| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 使地雷放置后限制可能触发地雷的时间段的地雷附加物 | CN200480030102.2 | 2004-10-15 | CN1867810A | 2006-11-22 | 宝莱斯·斐尔凡 |
| 本发明由起始部件(2B)组成,其在下侧制成锥形并成为地雷触发装置(1)的部件。当它旋入地雷主体(3)时,容纳腐蚀性物质的安瓿(D2)由锐利的尖末端打破,腐蚀性物质溢出并到达起始部件(2B)并将起始部件浸没其中。此腐蚀性物质缓慢侵蚀起始部件(2B)的壁,当其把壁蚀穿,此腐蚀性物质与置于起始部件(2B)内的起始爆炸物混合,将其浸泡并将其中和,用这样的方式,此初始爆炸性物质失去它的爆炸特征,并且此地雷再也不能被触发。圆柱形套(D)用作放置安瓿(D2)和在安瓿(D2)破裂之后,保留腐蚀性液体。 | ||||||
| 2 | 使地雷放置后限制可能触发地雷的时间段的地雷附加物 | CN200480030102.2 | 2004-10-15 | CN100529647C | 2009-08-19 | 宝莱斯·斐尔凡 |
| 本发明由起始部件(2B)组成,其在下侧制成锥形并成为地雷触发装置(1)的部件。当它旋入地雷主体(3)时,容纳腐蚀性物质的安瓿(D2)由锐利的尖末端打破,腐蚀性物质溢出并到达起始部件(2B)并将起始部件浸没其中。此腐蚀性物质缓慢侵蚀起始部件(2B)的壁,当其把壁蚀穿,此腐蚀性物质与置于起始部件(2B)内的起始爆炸物混合,将其浸泡并将其中和,用这样的方式,此初始爆炸性物质失去它的爆炸特征,并且此地雷再也不能被触发。圆柱形套(D)用作放置安瓿(D2)和在安瓿(D2)破裂之后,保留腐蚀性液体。 | ||||||
| 3 | Dud de-arming device or insert for projectile fuse | JP11228389 | 1989-05-02 | JPH01318900A | 1989-12-25 | ROBERUTO APOTEROTSU |
| PURPOSE: To obtain a dud de-arming device which can be built in an existing projectile fuse by moving a rotor to a safety position through a spring or mov ing a collision sensor through a collision delay part upon unlocking thereby releasing the rotor and moving it to a safety position through the spring force of safety units. CONSTITUTION: The dud de-arming device is encased in a tubular case 15, a rotor 17 is locked at a shooting position and a trigger means is located at an unlocking part such that the rotor 17 is moved to a safety position by the spring force of safety units 23-32 upon unlocking. A rotor 43 is held at a shooting position before hitting a target through a collision sensor 45 constituting the trigger means. The collision sensor 45 is moved by a collision delay part to release the rotor 43 which is then moved to a safety position by the spring force of the safety units 23-32. COPYRIGHT: (C)1989,JPO | ||||||
| 4 | Safety ignition circuit for underwater igniter | JP13572880 | 1980-09-29 | JPS56105299A | 1981-08-21 | GIYUNTAA BATSUKUSHIYUTAIN; HANSU BUARUTAA UNGAA; MIHIAERU GIYUNTAA; DEIITAA KARUTOBAITSUAA; HENDORIKU BUERUTOHEEN |
| 5 | 제어불능 이스케이프먼트용의 기계적 자폭기 | KR1020097027429 | 2008-05-30 | KR1020100033983A | 2010-03-31 | 테일러노먼씨 |
| An escapement fuze self-destruct mechanism for a projectile includes a drive weight that maintains a biasing member in a compressed state by centrifugal force when a projectile's RPM speed is above a preselected threshold. When the RPM speed falls below the preselected threshold, the biasing member exerts sufficient counter-rotational force to overcome the centrifugal force exerted by the drive weight. The biasing member expands to an uncompressed state and displaces the drive weight into position for mechanically implementing self-destruction of the projectile if a rotor is fully armed or for rendering the projectile ''safe'' if the rotor is in any position other then fully armed. | ||||||
| 6 | 화약퓨즈가 구비된 운반 고리 | KR1020140062183 | 2014-05-23 | KR101537904B1 | 2015-07-20 | 정선태; 윤여민 |
| 본발명은포탄의보관시사용되는운반고리에화약퓨즈를구비한운반고리로대체함으로써화재시포탄이열 축적에의해주장약이점화되더라도폭발하지않고연소를유지시켜포탄의둔감성을향상시킬수 있는안전장치로서, 화약퓨즈가구비된운반고리에관한것이다. 본발명에의한화약퓨즈가구비된운반고리는화약퓨즈가주장약및 보조장약보다낮은온도에서점화되어개구부를형성함으로써탄약의폭발이아닌연소를유도하여포탄의둔감성을향상시킬수 있는장점이있다. | ||||||
| 7 | DETONATOR ARMING | PCT/ZA2004000071 | 2004-06-25 | WO2005005912A3 | 2005-02-24 | KOEKEMOER ANDRE LOUIS; LABUSCHAGNE ALBERTUS ABRAHAM |
| A detonator which, once armed, is automatically disarmed after a predetermined time period in the absence of at least one defined signal during such time period. | ||||||
| 8 | Firing Mechanism for a Grenade, a Grenade and a Method of Operating a Grenade | US15572057 | 2016-06-06 | US20180135954A1 | 2018-05-17 | Duncan Thomas |
| 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. | ||||||
| 9 | Method for providing electrical energy to a self-destruct fuze for submunitions contained in a projectile | US15783808 | 2017-10-13 | US09939242B2 | 2018-04-10 | Jahangir S Rastegar; Richard T Murray; Chris Janow; Richard Dratler |
| A method for providing electrical energy to a self-destruct fuze for submunitions in a projectile, the method including: storing mechanical energy in an elastic element attached to a first movable mass at one end of the elastic element upon a firing acceleration of the projectile; engaging a second movable mass with the first movable mass such that movement of the second movable mass upon the acceleration moves the second movable mass which in turn moves the first movable mass; converting the stored mechanical energy to electrical energy upon the acceleration to vibrate the first movable mass and the elastic element to apply a cyclic force to a piezoelectric element attached to another end of the elastic element; and locking the second movable mass in a position where the second movable mass cannot interfere with vibration of the first movable mass upon the second movable mass being subjected to the acceleration. | ||||||
| 10 | ROCKER ARM DETONATOR | US15185563 | 2016-06-17 | US20170363400A1 | 2017-12-21 | Helge GRAF |
| A rocker arm detonator is provided that includes a detonator head, which includes a pivotably arranged firing pin which is acted upon by a firing pin spring, and has a safety clip, which is pivotably disposed in the same direction of rotation as the firing pin from a starting position, in which it is pressed in the direction of the detonator head to a firing pin release position. To reliably avoid an unintentional detonation of the rocker arm detonator prior to its proper use, when the rocker arm detonator is not in use, the firing pin spring is in its untensioned state and may be tensioned by a separate tensioning lever as soon as the rocker arm detonator is to be properly deployed. | ||||||
| 11 | Rocker arm detonator | US15185563 | 2016-06-17 | US09846019B1 | 2017-12-19 | Helge Graf |
| A rocker arm detonator is provided that includes a detonator head, which includes a pivotably arranged firing pin which is acted upon by a firing pin spring, and has a safety clip, which is pivotably disposed in the same direction of rotation as the firing pin from a starting position, in which it is pressed in the direction of the detonator head to a firing pin release position. To reliably avoid an unintentional detonation of the rocker arm detonator prior to its proper use, when the rocker arm detonator is not in use, the firing pin spring is in its untensioned state and may be tensioned by a separate tensioning lever as soon as the rocker arm detonator is to be properly deployed. | ||||||
| 12 | Thermal trigger with an integrated out-of-line lockout device for a thermally-initiated ventilation system or other system | US14802683 | 2015-07-17 | US09696125B2 | 2017-07-04 | Paul A. Merems |
| A device includes a thermal trigger having a firing pin, where the thermal trigger is configured to move the firing pin in response to an elevated temperature. The device also includes an out-of-line lockout device configured to disarm the thermal trigger in response to acceleration of the lockout device. The lockout device is configured to move a first lockout ball into a notch of the firing pin to disarm the thermal trigger. The lockout device could include an inertial mass configured to move the first lockout ball into the notch of the firing pin and a first spring configured to bias the inertial mass in an initial position. The lockout device could also include a second lockout ball configured to move into a position that prevents the inertial mass from returning to the initial position or a dampener configured to slow movement of the inertial mass. | ||||||
| 13 | Signal Inhibiting Apparatus and Corresponding Methods | US15457853 | 2017-03-13 | US20170187485A1 | 2017-06-29 | Timothy Patrick Dunnigan |
| An apparatus (100) includes a canine harness (101) with a radio frequency inhibitor (400). A leash (1002) can serve as a control device (102). The leash can selectively mechanically couple to the canine harness and electrically couple an actuator (114) to the radio frequency inhibitor. When the actuator is actuated, the radio frequency inhibitor is to emit one or more radio frequency inhibition signals (405), which can include the emission of all programmed signals simultaneously. Radio frequency inhibitors can also be integrated into clothing or armor (1802), as well as equipment (1901). The radio frequency inhibitor can interrupt, suppress, or halt electronic detonation communications to an explosive device. | ||||||
| 14 | MULTI-ACTION FUZE AND WARHEAD SEPARATOR FITTED TO A MUNITION | US14683319 | 2015-04-10 | US20160131466A1 | 2016-05-12 | NICOLAS HORACIO BRUNO; KEVIN MICHAEL SULLIVAN |
| A multi-step separator for a fuze is configured to be mated to an explosive device in a military munition, either at a production facility during manufacture of the munition or during use in the field. The fuze includes a detonator with a booster or spit-back element for initiating an energetic sequence resulting in a high-order detonation of the explosive device. The multi-step separator includes: (a) a fuze-munition interface device for retaining the fuze in a confined, close relationship with the explosive device and for releasing the fuze when and if it is subjected to an external stimulus that may cause it to detonate the explosive device; and (b) a separating device for physically distancing the fuze from the explosive device when and if the fuze is released. | ||||||
| 15 | Systems and Methods for Firearm Cartridge Management | US14183542 | 2014-02-19 | US20150233660A1 | 2015-08-20 | Rick H. Barton |
| An ignition inhibitor system within a firearm cartridge and a method of making same, comprising an internal framework with a top end and a bottom end as well as chambering and sub-sections for, a fluid chamber, a switch, a power source an actuator; said bottom end having port holes in proximity to a fluid chamber adjacent to the primer charge; a switch located within said internal framework that is activated by one of electromagnetic energy transmission devices, radio frequency identification transmission devices and other wireless signaling technologies and systems; as well as an actuator that causes the deployment of fluid in the fluid chamber sub-section, a power source, which are connected with electrically conductive materials and all of which are located within said internal framework; and fluid that is released upon the activation of said ignition inhibitor system described herein. | ||||||
| 16 | Energy harvesting power sources for detecting target impact of a munition | US11654289 | 2007-01-17 | US08701559B2 | 2014-04-22 | Jahangir S. Rastegar; Carlos M. Pereira; Richard Dratler |
| A method for detecting a target impact of the munition. The method including: providing the munition with a power supply having a piezoelectric material for generating power from an axial vibration induced by the munition; monitoring an output from the power supply; and determining if the munition has axially impacted a target based on the output. | ||||||
| 17 | Munition having detonation time-out circuitry | US13792008 | 2013-03-09 | US08635956B2 | 2014-01-28 | Jahangir S. Rastegar; Carlos M. Pereira; Richard Dratler |
| A munition including: a power supply having a piezoelectric material for generating power from a vibration upon impact of the munition; a processor operatively connected to the power supply for initiating detonation time-out circuitry to disable detonation of the munition after a predetermined time. | ||||||
| 18 | Deactivating an explosive composition using plants | US12865670 | 2009-02-02 | US08618347B2 | 2013-12-31 | Thomas Smylie; Richard John Goodridge; Deane Tunaley; Steven Kotsonis; Les Armstrong; Brad Beikoff |
| A method of deactivating an explosive composition provided in an explosive cartridge, which method comprises exposing the explosive composition to a deactivating agent that renders the explosive composition insensitive to detonation, wherein the deactivating agent is a plant. | ||||||
| 19 | Device and method for calculating at least one of a force and an acceleration of an object | US13487232 | 2012-06-03 | US08581474B2 | 2013-11-12 | Jahangir S. Rastegar; Carlos M. Pereira; Richard Dratler |
| A method for generating electrical power from an acceleration of an object is provided. The method including: vibrating a mass-spring unit upon an acceleration of an object; transmitting a force resulting from the acceleration from the mass-spring unit to the one or more piezoelectric elements; converting the vibration of the mass-spring unit to an electrical energy; and calculating at least one of the force and acceleration based on an output of the one or more piezoelectric elements. | ||||||
| 20 | Detonation control system | US12874878 | 2010-09-02 | US08369062B2 | 2013-02-05 | Delmer D. Fisher; Brady A. Plummer; Robert W. Plummer |
| According to certain embodiments, a detonation control system includes a controller circuit coupled to a manual switch and a detonation device. The detonation device is configured to activate an explosive. The controller circuit includes a memory operable to store one of a multiple time-to-fire settings representing a time delay from arming the detonation device to activation of the detonation device. The controller circuit is operable to store a first time-to-fire setting in the memory, store another of the multiple time-to-fire settings in the memory upon actuation of the manual switch, and repeat the step of storing another of the multiple time-to-fire settings in the memory for each actuation of the manual switch. | ||||||
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