초록 ▼

A fuze for a submunition comprises a fuze housing with a stabilizer ribbon for aerodynamic orientation, a fuze slider released by tension on the stabilizer ribbon, an air-powered electric generator extended into the airstream by the fuze slider and powered in flight by high-speed airflow, a MEMS saf

A fuze for a submunition comprises a fuze housing with a stabilizer ribbon for aerodynamic orientation, a fuze slider released by tension on the stabilizer ribbon, an air-powered electric generator extended into the airstream by the fuze slider and powered in flight by high-speed airflow, a MEMS safety and arming device, a fuze circuit board including an explosive fireset, and an electrically initiated firetrain. The fuze is fixed to and communicates explosively with the end of a grenade warhead.

대표청구항 ▼

What is claimed is: 1. A MEMS safety and arming mechanism, comprising: a setback slider operable to move in a first direction from a safe position to a latched position in response to a setback acceleration, the setback slider being spring biased against movement in the first direction; an arming s

What is claimed is: 1. A MEMS safety and arming mechanism, comprising: a setback slider operable to move in a first direction from a safe position to a latched position in response to a setback acceleration, the setback slider being spring biased against movement in the first direction; an arming slider operable to move in a second direction opposite the first direction, from a safe position to an armed position in response to a deceleration, the arming slider being spring biased against movement in the second direction; a first lock that prevents movement of the arming slider, the first lock comprising a setback sequence pivot that is rotatable from a first position that prevents movement of the arming slider to a second position that allows movement of the arming slider, the second position of the setback sequence pivot being attained when the setback slider reaches the latched position and the arming slider begins movement in the second direction; and a second lock that prevents movement of the arming slider, the second lock comprising a command rotor that is rotatable from a first position that prevents movement of the arming slider to a second position that allows movement of the arming slider, the second position of the command rotor being attained in response to a command arm electrical signal that is generated externally of the MEMS safety and arming mechanism. 2. The MEMS safety and arming mechanism of claim 1 further comprising a substrate and a frame above the substrate, the frame including openings in which each of the setback slider, arming slider, first lock and second lock move. 3. The MEMS safety and arming mechanism of claim 2 wherein the setback slider and the opening for the setback slider include zigzag portions that provide an inertial delay to movement of the setback slider. 4. The MEMS safety and arming mechanism of claim 2 wherein the command rotor first position is attained after partial movement of the arming slider in the second direction. 5. The MEMS safety and arming mechanism of claim 4 wherein the arming slider includes a transfer charge disposed therein. 6. The MEMS safety and arming mechanism of claim 5 further comprising a command rotor actuator disposed adjacent the command rotor and operable to move the command rotor from the first position to the second position in response to the command arm electrical signal. 7. The MEMS safety and arming mechanism of claim 6 wherein the command rotor actuator comprises a bellows actuator. 8. The MEMS safety and arming mechanism of claim 1 wherein the setback sequence pivot comprises right and left arms, the right arm being heavier than the left arm. 9. The MEMS safety and arming mechanism of claim 8 wherein the setback slider comprises a setback slider sequence pocket for receiving the left arm of the setback sequence pivot when the setback sequence pivot is in its second position. 10. The MEMS safety and arming mechanism of claim 8 wherein the arming slider includes a shoulder, the right arm of the setback sequence pivot bearing on the shoulder of the arming slider when the setback sequence pivot is in its first position. 11. The MEMS safety and arming mechanism of claim 2 wherein the command rotor includes a foot and the arming slider includes a safety catch tab, the foot of the command rotor engaging the safety catch tab of the arming slider when the command rotor is in its first position. 12. The MEMS safety and arming mechanism of claim 11 wherein the command rotor includes a latch barb and the frame includes a rotor latch indent, the latch barb engaging the rotor latch indent in the second position of the command rotor. 13. A MEMS safety and arming device, comprising: the MEMS safety and arming mechanism of claim 5; an input explosive column located adjacent one end of the transfer charge when the arming slider is in the armed position such that detonation of the input explosive column causes detonation of the transfer charge and located distant the one end of the transfer charge when the arming slider is in the safe position such that detonation of the input explosive column does not cause detonation of the transfer charge; and an output explosive column located adjacent another end of the transfer charge when the arming slider is in the armed position such that detonation of the transfer charge causes detonation of the output explosive column and located distant the another end of the transfer charge when the arming slider is in the safe position such that detonation of the transfer charge does not cause detonation of the output explosive column. 14. The MEMS safety and arming device of claim 13 further comprising a cover assembly with an explosive initiator, the cover assembly being disposed over the frame, the input explosive column being disposed in the cover assembly with one end of the input explosive column adjacent the initiator such that detonation of the initiator causes detonation of the input explosive column. 15. The MEMS safety and arming device of claim 14 further comprising an explosive output assembly with an explosive output charge, the explosive output assembly being disposed below the frame, the output explosive column being disposed in the explosive output assembly with one end of the output explosive column adjacent the explosive output charge such that detonation of the output explosive column causes detonation of the explosive output charge. 16. A fuze for a munition having a warhead, comprising: a fuze housing; a fuze slider having a first position in the fuze housing and a second position at least partially out of the fuze housing; and the safety and arming device of claim 15 disposed in the fuze housing. 17. The fuze of claim 16 wherein the safety and arming device is attached to the fuze slider and further wherein, in the first position of the fuze slider, the explosive output charge of the safety and arming device is located such that detonation of the explosive output charge does not cause detonation of the warhead and, in the second position of the fuze slider, the explosive output charge of the safety and arming device is located such that detonation of the explosive output charge does cause detonation of the warhead. 18. The fuze of claim 17 further comprising a fuze circuit board electrically connected to the safety and arming device; an accelerometer electrically connected to the fuze circuit board; and an air powered generator disposed on the fuze slider and electrically connected to the fuze circuit board. 19. The fuze of claim 18 further comprising a ribbon attached to the fuze housing wherein drag force on the ribbon is operable to free the fuze slider to move at least partially out of the fuze housing. 20. The fuze of claim 19 wherein, in the second position of the fuze slider, the air-powered generator supplies electric power and a signal indicative of fuze deceleration to the fuze circuit board as the fuze decelerates in the atmosphere. 21. The fuze of claim 20 wherein the fuze circuit board sends the command arm electrical signal to the MEMS safety and arming device when the command rotor is in its first position. 22. The fuze of claim 21 wherein the command arm electrical signal activates the command rotor actuator to move the command rotor from its first position to its second position. 23. The fuze of claim 22 wherein with the command rotor in its second position, the arming slider moves to the armed position, if the fuze has a deceleration greater than a spring force biasing the arming slider against movement to the armed position. 24. The fuze of claim 23 wherein when the accelerometer senses an impact, the fuze circuit board sends a fire signal to the explosive initiator in the cover assembly of the MEMS safety and arming device. 25. The fuze of claim 24 wherein the explosive initiator causes detonation of the input explosive column, which then detonates the transfer charge, if the arming slider is in the armed position. 26. The fuze of claim 25 wherein the transfer charge detonates the output explosive column, which detonates the explosive output charge, which detonates the warhead, if the fuze slider is in its second position.