magnetic sensor, determining, based on the at least one proximity signal, that the at least one charge is removably attached to the round, generating an output signal indicating that the at least one charge is removably attached to the round, and wirelessly transmitting the output signal to an electronic device.

A weapon training system including a magnetic sensor system is described. The magnetic sensor system is insertable into or integrated with a round of an indirect firing weapon and includes at least one magnetic sensor and a microcontroller communicatively coupled to the at least one magnetic sensor. The microcontroller is configured to perform operations including receiving at least one proximity signal from the at least one magnetic sensor indicating a proximity of at least one magnet of at least one charge to the at least one magnetic sensor, determining, based on the at least one proximity signal, that the at least one charge is removably attached to the round, generating an output signal indicating that the at least one charge is removably attached to the round, and wirelessly transmitting the output signal to an electronic device.

A weapon training system including a magnetic sensor system is described. The magnetic sensor system is insertable into or integrated with a round of an indirect firing weapon and includes at least one magnetic sensor and a microcontroller communicatively coupled to the at least one magnetic sensor. The microcontroller is configured to perform operations including receiving at least one proximity signal from the at least one magnetic sensor indicating a proximity of at least one magnet of at least one charge to the at least one magnetic sensor, determining, based on the at least one proximity signal, that the at least one charge is removably attached to the round, generating an output signal indicating that the at least one charge is removably attached to the round, and wirelessly transmitting the output signal to an electronic device.

An indirect fire mission training round includes a projectile training shell having an outer periphery, a proximal end, and a distal end, the proximal end defining an interior chamber. The projectile training shell is configured to be inserted within a cavity of a projectile firing instrument. The round includes an interlock member configured to securely receive a proximal portion of a subsequent training round within the interior chamber of the projectile training shell. The round includes a resistance brake extending outward from the outer periphery and configured to contact a wall of the cavity of the firing instrument and provide resistance that secures the projectile training shell at a position within the cavity. The resistance break is selectively disengageable such that the position of the projectile training shell is adjustable.

An indirect fire mission training round includes a projectile training shell having an outer periphery, a proximal end, and a distal end, the proximal end defining an interior chamber. The projectile training shell is configured to be inserted within a cavity of a projectile firing instrument. The round includes an interlock member configured to securely receive a proximal portion of a subsequent training round within the interior chamber of the projectile training shell. The round includes a resistance brake extending outward from the outer periphery and configured to contact a wall of the cavity of the firing instrument and provide resistance that secures the projectile training shell at a position within the cavity. The resistance break is selectively disengageable such that the position of the projectile training shell is adjustable.

A weapon training system including a magnetic sensor system is described. The magnetic sensor system is insertable into or integrated with a round of an indirect firing weapon and includes at least one magnetic sensor and a microcontroller communicatively coupled to the at least one magnetic sensor. The microcontroller is configured to perform operations including receiving at least one proximity signal from the at least one magnetic sensor indicating a proximity of at least one magnet of at least one charge to the at least one magnetic sensor, determining, based on the at least one proximity signal, that the at least one charge is removably attached to the round, generating an output signal indicating that the at least one charge is removably attached to the round, and wirelessly transmitting the output signal to an electronic device.

A weapon training system including a magnetic sensor system is described. The magnetic sensor system is insertable into or integrated with a round of an indirect firing weapon and includes at least one magnetic sensor and a microcontroller communicatively coupled to the at least one magnetic sensor. The microcontroller is configured to perform operations including receiving at least one proximity signal from the at least one magnetic sensor indicating a proximity of at least one magnet of at least one charge to the at least one magnetic sensor, determining, based on the at least one proximity signal, that the at least one charge is removably attached to the round, generating an output signal indicating that the at least one charge is removably attached to the round, and wirelessly transmitting the output signal to an electronic device.