An electronic securing device for an electronic load with an energy supply is provided, which can supply the securing device and the load with energy when an input signal is applied for a corresponding time, wherein the electronic securing device has a time delay, which ensures that only signals of a predetermined minimum duration are detected as a signal. The electronic securing device also has a programmable logic, which comprises the time control, and by way of which an operating switch can also be switched on. The programmable logic switches the energy supply to the load for a certain time and switch off again after the time has elapsed. The switching of the energy to the load takes place via a power switch. The switching off of the logic takes place via a first logic switch, which in turn can switch the operating switch and thereby deactivate the logic.

An electronic securing device for an electronic load with an energy supply is provided, which can supply the securing device and the load with energy when an input signal is applied for a corresponding time, wherein the electronic securing device has a time delay, which ensures that only signals of a predetermined minimum duration are detected as a signal. The electronic securing device also has a programmable logic, which comprises the time control, and by way of which an operating switch can also be switched on. The programmable logic switches the energy supply to the load for a certain time and switch off again after the time has elapsed. The switching of the energy to the load takes place via a power switch. The switching off of the logic takes place via a first logic switch, which in turn can switch the operating switch and thereby deactivate the logic.

A munition with redundant safety features to return the munition to a safe, unarmed state, the munition includes an encasement, an energetic within the encasement, an electronic initiator configured to initiate a detonation of the energetic, wherein the electronic initiator is configured to be discharged to prevent detonation of the energetic, and a mechanical safety assembly configured to be selectively moved from an unarmed position to an armed position, wherein in the armed position the mechanical safety assembly provides a physical barrier between the energetic and the electronic initiator to prevent detonation of the energetic, wherein in the armed position in the mechanical safety assembly provides a pathway between the energetic and the electronic initiator.

A munition with redundant safety features to return the munition to a safe, unarmed state, the munition includes an encasement, an energetic within the encasement, an electronic initiator configured to initiate a detonation of the energetic, wherein the electronic initiator is configured to be discharged to prevent detonation of the energetic, and a mechanical safety assembly configured to be selectively moved from an unarmed position to an armed position, wherein in the armed position the mechanical safety assembly provides a physical barrier between the energetic and the electronic initiator to prevent detonation of the energetic, wherein in the armed position in the mechanical safety assembly provides a pathway between the energetic and the electronic initiator.

Rocket armament launchable from a tubular launcher with an outside launcher non-ignition securing and motor separation during flight and a method to prevent the ignition of the armaments rocket even in the event of actuation of the armaments pyrotechnic assembly, which normally serves to eject the armament from the launcher and to ignite its rocket motor, wherein the armament comprises a gas dispersion assembly, which when the armament is not encased in the tubular launcher, prevents the ignition of the rocket motor even if the armaments pyrotechnic assembly is actuated; and a cutting and separation assembly that is actuated by the pressure of the rocket motor gases for mechanically cutting a structural connection between the rocket motor and the armaments effective payload and separate them during their flight.

A grenade firing mechanism (12) includes a body (24) containing a firing pin (20) and a tiring pin actuator mechanism (22). A safety system includes twist to arm collar (70) and a safety interlock (92). The collar is movable between an unarmed position and an armed position and tire safety interlock is movable between a collar locking position, a collar release position and a firing position. When the collar (70) is in the unarmed position and the safety interlock (92) is in the collar locking position, actuation of the firing pin (20) is inhibited and the safety interlock (92) inhibits movement of the collar to the armed position. When, the safety interlock (92) is in the collar release position, the collar (70) is able to be moved between said unarmed and armed positions and actuation of the firing pin is inhibited. When the collar (70) is in the armed position and the -safety interlock (92) is in the firing position, actuation of the firing pin is enabled.

A grenade firing mechanism (12) includes a body (24) containing a firing pin (20) and a tiring pin actuator mechanism (22). A safety system includes twist to arm collar (70) and a safety interlock (92). The collar is movable between an unarmed position and an armed position and tire safety interlock is movable between a collar locking position, a collar release position and a firing position. When the collar (70) is in the unarmed position and the safety interlock (92) is in the collar locking position, actuation of the firing pin (20) is inhibited and the safety interlock (92) inhibits movement of the collar to the armed position. When, the safety interlock (92) is in the collar release position, the collar (70) is able to be moved between said unarmed and armed positions and actuation of the firing pin is inhibited. When the collar (70) is in the armed position and the -safety interlock (92) is in the firing position, actuation of the firing pin is enabled.

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.

A heat-activated triggering device, such as for a missile or munition, includes a bi-metal trigger element, with a breakable pin of a first metal surrounded by a sleeve made of a second metal that is different than the first metal. The sleeve may be made of a shape memory alloy, such as a single-crystal shape memory alloy, that is pre-compresses around part of the pin. The sleeve may be configured to put a tension force on the pin as the sleeve passes a predetermined temperature, for instance a temperature at which the shape memory feature of the sleeve is activated. The pin may have a weakened portion, such as a notched portion, at which the pin breaks. The breaking of the pin may be used to drive a firing pin into a primer, to initiate a detonation and/or combustion reaction.

A blasting cap simulator for use in bomb disposal training. The simulator has a bridge rectifier, a voltage regulator and an RF key fob transmitter. A fuse across the incoming power lines shorts the device and prevents it from activating until the fuse is blown. It then sends an RF signal to an instructor. The transmitter uses the power lines as an antenna to send out the RF signal. The transmitter is protected from the voltage of the power lines by a choke located on each powerline.