Advanced grenade concept with novel placement of MEMS fuzing technology
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F42C-015/184
F42C-015/40
F42C-015/24
F42C-015/22
출원번호
US-0924797
(2010-09-23)
등록번호
US-8522682
(2013-09-03)
발명자
/ 주소
Genson, Kevin
Jean, Daniel
Hendershot, John
Laib, Gerald
Olson, David
Chen, Ezra
Badescu, Veronica
Mansfield, Anthony
Caruso, Troy
출원인 / 주소
The United States of America as Represented by the Secretary of the Navy
대리인 / 주소
Zimmerman, Fedric J.
인용정보
피인용 횟수 :
6인용 특허 :
29
초록▼
The present disclosure relates to systems and methods for explosive systems such as grenades with novel micro-electromechanical systems (MEMS) fuze and novel placement of the MEMS fuze providing increased performance, reliability, and safety. The MEMS fuze is disposed towards a rear portion of the e
The present disclosure relates to systems and methods for explosive systems such as grenades with novel micro-electromechanical systems (MEMS) fuze and novel placement of the MEMS fuze providing increased performance, reliability, and safety. The MEMS fuze is disposed towards a rear portion of the explosive system providing superior performance and design flexibility. Further, the explosive system includes electronics configured to implement a launch timer and to sense impact or when the system stops spinning. The present invention includes an operational method improving safety and reliability by preventing detonation until after the launch timer expires, upon impact, or when the explosive system stops spinning.
대표청구항▼
1. An explosive system, comprising: a case comprising an interior with a front portion, a middle portion, and a rear portion;a main explosive charge being disposed within the middle portion of the interior of the case;a micro-electromechanical systems fuze disposed within the rear portion of the int
1. An explosive system, comprising: a case comprising an interior with a front portion, a middle portion, and a rear portion;a main explosive charge being disposed within the middle portion of the interior of the case;a micro-electromechanical systems fuze disposed within the rear portion of the interior of the case;circuit boards; anda piezoelectric energy source being situated substantially adjacent to the main explosive charge for detecting and harvesting energy based on a launch acceleration, wherein the piezoelectric energy source is communicatively coupled to the circuit boards and the micro-electromechanical systems fuze, wherein the micro-electromechanical systems fuze is configured, to detonate the main explosive charge, andwherein the micro-electromechanical systems fuze comprises a plurality of safety mechanisms, andwherein the micro-electromechanical systems fuze comprises a spin armed slider, a solely electronic command lock and a setback lock to hold the spin armed slider in place. 2. The explosive system of claim 1, further comprising a shaped charge liner being disposed in the front portion of the interior of the case. 3. The explosive system of claim 2, wherein the shaped charge liner is configured to penetrate a target upon detonation of the main explosive charge, and wherein penetration is unimpeded by the micro-electromechanical systems fuze. 4. The explosive system of claim 2, wherein the shaped charge liner is a conical shaped charge liner to optimize penetration into the target. 5. The explosive system of claim 1, wherein the case comprises a fragmenting case configured to fragment upon detonation of the main explosive charge. 6. The explosive system of claim 1, wherein the circuit boards comprise electronic components disposed in the rear portion and communicatively coupled to the micro-electromechanical systems fuze, and wherein the piezoelectric energy source powers the electronic components. 7. The explosive system of claim 6, wherein the plurality of safety mechanisms comprise the setback lock on the micro-electromechanical systems fuze, a timer in the circuit boards configured to remove the electronic command lock on the micro-electromechanical systems fuze, and the electronic components to detect impact and spin of the explosive system. 8. The explosive system of claim 6, wherein the plurality of safety mechanisms comprise a setback lock on the micro-electromechanical systems fuze, a timer in the circuit boards configured to remove a command lock on the micro-electromechanical systems fuze, and the electronic components sense impact and spin of the explosive system, and wherein the setback lock is released upon launch of the explosive system, the command lock is removed upon expiration of the timer, and a micro-detonator on the micro-electromechanical systems fuze detonates the main explosive charge based upon the electronic components sensing at least one of impact and cessation of the spinning. 9. The explosive system of claim 1, wherein the micro-electromechanical systems fuze comprises an initiator out of line from a micro-detonator cup disposed to the spin arm slider. 10. The explosive system of claim 9, wherein the circuit boards are disposed in the rear portion and the circuit boards are communicatively coupled to the micro-electromechanical systems fuze, wherein upon firing, the setback lock is moved out of position,wherein the circuit boards are configured to activate a timer upon firing; release the command lock upon expiration of the timer; and detect spinning and impact of the explosive system, andwherein upon release of the command lock and the setback lock, the spin armed slider moves into position such that the micro-detonator cup is in line with the initiator thereby to arm the micro-electromechanical systems fuze. 11. The explosive system of claim 1, wherein the micro-electromechanical systems fuze is comprised of silicon. 12. An explosive system, comprising: electronic components being disposed on a circuit board;a micro-electromechanical systems fuze comprising a plurality of safety mechanisms, wherein the micro-electromechanical systems fuze is communicatively coupled to the electronic components; anda piezoelectric energy source being situated substantially adjacent to a main explosive charge for detecting and harvesting energy based on a launch acceleration, wherein the piezoelectric energy source is communicatively coupled to the electronic components and the micro-electromechanical systems fuze,wherein each of the circuit board, the micro-electromechanical systems fuze, and the piezoelectric energy source are disposed in a rear portion of the explosive system, andwherein the micro-electromechanical systems fuze comprises a spin armed slider, a solely electronic command lock, and a setback lock to hold the spin armed slider in place. 13. The explosive system of claim 12, wherein the plurality of safety mechanisms comprise the setback lock on the micro-electromechanical systems fuze, a timer in the electronic components configured to remove the electronic command lock on the micro-electromechanical systems fuze, and sensors in the electronic components to detect impact and spin of the explosive system. 14. The explosive system of claim 13, wherein the setback lock is released upon launch of the explosive system, the electronic command lock is removed upon expiration of the timer, and a micro-detonator on the micro-electromechanical systems fuze detonates a main explosive charge in the explosive system based upon the sensors, which detect at least one of impact and cessation of the spin. 15. The explosive system of claim 12, wherein an initiator out of line from a micro-detonator cup disposed to the spin arm slider. 16. The explosive system of claim 15, wherein upon firing, the setback lock is moved out of position, wherein the electronic components are configured to activate a timer upon firing; release the electronic command lock upon expiration of the timer; and detect spin and impact of the explosive system, andwherein upon release of the electronic command lock and the setback lock, the spin armed slider moves into position such that the micro-detonator cup is in line with the initiator thereby to arm the micro-electromechanical systems fuze. 17. A method, comprising: providing a round, and a micro-electromechanical systems fuze;providing a piezoelectric energy source being acted upon by substantially adjacent components for powering the micro-electromechanical systems fuze;wherein the piezoelectric energy source detects and harvests energy based on a launch accelerationlaunching a round, wherein the round comprises the micro-electromechanical systems fuze in a rear portion of the round after explosive charges;releasing a setback lock on the micro-electromechanical systems fuze upon launching;initiating a timer upon launching;releasing a command lock on the micro-electromechanical systems fuze based on the timer thereby allowing a micro-detonator on the micro-electromechanical systems fuze to slide into position; anddetecting impact and detonating the round through the micro-detonator wherein the micro-electromechanical systems fuze comprises a spin armed slider, a solely electronic command lock, and the setback lock to hold the spin armed slider in place. 18. The method of claim 17, further comprising detecting no impact and detecting the round has stopped spinning and detonating the round through the micro-detonator.
Rastegar, Jahangir S.; Spinelli, Thomas, Methods and apparatus for integrated energy harvesting power sources and inertial sensors for gun-fired munitions.
Hodge, Kathleen F.; Hoffmaster, David K.; Mogan, William W.; Fines, Marion E.; Haun, Daniel V., Submunition fuzing and self-destruct using MEMS arm fire and safe and arm devices.
Robinson, Charles H.; Wood, Robert H.; Gelak, Mark R.; Hoang, Thinh Q.; Smith, Gabriel L., Ultra-miniature electro-mechanical safety and arming device.
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