A tubing conveying perforating system with a firing head is provided, and a method for using the same is provided. The firing head includes a firing pin and a percussion initiator. The firing pin is configured to degrade over a predetermined period of time from an initial state to a degraded state, and in the degraded state the firing head is inoperable.

A tubing conveying perforating system with a firing head is provided, and a method for using the same is provided. The firing head includes a firing pin and a percussion initiator. The firing pin is configured to degrade over a predetermined period of time from an initial state to a degraded state, and in the degraded state the firing head is inoperable.

Methods, systems, and devices for an area-denial munition configured for self-neutralization of an explosive ordnance. In one or more embodiments the munition including a housing including a chassis defining one or more openings such that the housing is an at least partially open structure exposing an interior to an ambient environment. In various embodiments the munition includes a detonation module including a detonation initiator and a deflagration module including a deflagration initiator coupled with a pyrotechnic primer, and munition control circuitry. In various embodiments the munition control circuitry receives instructions to deflagrate the explosive ordnance and instructs the deflagration module to activate the deflagration initiator. In various embodiments, the deflagration initiator causes a deflagration of the explosive ordnance for self-neutralization of the munition resulting in safe destruction of the munition's explosive charge and control electronics.

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 number of devices and methods for biopassivating explosive ordnance are disclosed. In some embodiments, a biopassivation reactor device is used to render energetic material in an explosive ordnance less explosive and/or non-explosive. This can be done by coupling the biopassivation reactor device to the fuse opening of the explosive ordnance. This can also be done by incorporating the biopassivation reactor device into the explosive ordnance at the time of manufacture. The biopassivation reactor device can include a housing enclosing microorganisms, water, additives, and/or the like. In some embodiments, an entire ordnance magazine can be operated as a bioreactor to passivate the explosive ordnance inside.

A concealed amalgamated neutralizer device covertly combines neutralizer material of inert materials such as calcium carbonate or silicates with common energetic material for the prevention of malicious use of the energetic material. The concealed amalgamated neutralizer device may vary in shape, size, and color and is therefore adaptable to varying methods of containment. The neutralizer material mimics the energetic material without detection. Upon disassembly of the concealed amalgamated neutralizer device, the neutralizer material is mixed with and neutralizes the energetic material rendering the energetic material useless. A container is provided which has a bottom section having an interior surface including a plurality of integrally formed recesses that are filled with the energetic material which allow manipulation of flash direction and intensity upon detonation.

Methods, systems, and devices for an area-denial munition configured for self-neutralization of an explosive ordnance. In one or more embodiments the munition including a housing including a chassis defining one or more openings such that the housing is an at least partially open structure exposing an interior to an ambient environment. In various embodiments the munition includes a detonation module including a detonation initiator and a deflagration module including a deflagration initiator coupled with a pyrotechnic primer, and munition control circuitry. In various embodiments the munition control circuitry receives instructions to deflagrate the explosive ordnance and instructs the deflagration module to activate the deflagration initiator. In various embodiments, the deflagration initiator causes a deflagration of the explosive ordnance for self-neutralization of the munition resulting in safe destruction of the munition's explosive charge and control electronics.

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.

There is provided an arming apparatus for a store, the apparatus comprising: a first attachment system and a second attachment system; a linking connector coupled with the first attachment system and the second attachment system; and an arming clip; wherein each of the first attachment system and the second attachment system comprises: a first frangible connector coupled with the arming unit and the linking connector; and a second frangible connector coupled with the linking connector and the store. The linking connector is coupled to the first attachment system via a first coupling arrangement and is coupled to the second attachment system via a second coupling arrangement, wherein the first coupling arrangement and the second coupling arrangement are different. Each of the first coupling arrangement and the second coupling arrangement are manually secure.