This invention describes embodiments of door breaching grenades (100,100a,100b,100c,100d). Each grenade comprises a projectile (101,101a,101b,101c,101d) coupled to a propulsion cartridge (105); each projectile comprises a shell (110), a body member (140) and an ogive (180). A safe-and-arm mechanism (150) is located in the body member. A seat member (160) and a plunger (166) are assembled on a forward face of the body member so that a leading end of the plunger is in contact with an inside tip surface of the ogive, or a hollow guide member (184) is integrally formed with an inside tip surface of the ogive. In the armed state, upon impacting on a door/barricade (5), the plunger or hollow guide/sleeve impinges on a detonator pin (164), which then sets off a chain of explosive charges (152, 120, 122) whilst the projectile is still outside the door/barricade. The grenade is made substantially of polymer parts.

This invention describes embodiments of door breaching grenades (100,100a,100b,100c,100d). Each grenade comprises a projectile (101,101a,101b,101c,101d) coupled to a propulsion cartridge (105); each projectile comprises a shell (110), a body member (140) and an ogive (180). A safe-and-arm mechanism (150) is located in the body member. A seat member (160) and a plunger (166) are assembled on a forward face of the body member so that a leading end of the plunger is in contact with an inside tip surface of the ogive, or a hollow guide member (184) is integrally formed with an inside tip surface of the ogive. In the armed state, upon impacting on a door/barricade (5), the plunger or hollow guide/sleeve impinges on a detonator pin (164), which then sets off a chain of explosive charges (152, 120, 122) whilst the projectile is still outside the door/barricade. The grenade is made substantially of polymer parts.

A strike pin assembly for a fuse assembly in which the strike pin assembly is maintained in a locked position by a holding force of a filament and an interference provided by a plurality of retention bodies. Upon a breakage of the filament, such as, for example, in response to heat generated by operation of a fuse element, a trigger can be displaced via a first biasing force in a distal direction such that the trigger is positioned at a location that does not impede an inward displacement of a plurality of retention bodies from a recess of a firing pin. Upon the inward displacement of the retention bodies, a second biasing force can displace the firing pin in the distal direction such that a portion of the firing pin can protrude out from an adapter of the strike pin assembly.

Disclosed is a fire-fighting device, which includes a casing that delimits an inner cavity in which at least one dispersible fire-extinguishing agent is deposited, and pyrotechnics suitable for generating an explosion causing the casing to rupture and the fire-extinguishing agent to be dispersed. The pyrotechnics include at least one explosive charge, generating the explosion, and a detonator for triggering the explosion of the at least one explosive charge. The detonator includes an ignition device designed to trigger, when in an active state, the explosion of the at least one explosive charge, and an impact sensor designed to detect a mechanical impact received by the device and to bring the ignition device to the active state upon detection of the mechanical impact.

A method for storing energy in a device upon acceleration of the device. The method including: permitting a first movable member configured to be movable in one direction relative to a base; biasing the first movable member in a second direction opposed to the first direction; permitting a plurality of second movable members, to be each movable towards an engagement surface of the first movable member when subjected to a predetermined acceleration event in a direction offset from the first direction; and sequentially engaging a portion of the engagement surface, which when pressed causes a movement of the first movable member in the one direction against a biasing force of the first biasing member, upon an increasing acceleration of the base such that energy is stored in the first biasing member.

A method for storing energy in a device upon acceleration of the device. The method including: permitting a first movable member configured to be movable in one direction relative to a base; biasing the first movable member in a second direction opposed to the first direction; permitting a plurality of second movable members, to be each movable towards an engagement surface of the first movable member when subjected to a predetermined acceleration event in a direction offset from the first direction; and sequentially engaging a portion of the engagement surface, which when pressed causes a movement of the first movable member in the one direction against a biasing force of the first biasing member, upon an increasing acceleration of the base such that energy is stored in the first biasing member.

Fuze assembly systems, devices, and methods. The fuze assembly includes a baseplate; a first gear operably connected to the baseplate and rotatable about a fixed axis between a safety position and an armed position; and a retention device configured to retain the first gear in the safety position and enable rotation of the first gear while being subject to a centrifugal force above a first threshold from rotation of the assembly. The fuze assembly further includes a second gear in operable contact with the first gear and configured to move along a path of the baseplate due to the centrifugal force to rotate the first gear from the safety position to the armed position.

Fuze assembly methods and devices. The methods include providing a firing pin to detonate the projectile; operably connecting a weighted body to the firing pin; and operably connecting a flexural portion to the weighted body to retain position of the weighted body due to centrifugal force generated by the rotation of the projectile to retain the firing pin in a detonation prevention position and move the weighted body to drive the firing pin to a detonation position upon impact of the projectile.

Fuze assembly methods and devices. The methods include providing a firing pin to detonate the projectile; operably connecting a weighted body to the firing pin; and operably connecting a flexural portion to the weighted body to retain position of the weighted body due to centrifugal force generated by the rotation of the projectile to retain the firing pin in a detonation prevention position and move the weighted body to drive the firing pin to a detonation position upon impact of the projectile.

Fuze assembly systems, devices, and methods. The fuze assembly includes a baseplate; a first gear operably connected to the baseplate and rotatable about a fixed axis between a safety position and an armed position; and a retention device configured to retain the first gear in the safety position and enable rotation of the first gear while being subject to a centrifugal force above a first threshold from rotation of the assembly. The fuze assembly further includes a second gear in operable contact with the first gear and configured to move along a path of the baseplate due to the centrifugal force to rotate the first gear from the safety position to the armed position.