子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | Sicherungseinrichtung für einen Zünder eines Gefechtskopfes | EP87114311.1 | 1987-10-01 | EP0267407A1 | 1988-05-18 | Hälssig, Andreas; Mossmann, Horst; Dinger, Horst |
Eine Zündeinrichtung mit Rotor(3) soll nur dann in eine Munition einbaubar sein, wenn der Rotor in Sicherstellung steht. Steht er in Scharfstellung, dann soll ein Einbau der Zündeinrichtung nicht möglich sein. Diese weist ein Einbausicherungsglied(5) auf, zwischen dem und dem Rotor(3) ei ne Koppelstelle(10,12,13) ausgebildet ist. Der in Scharfstellung stehende Rotor(3) blockiert das Einbausicherungsglied(5), so daß ein Einbau der Zündeinrichtung nicht möglich ist. Über die Koppelstelle(10,12,13) gibt der in Sicherstellung stehende Rotor(3) das Einbausicherungsglied(5) zum Übergang in die Einbaustellung frei. In Einbaustellung ist eine Rotorbewegung nicht beeinträchtigt. |
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| 22 | 전파식 근접신관에서의 고도에 따른 감지거리 조정회로 | KR2019960054187 | 1996-12-23 | KR2019980041097U | 1998-09-15 | 김동환 |
| 본고안은전파식근접신관에관한것으로서, 더자세하게는고도가낮아짐에따라서수신장치에서의감지거리레벨을변화시키는기능을가진근접신관의송수신장치에대한것이다본 고안은, 송신기능과수신기능을구비하고, 송신된신호가목표물에의해반사된신호를수신하여목표물과의거리를탐지하는전파식근접신관에있어서, 목표물에의해반사되어되돌아온 신호중에서도플러신호를검출하기위한검출부; 상기검출부의후단에위치하고, 기준레벨감지기와조정부에의해발생하는제어신호에따라조정되는증폭기; 상기증폭기의출력신호의크기를일정한기준레벨과비교하여그 값들의차이에비례하는신호출력을발생시키기위한기준레벨감지기; 상기기준레벨감지기의출력을소정값으로시간지연시켜증폭기에입력시키기위한조정부를포함하는것을특징으로하는고도에따른감지거리조정회로를제공함으로서, 근접신관의고도가낮아짐에따른잡음증가에대응하는처리기능에의하여, 근접한거리에서의목표물탐지기능을향상시키는효과를달성한다. | ||||||
| 23 | 신관수신기의 중간주파 증폭용 트랜지스터 증폭회로 | KR2019960043334 | 1996-11-29 | KR2019980030238U | 1998-08-17 | 박정희 |
| 본고안은한국형신관에사용가능한중간주파증폭기및 그검파기회로에관한것으로, 더자세하게는증폭기의주파수대역이넓고소형크기로제작가능한신관수신기의중간주파증폭용트랜지스터증폭회로및 이증폭회로와일체로결합된검파기회로에관한것이다. 본고안은, 포탄신관의수신기에사용되며, 주파수변환회로를거쳐생성된중간주파의신호를증폭하기위한중간주파증폭기에있어서, 입력되는중간주파신호를바이패스시켜트랜지스터증폭기에인가하기위한커패시터; 상기커패시터를통한입력신호가그 베이스에인가되고, 전원전압이저항기를거쳐그 콜렉터에인가되는트랜지스터; 전원전압을상기트랜지스터의베이스에바이어스하기위해그 전압을분압하는두개의저항기; 상기트랜지스터의이미터와그라운드사이에연결되어그 바이어스를안정화시키기위한저항기; 상기저항기와병렬로연결되어고주파신호를바이패스시키기위한커패시터; 그리고, 상기트랜지스터에의해증폭된중간주파의신호를출력시키기위해그 콜렉터에연결되어고주파신호만을출력시키기위한커패시터를포함하여형성되는것을특징으로하는신관수신기의중간주파증폭용트랜지스터증폭회로를제공한다. | ||||||
| 24 | MUNITION WITH FUZE SHOCK TRANSFER SYSTEM | EP15800998.5 | 2015-05-29 | EP3218666B1 | 2018-05-16 | CUNDIFF, Brandon J.; SPILOTRO, John J.; LEE, Wayne Y.; CHRISTIANSON, Kim L.; BOOTES, Thomas H.; SHIRE, Jason M.; WADDELL, Jesse T. |
| A munition has a fuze that is mounted nonparallel to the axis of the munition, for example having a largest extent that is perpendicular to the longitudinal axis of the munition. Shocks from the fuze are transferred through a shock transfer device that is in contact with the fuze, to an initiation device that is also in contact with the shock transfer device. Shocks passing through the shock transfer device to the initiation coupler pass through a relatively narrow neck of the shock transfer device. In the shock transfer device the shock is concentrated and located precisely at the neck, before spreading out again and being transferred to the initiation device. In the initiation device the shock may detonate a high explosive material, which in turn is used to detonate a main explosive of the munition, such as a warhead. | ||||||
| 25 | Dispositif propulsif à progressivité regulée | EP09290837.5 | 2009-11-04 | EP2192376B1 | 2015-04-22 | Caillaut, Nicolas |
| 26 | Electrowetting battery having a nanostructured electrode surface | EP04256701.6 | 2004-10-29 | EP1533857B1 | 2007-01-03 | Kroupenkine, Timofei N.; Taylor, Joseph A.; Weiss, Donald |
| 27 | Artilleriegeschoss | EP99122446.0 | 1999-11-11 | EP1001244B1 | 2003-07-23 | Schildknecht, Manfred, Dr.; Stammel, Georg |
| 28 | SHOCK-RESISTANT ELECTRONIC CIRCUIT ASSEMBLY | EP97911702 | 1997-10-09 | EP0935734A4 | 2001-07-04 | MARSHALL PAUL N; TSEKA THOMAS C; WALSH BRENDAN M; FRITZ JAMES E |
| A shock-resistant electronic circuit assembly (10) is provided in which an electronic circuit is encased in an encapsulation (14) that engages a surrounding enclosure (18, 22) in shock-dispersing contact therewith. The encapsulation may have a plurality of edges (16, 16a, 16b), fins (24) or bosses (70) that bear against the enclosure. The encapsulation may include a shock-absorbing material (14f) disposed against the enclosure to protect the circuit against vibrations and a structural support material (14e) to protect the circuit against stress. The circuit assembly (10) may contain a capacitor (34) for storing an electrical signal and timing circuitry for releasing the stored energy after a predetermined delay. The circuit assembly (10) may be part of a transducer-circuit assembly (55) that includes a transducer module (58) for converting shock wave energy into electrical energy for the electronic circuit, and the released enregy may be converted into a detonation initiation signal. Assembly (55) may be part of a detonator (100) that receives a non-electric initiation signal and detonates following the delay determined by the electronic circuit. The detonator housing (112) or an optional sleeve (22) provides an enclosure for the assembly (55). | ||||||
| 29 | Ammunition impact fuse | EP90850279.2 | 1990-08-15 | EP0426627A3 | 1992-04-29 | Carlsson, Bengt |
An ammunition unit (1) is provided with a fuze function which is sensitive to impact on both soft and hard targets (19) and comprises a front barrier (2) which effects piercing of a hard target. Mounted behind the barrier is a safety and armament part (6). This is fixed in its longitudinal displacement direction by means of a locking member (14). The locking member yields when the ammunition unit, after striking the target (which causes a certain compression of the ammunition unit in its longitudinal direction), undergoes rearward compression and thus causes a relative movement between the barrier of the part connected to it and the safety and armament part (6). A relative movement is permitted between the safety and armament part and the other parts of the shell, with simultaneous retention of the centring of the safety and armament part in the ammunition unit. |
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| 30 | Sicherungseinrichtung für einen Zünder eines Gefechtskopfes | EP87114311.1 | 1987-10-01 | EP0267407B1 | 1991-01-16 | Hälssig, Andreas; Mossmann, Horst; Dinger, Horst |
| 31 | Mehrteiliger Geschoss-Zünder | EP85102686.4 | 1985-03-09 | EP0161409A2 | 1985-11-21 | Stützle, Dietmar, Dr. |
Ein mehrteiliger Geschoß-Zünder soll aus kostengünstig herstellbaren Einzelteilen bestehen. Dafür ist vorgesehen, Zünder-Teile - gleichgültig, ob es sich z. B. um Metallteile oder um Kunststoff-Gußteile handelt - mit einer im Wege der Kathoden-Zerstäubung aufgebrachten Oberflächen-Metallisierung als abriebfestem Schutz gegen Umwelteinflüsse und als elektrischen Schutzschirm gegen Einstreuen elektrischer Felder zu versehen. Insbesondere solche Oberflächen-Bereiche, die nach dem Zusammenbau der Zünder-Einzelteile als elektrische (ohmsche) Kontaktstrecken dienen, weisen zweckmäßigerweise zusätzlich eine Vergoldung auf. |
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| 32 | ARMING DEVICE FOR SEA MINES | EP83903235.0 | 1983-10-13 | EP0141812A1 | 1985-05-22 | BJÖRK, Jan; SVENSSON, Sven, Gunnar |
| Dispositif d'armement pour mines marines comprenant un détonateur électrique (26), une charge de transfert (16) et un interrupteur (34) pouvant être inséré entre le détonateur et la charge de transfert pour séparer ces deux éléments. Le détonateur fait partie d'une unité séparée (20) qui peut être insérée dans un espace (19) dans un logement (18) aménagé dans le dispositif d'armement. Des contacts électriques agissant de concert (28, 29, 30, 31) sont disposés dans l'unité et dans l'espace, respectivement, pour la connexion électrique du détonateur lors de l'insertion de celui-ci dans l'espace. | ||||||
| 33 | Mechanical inertial igniter with high-height drop safety feature for thermal batteries and the like | US13180469 | 2011-07-11 | US09123487B2 | 2015-09-01 | Jahangir S. Rastegar |
| A method for initiating a thermal battery including: releasing an engagement between an element and a striker mass upon an acceleration time and magnitude greater than a first threshold; and moving at least one member into a path of the element to prevent the element from releasing the striker mass only where the acceleration time and magnitude is greater than a second threshold, the second threshold being greater than the first threshold. | ||||||
| 34 | AMUNITION WITH PROJECTILE CONTAINING NO EXPLOSIVE MATERIAL IN ORDER TO CREATE A MULTI-SPECTRAL TARGET SIGNATURE | US14098106 | 2013-12-05 | US20140305328A1 | 2014-10-16 | Lars Dierks; Christopher Zimmermann |
| An ammunition is proposed with an explosive-free missile that releases, upon dismantling at the target a fuel or fuel mixture as flammable air-fuel mixture, being caused to spontaneously react by at least one, by impact dismantling triggered, explosive-free, spark-generating ignition mechanism. The thus produced optical and thermal target signature can be detected with the naked eye, as well as with rifle scopes or other optical target detection systems, as well as with night-vision and thermal imaging devices. | ||||||
| 35 | CHANGING THE STATE OF A SWITCH THROUGH THE APPLICATION OF POWER | US14119294 | 2011-06-02 | US20140091893A1 | 2014-04-03 | Clovis Satyro Bonavides; Daniel F Dorffer; Jim Taylor Hill |
| A switch includes a spring. The switch further includes a collapsing element. The spring has a first state in which it is being held in tension by a restraining element and a second state in which it is not being held in tension because the restraining element has failed. The collapsing element is situated such that when sufficient power is applied to the collapsing element heat from the collapsing element will cause the restraining element to fail. The switch further includes a first contact coupled to the spring. The switch further includes a second contact coupled to the spring. The first contact and the second contact are separate from each other when the spring is in the first state. The first contact and the second contact are electrically connected to each other when the spring is in the second state. | ||||||
| 36 | Multi-caliber fuze kit and methods for same | US12469443 | 2009-05-20 | US08513581B2 | 2013-08-20 | Chris E. Geswender; Cesar Sanchez; Matthew A. Zamora |
| A multi-caliber fuze kit includes a fuze housing configured for coupling with multiple projectiles. One or more canards are moveably coupled with the fuze housing. The one or more canards are adjustable between two or more canard configurations. In a first canard configuration, the one or more canards are at a first canard angle relative to a bore sight of the fuze housing, and the first canard angle is configured for use with a first projectile. In a second canard configuration, the one or more canards are at a second canard angle relative to the bore sight of the fuze housing, and the second canard angle is configured for use with a second projectile. The first and second canard angles are different. In another example, in the first canard configuration the one or more canards include a first canard shape configured to provide a first specified trajectory with the first projectile. In the second canard configuration the one or more canards include a second canard shape configured to provide a second specified trajectory with the second projectile. The first canard shape and the second canard shape are different. | ||||||
| 37 | RESERVE CELL-ARRAY NANOSTRUCTRED BATTERY | US10803565 | 2004-03-18 | US20100183906A1 | 2010-07-22 | Marc Scott Hodes; Paul Robert Kolodner; Timofei Nikita Kroupenkine; Alan Michael Lyons; Mary Louise Mandich; Joseph Ashley Taylor; Donald Weiss |
| A battery having an electrode with at least one nanostructured surface is disclosed wherein the nanostructured surface is divided into cells and is disposed in a way such that an electrolyte fluid of the battery is prevented from contacting the portion of electrode associated with each cell. When a voltage is passed over the nanostructured surface associated with a particular cell, the electrolyte fluid is caused to penetrate the nanostructured surface of that cell and to contact the electrode, thus activating the portion of the battery associated with that cell. The current/voltage generated by the battery is controlled by selectively activating only a portion of the cells. Multiple cells can be active simultaneously to produce the desired voltage. The more cells that are active, the higher the current/voltage and the lower the overall life of the battery. The life of the battery can be extended by activating fewer cells simultaneously. | ||||||
| 38 | Accelerometer mounting for a penetrator and method thereof | US11613497 | 2006-12-20 | US07552682B2 | 2009-06-30 | Stanley N. Schwantes; Bradley M. Biggs; Michael A. Johnson |
| A fuze for a weapon configured as a projectable device is provided to reduce the mechanical amplification of impact and penetration shock to a fuze-mounted accelerometer when a projectable device including the fuze encounters a target. The fuze includes a fuze housing having an outer surface, a flange extending radially from the outer surface of the fuze housing, and an acceleration sensor connected to the flange. The flange may include one or more axial holes to enable attachment of the fuze to a projectable device. A penetrating weapon projectable device and a method for installing a fuze for a projectable device are also provided. | ||||||
| 39 | Electrowetting battery having a nanostructured electrode surface | US10716084 | 2003-11-18 | US20050106459A1 | 2005-05-19 | Timofei Kroupenkine; Joseph Taylor; Donald Weiss |
| A method and apparatus are disclosed wherein a battery comprises an electrode having at least one nanostructured surface. The nanostructured surface is disposed in a way such that an electrolyte fluid of the battery is prevented from contacting the electrode, thus preventing discharge of the battery when the battery is not in use. When a voltage is passed over the nanostructured surface, the electrolyte fluid is caused to penetrate the nanostructured surface and to contact the electrode, thus activating the battery. In one illustrative embodiment, the battery is an integrated part of an electronics package. In another embodiment, the battery is manufactured as a separate device and is then brought into contact with the electronics package. In yet another embodiment, the electronics package and an attached battery are disposed in a projectile that is used as a military targeting device. | ||||||
| 40 | Munition article with antenna for satellite navigation | US09951244 | 2001-09-13 | US06615734B2 | 2003-09-09 | Volker Koch; Martin Hertel; Werner Wiesbeck; Eberhard Gschwendtner |
| A munition article is to be provided with an antenna which, by virtue of a characteristic which is uniform all around, permits interference-free reception of items of satellite navigation information, even if in the manner of an artillery projectile it is fired with spin along an elongate ballistic trajectory, so that a tail antenna with a spherical characteristic does not allow the expectation of good reception factors in relation to navigation satellites which are as high as possible above the horizon. Therefore the tip (10) of the fuse tip (11) of the projectile is equipped with a dipole satellite antenna which faces in the direction of flight. Connected to the dipole (13) which is arranged concentrically with respect to the longitudinal axis (14) of the projectile are symmetrically disposed conductor portions (15) which rest with a close fit in recesses (19) in the ballistic cap (12). | ||||||
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