| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 101 | Système de trajectographie d'un bâtiment naval | EP84401629.5 | 1984-08-03 | EP0133408A1 | 1985-02-20 | Possemé, Gilles |
L'invention concerne un système de trajectographie de bâtiment naval. Il comporte sur le bâtiment (10) un émetteur (11) de rayonnements magnétiques et, disposés au fond de la mer, deux magnétomètres triaxiaux (12 et 13). Ce système permet notamment d'établir, dans une station d'immunisation, le trajet d'un bateau immunisé ou à immuniser contre les détections magnétiques. |
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| 102 | Einrichtung zur Kompensation des magnetischen Störfeldes eines Objektes mittels einer magnetischen Eigenschutzanlage | EP80104270.6 | 1980-07-19 | EP0024307B1 | 1984-03-28 | Nissen, Walter, Dr. |
| 103 | 함정의 자기신호 저감을 위한 2단계 탈자 방법 | KR1020180074885 | 2018-06-28 | KR101892016B1 | 2018-09-28 | 정현주; 양창섭; 배기웅 |
| 본발명에따른함정의자기신호저감을위한탈자(demagnetization) 방법은, 시작자기장을인가하고, 전류의극성을교번시키면서종료자기장까지일정크기의비율로감소시키는제1 교번자기장인가단계; 제2 교번자기장을인가하여수직영구자화(PVM: Permanent Vertical Magnetization)와수직유도자화(IVM: Induced Vertical Magnetization)의합이임계값이하가되는지점을탐색하는제2 교번자기장인가단계; 및제2 교번자기장보다많은교번횟수를갖는제3 교번자기장을인가하여, 수직방향자화(VM, Vertical Magnetization)에의한자기장이발생하지않는지여부를판단하는제3 교번자기장인가단계를포함하여, 전장환경에서수중기뢰등과같은적 위협세력으로부터함정의생존성을증대시킬수 있다. | ||||||
| 104 | 소자 장비 일체형 선박 탈자 시스템을 이용한 선박 탈자 방법 | KR1020150135660 | 2015-09-24 | KR101614041B1 | 2016-04-20 | 임선호; 박현수 |
| 소자장비일체형선박탈자시스템을이용한선박탈자방법을공개한다. 본발명은센서부, 선박의소자및 탈자를위해선박내에기설정된위치에배치되는복수개의수직코일, 복수개의종축코일, 복수개의횡축코일및 메인코일을구비하는코일부, 전원부및 제어부를구비하는소자장비일체형선박탈자시스템의선박탈자방법에있어서, 제어부가선박의모드가소자모드또는탈자모드인지판별하는단계, 선박모드가탈자모드이면, 제어부가센서부에서인가되는감지신호로부터선박의방향이자북방향인지판별하는단계, 선박의방향이자북방향이면, 제어부가감지신호로부터지구자기장을분석하는단계, 제어부가선박의영구자기성분을소거하는탈자를수행하기위해, 메인코일과복수개의종축코일각각으로인가할지구자기장보상전류및 기설정된탈자전류를계산하는단계및 제어부가전원부를제어하여메인코일과복수개의종축코일각각으로계산된지구자기장보상전류및 탈자전류를인가하는단계를포함한다. | ||||||
| 105 | 소자 장비 일체형 선박 탈자 시스템 | KR1020150135659 | 2015-09-24 | KR101614039B1 | 2016-04-20 | 임선호; 박현수 |
| 소자장비일체형선박탈자시스템을공개한다. 본발명은복수개의센서를구비하여감지신호를생성하는센서부, 선박내에배치되어선박의소자를위한수직방향, 종축방향및 횡축방향자기를생성하기위한복수개의소자코일및 탈자를위한수직방향및 종축방향의자기를생성하기위한복수개의탈자코일을구비하는코일부, 감지신호를인가받아선박의현재위치와상태, 지구자기장의변화및 선박의유도자기성분을분석하고, 소자모드또는탈자모드시에선박의유도자기성분과영구자기성분을저감하기위해복수개의소자코일과복수개의탈자코일각각으로인가되어야하는보상전류를계산하는제어부및 제어부의제어에따라코일부의소자코일및 탈자코일각각으로전류를인가하는전원부를포함하고, 코일부는종축방향의자기를생성하기위한탈자코일과소자코일을공통으로이용하는것을특징으로한다. | ||||||
| 106 | HTSC 자기소거 코일용의 인터페이스 장치 및 접속 배선함 | KR1020107023902 | 2009-03-18 | KR101330233B1 | 2013-11-15 | 킹,크리스토퍼,쥐.; 맥과이어,제임스,에프. |
| 적어도 하나의 고온 초전도체(HTS) 전선 다발(2)의 개별의 도체(3)의 직렬 접속을 허용하는 접속 배선함(14)이 제공된다. 해당 접속 배선함은 접속 배선함 하우징 내에 배치된 전기적 인터페이스 장치(3)를 포함한다. 해당 인터페이스 장치는 각각의 HTS 전선 다발의 각 도체의 양 단부를 입수하여, 도체의 각각의 제1단부와 다른 전선 다발 도체의 각각의 제2단부 간의 초전도성 전기 접속을 제공하여 적어도 하나의 초전도 멀티-턴 전자기 권선을 형성하도록 구성되어 있다.
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| 107 | 고온 초전도 테이프를 포함하는 컴팩트한 가요성 고전류 컨덕터 | KR1020097001426 | 2007-07-23 | KR101152467B1 | 2012-06-01 | 오토알렉산더; 맨슨랄프피; 매귀어제임스에프; 유안지에 |
| 고온 초전도(High Temperature Superconducting; HTS) 테이프를 포함하는 고전류의 컴팩트한 가요성 컨덕터와 이 컨덕터 제조 방법이 설명되어 있다. HTS 테이프는 스택으로 배치되고, 복수 개의 스택은 상위 구조체를 형성하도록 배치되며, 상위 구조체는 케이블 축을 중심으로 꼬여 HTS 테이블이 얻어진다. 본 발명의 HTS 케이블은 디가우징(degaussing)을 위한 자기장을 생성하는 데 채용되는 케이블과 고전류 전력 전달 또는 분배 용례과 같은 다양한 용례에 사용될 수 있다. | ||||||
| 108 | 초전도 선재를 이용한 함정 탈자 시스템 | KR1020100082530 | 2010-08-25 | KR101027535B1 | 2012-04-18 | 김형수 |
| PURPOSE: A demagnetization system using a superconductive wire for a vessel is provided to reduce the time for winding by employing a lightweight superconductive wire. CONSTITUTION: A demagnetization system using a superconductive wire for a vessel comprises a superconductive cable(30), a power supply device(20), a cooling device(10), and a vacuum pump(14). The superconductive cable comprises a superconductive wire wound around a vessel, a first insulation layer surrounding the superconductive wire, a second insulation layer blocking heat exchange between the first insulation layer and the atmosphere, and an intermediate layer which is filled with a blocking material for blocking heat transfer between the first and second insulation layers. The power supply device supplies electric current to the superconductive wire for cancelling a permanent magnetic field created in the vessel. The cooling device injects coolant into the first insulation layer and circulates the coolant through the first insulation layer, thereby maintaining the superconductive wire in a predetermined temperature range. | ||||||
| 109 | MAGNETIC SIGNATURE ASSESSMENT | PCT/GB2007004086 | 2007-10-26 | WO2008050137A3 | 2009-04-02 | TWELVETREES ROGER; COX EMILY; GANDERTON CARL; RAWLINS PAUL; WATSON STEPHEN MILES |
| Magnetic signature assessment apparatus for a vehicle comprising sensors for incorporation in the vehicle to measure the magnetic field normal to a closed surface at least approximately bounding the vessel and processing means for calculating from the normal field measurements a scalar magnetic potential outside the surface. Apparatus may be provided on the vehicle to generate a magnetic field to suppress the magnetic signature corresponding to the scalar potential. The invention also extends to corresponding methods and to programs for implementing those methods. | ||||||
| 110 | HIGH-CURRENT, COMPACT FLEXIBLE CONDUCTORS CONTAINING HIGH TEMPERATURE SUPERCONDUCTING TAPES | PCT/US2007016544 | 2007-07-23 | WO2008011184A3 | 2008-04-10 | OTTO ALEXANDER; MASON RALPH P; MAGUIRE JAMES F; YUAN JIE |
| High-current, compact, flexible conductors containing high temperature superconducting (HTS) tapes and methods for making the same are described. The HTS tapes are arranged into a stack, a plurality of stacks are arranged to form a superstructure, and the superstructure is twisted about the cable axis to obtain a HTS cable. The HTS cables of the invention can be utilized in numerous applications such as cables employed to generate magnetic fields for degaussing and high current electric power transmission or distribution applications. | ||||||
| 111 | MULTIPHASE COAXIAL SUPERCONDUCTING CABLES AND CORC DEGAUSSING SYSTEM | PCT/US2014045794 | 2014-07-08 | WO2015006350A3 | 2015-02-19 | VAN DER LAAN DANIËL CORNELIS |
| A superconducting cable and connection structure includes one or more superconducting cables. Each cable has superconducting tapes wound about a former in a plurality of phases. Superconducting tapes of a first phase extends further toward a distal end of each cable end than the superconducting tapes of the second phase. The first and second cable ends of one superconducting cable (or a first end of a first superconducting cable and a second end of a second superconducting cable) are arranged with the first phase of the second cable end electronically coupled to the second phase of the first cable end. Connector structures may couple the cable ends together. The cable(s) form one or more loops within a cryostat, to form a degaussing coil. | ||||||
| 112 | DYNAMIC DEGAUSSING SYSTEM | PCT/US0330886 | 2003-10-01 | WO2005015578A3 | 2006-08-10 | SWINBANKS MALCOLM A; RUCKMAN CHRISTOPHER E; HOLFORD JOHN M |
| A dynamic degaussing system includes a magnetic field sensor (136) for generating a sensor signal in response to a sensed magnetic field. The magnetic field sensor (136) is coupled to a controller (400) that produces an output signal based on the sensor signal. The controller may include feedforward and feedback control loops. The output signal of the controller controls a magnetic field generator (130) which generates a magnetic field so as to attenuate the sensed magnetic field. | ||||||
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