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 |
|---|---|---|---|---|---|---|
| 261 | 개발 가능한 지하수 포획구간 표출 및 해당 포획구간의 양수량 산출 시스템 및 그 방법 | KR1020170045864 | 2017-04-10 | KR101763135B1 | 2017-07-31 | 김준호 |
| 본발명은사용자인터페이스를통해지도상에서양수정의위치를지정하면주위의관정시설에영향을미치지않으며, 주위의오염원으로부터영향을받지않는최대범위의포획구간을자동으로설정하고, 설정된포획구간에서개발가능한양수량을산출하는개발가능한지하수포획구간표출및 해당포획구간의양수량산출시스템및 그방법에관한것이다. 본발명에의하면, 지도상에서양수정의위치좌표를설정하기만하면, 해당위치에서주위시설에영향을미치지않는최대의포획구간을표출하고, 해당포획구간에서개발가능한양수량을한번에간편하게확인할수 있다. | ||||||
| 262 | 균일한 라인 스캐닝으로 충전 재료 표면의 토폴로지를 결정하는 방법 | KR1020177010406 | 2014-10-22 | KR1020170072207A | 2017-06-26 | 밸데슈테펜; 벨레롤란트; 그리스바움카를; 페렌바흐요제프 |
| 충전재료표면(101)의토폴로지를결정하는충전레벨측정장치(100)로서, 라디에이터요소들(202)의어레이를포함하는안테나장치(102) 및어레이와평행한축(131)에대하여안테나장치를회전하는회전가능마운트를포함한다. 이방법에서, 국부적인오버스캐닝의발생없이, 안테나장치의복수의방사각도들이전자적및 기계적으로충전재료표면에대해설정될수 있다. | ||||||
| 263 | 회전 중심 수정으로 표면 토폴로지 판단에 의한 충전 수위 측정 | KR1020167030717 | 2014-05-02 | KR1020160146777A | 2016-12-21 | 호페러크리스티안 |
| 내용물의충전수위를판단하기위해, 내용물의표면을스캐닝함으로써내용물표면의토폴로지가판단된다. 내용물의표면토폴로지의산출을위해, 내용물의표면에서반사되고충전수위게이지의안테나유닛에의해수집된측정신호는상기안테나유닛의주 방사축의회전중심으로부터상기측정신호의기점(origin)의거리를참작하여분석된다. 이는측정신호의기점과주 방사축의회전중심이일치하지않는다하더라도벌크물질의정확한충전수위판단을가능하게한다. | ||||||
| 264 | 액량 검출 장치 | KR1020150033026 | 2015-03-10 | KR101657879B1 | 2016-09-19 | 마나베유이치 |
| (과제) 복수개의자기센서식검출기를이용하여, 복수개의저류부에저류되는합계의액량을검출하는구성에있어서, 접속선의총 수의증가를억제할수 있는액량검출장치를제공하는것. (해결수단) 연료량검출장치 (10) 는, 각저류부 (14, 16) 각각에배치되는제 1, 2 연료량검출기 (36, 22) 와, 접속선 (47) 을구비한다. 제 1 연료량검출기 (36) 는, 플로트 (32) 와, 아암부재 (34) 와, 제 1 아날로그신호를생성하는자기센서 (141) 와, 제 1 출력전압값을출력하고, 접속선 (47) 의일단이접속되는출력단자 (45c) 를구비한다. 제 2 연료량검출기 (22) 는, 플로트 (24) 와, 아암부재 (26) 와, 제 2 아날로그신호를생성하는자기센서 (131) 와, 접속선 (47) 의타단이접속되는기준단자 (35b) 와, 제 2 아날로그신호가나타내는전압값과, 제 1 출력전압값이적산된적산전압값에대응하는제 2 출력전압값을출력하는출력단자 (35c) 를구비한다. | ||||||
| 265 | 유체 흐름 제어 장치 | KR1020167024287 | 2012-12-21 | KR1020160107359A | 2016-09-13 | 카멘딘; 페렛밥디.; 케인데렉쥐.; 유브라이언에이치.; 트레이시브라이언디.; 존슨매튜제이.; 슈넬링거토마스에스.; 랑겐펠드크리스토퍼씨.; 라니간리차드제이.; 브라이언트주니어로버트제이.; 머피콜린에이치.; 커윈존엠.; 슬레이트마이클제이.; 우스만파루크; 클라크케이틀린에스. |
| 유체흐름을조절하기위한장치, 시스템및 방법이개시된다. 상기장치는, 탄성적으로변형가능하며, 제1 단부와제2 단부를갖는만곡된세장형지지부재를포함한다. 상기장치는만곡된세장형지지부재에대해제1 단부와제2 단부사이에튜브를배치하도록구성된대향지지부재를또한포함한다. 상기제1 단부와제2 단부가서로를향해이동함으로써만곡된세장형지지부재가변형되어상기튜브의길이를따라내부체적이감소하게된다. | ||||||
| 266 | 유체 흐름 제어 장치 | KR1020147019883 | 2012-12-21 | KR101657385B1 | 2016-09-13 | 카멘딘; 페렛밥디.; 케인데렉쥐.; 유브라이언에이치.; 트레이시브라이언디.; 존슨매튜제이.; 슈넬링거토마스에스.; 랑겐펠드크리스토퍼씨.; 라니간리차드제이.; 머피콜린에이치.; 커윈존엠.; 슬레이트마이클제이.; 우스만파루크; 클라크케이틀린에스. |
| 유체흐름을조절하기위한장치, 시스템및 방법이개시된다. 상기장치는, 탄성적으로변형가능하며, 제1 단부와제2 단부를갖는만곡된세장형지지부재를포함한다. 상기장치는만곡된세장형지지부재에대해제1 단부와제2 단부사이에튜브를배치하도록구성된대향지지부재를또한포함한다. 상기제1 단부와제2 단부가서로를향해이동함으로써만곡된세장형지지부재가변형되어상기튜브의길이를따라내부체적이감소하게된다. | ||||||
| 267 | 도막부피측정장치 및 방법 | KR1020140143426 | 2014-10-22 | KR101599031B1 | 2016-03-02 | 김종호; 이경훈 |
| 도막부피측정장치가개시된다. 본발명의실시예에따른도막부피측정장치는일측에개방부가형성되는용기부; 상기개방부에결합되는덮개부; 상기덮개부의일면에형성되고, 일측이개방되며, 도막을수용하는도막수용부; 및상기도막수용부의외측에상기덮개부를관통하여형성된관통홀을포함한다. | ||||||
| 268 | 유동 채널을 갖는 장치 | KR1020157030771 | 2014-03-27 | KR1020150138279A | 2015-12-09 | 펠버아르민 |
| 본발명은유체를위한유동채널(K)을갖는장치에관한것으로, 이장치는유동채널(K)에배치되는역류방지밸브(4)를포함하고, 이역류방지밸브(4)에의해, 유체는제 1 방향으로유동채널(K)을통해흐를수 있고또한제 1 방향의반대방향으로유동채널(K)을통해흐르는것이방지된다. 본장치는유동채널(K)을통과하는유체의유동을검출하기위한유동검출기(5)를더 포함하며, 이유동검출기(5)는역류방지밸브(4)에서의변화를검출하며, 이검출된변화는유체의유동에대한지표로서역할한다. 본발명에따른장치는, 기존의역류방지밸브를표시수단으로서사용함으로써유동이간단한수단의사용으로검출될수 있게해준다. | ||||||
| 269 | 유량 조절 장치 | KR2020140003841 | 2014-05-19 | KR2020150004258U | 2015-11-27 | 김상두 |
| 본고안은유량조절장치에관한것으로, 선박의기름탱크와연결되고공기를유입하여상기기름탱크내부에저장된기름의양을체크할수 있는유량조절장치에있어서, 공기조절부재를포함하여상기공기를유입하는에어유입부, 상기에어유입부와연결되어상기에어유입부로유입된공기를상기기름탱크로가이드하는에어가이드부및 상기에어가이드부에배치된적어도하나의밸브를포함한다. 따라서, 선박운행여부에관계없이내부에유입되는공기를제어할수 있다. | ||||||
| 270 | 콘텐츠 제공 장치 및 방법 | KR1020140053508 | 2014-05-02 | KR1020150126507A | 2015-11-12 | 권용무; 박재혁 |
| 콘텐츠제공장치는소비성물질을담을수 있는용기; 상기용기에담긴상기소비성물질의양을측정하는센서; 상기센서에의해측정된상기소비성물질의양에따라제공하는콘텐츠의출력을제어하는콘텐츠출력제어부; 및상기콘텐츠출력제어부에의해제어된출력으로상기콘텐츠를출력하는콘텐츠출력부를포함할수 있다. 또, 용기에담긴소비성물질의양을측정하는단계; 측정된상기소비성물질의양에따라제공하는콘텐츠의출력을결정하는단계; 및결정된출력으로상기콘텐츠를제공하는단계를포함할수 있다. | ||||||
| 271 | 액량 검출 장치 | KR1020140127139 | 2014-09-23 | KR1020150050342A | 2015-05-08 | 이케야마사키; 이노우에데츠지 |
| 자기센서를이용한검출기를사용한경우에있어서, 용기내에복수의검출기를배치했을때라하더라도출력신호라인의증가를억제한다.연료량검출장치 (10) 는, 용기내에설치되는복수의검출기 (22, 36) 와, 복수의검출기로부터출력되는신호에기초하여, 용기내의액량에따른검출신호를출력하는출력회로 (38) 를가지고있다. 각검출기 (22, 36) 는, 플로트 (24, 32) 와, 플로트의상하방향의운동을회전운동으로변환하는아암부재 (26, 34) 와, 아암부재의회전운동에따른아날로그신호를출력하는자기센서 (31, 41) 를가지고있다. 출력회로 (38) 는, 각검출기 (22, 36) 로부터출력되는아날로그신호가입력되고, 1897331 그들입력되는복수의아날로그신호에기초하여용기 (12) 내의액량에따른아날로그검출신호를출력한다. | ||||||
| 272 | 풍량 측정용 정압탭이 구비된 이동식 디지털 풍량 측정장치 | KR1020130078421 | 2013-07-04 | KR101415882B1 | 2014-08-06 | 오상택 |
| The present invention relates to a portable digital air volume measurement device having a static pressure tab for air volume measurement, including: a duct hopper receiving an outlet port of a blower or a duct, and having an air receiving portion to which the discharged air is introduced; a connecting pipe connected to the duct hopper to prevent loss of the discharged air formed in a bellows shape to easily adjust its length; a pressure measurement tap connected to an upper portion of the duct hopper to communicate with the air receiving portion measuring air volume, static pressure, and average pressure when the discharged air is introduced; a support handle rotatably connected to both sides of the duct hoppers having a height adjusting member to adjust its length such that the duct hopper is easily installed at a height position; a duct connecting unit having a support frame to support the duct hopper from the ground such that the discharged air is stably introduced into the connecting pipe; and an air volume measurement unit connected to the duct connecting unit to measure the volume and the air pressure. | ||||||
| 273 | 항공기의 연료 측정 시스템 및 이를 이용한 연료 측정 방법 | KR1020120087646 | 2012-08-10 | KR1020140021332A | 2014-02-20 | 김보성 |
| The purpose of the present invention is to provide a fuel measuring system for an aircraft and a fuel measuring using the same, which are to remove inaccuracy of a measured fuel amount due to changes in the flight attitude of a conventional aircraft, and to accurately measure the fuel amount regardless of the changes in the flight attitude of an aircraft. To achieve the purpose above, the fuel measuring system for an aircraft comprises: a fuel tank which stores fuel; and a fuel sensor which is mounted in the fuel tank in order to sense the remaining fuel amount in the inside thereof. In addition, the fuel measuring system for an aircraft comprises: a fuel pipe which moves the fuel from the fuel tank to an engine: a sensing unit which senses the flow rate of the fuel that flows inside the fuel pipe; and a calculating unit which calculates an initial fuel amount inside the fuel tank through the fuel sensor prior to a flight or calculates a used fuel amount by accumulating the flow rate of the fuel sensed by the sensing unit for a fixed time. The fuel measuring system for an aircraft and the fuel measuring using the same can accurately measure the remaining fuel amount inside the fuel tank regardless of changes in the flight attitude of the aircraft. [Reference numerals] (200) Calculating unit; (AA) Engine direction | ||||||
| 274 | 마이크로 밸브 유동 전산 모사기 | KR1020080040150 | 2008-04-30 | KR1020090114490A | 2009-11-04 | 원태영; 조범구; 김병환; 김수연 |
| PURPOSE: A flow simulator of micro-valve is provided to analyze the velocity field related to the valve flow in a complicated shape and to control the minute quantity of fluid flow. CONSTITUTION: A flow simulator of micro-valve is the flow interpreter of the micro valve which using the finite volume method. It is the automatic lattice generator of the micro valve for the floating analysis. The numerical analysis code finite volume method for the non-orthogonal multi-lattice system using for the automatic grid generation is used. | ||||||
| 275 | 미량의 혈액용적 측정 방법 및 그 시스템 | KR1020070056708 | 2007-06-11 | KR1020080108745A | 2008-12-16 | 차은종; 박미숙; 김경아 |
| A method and a system for measuring a very small volume of blood are provided to measure a very small volume of blood precisely and conveniently by absorbing the blood into an absorption badge for converting a very small volume into a large area so as to calculate the same into a calibration curve. An absorption badge(200) absorbs a small amount of taken blood. An image scanner(300) scans the blood of the absorption badge to convert the same a digital image. A computer(400) is connected to the image scanner for analyzing the digital image. | ||||||
| 276 | 저수용량 측량에 사용되는 지피에스 수신구 | KR1020080010597 | 2008-02-01 | KR100826631B1 | 2008-05-02 | 조희평 |
| A GPS(Global Positioning System) receiver for measuring reserved water is provided to prevent discontinuous measurement by embedding an RF(Radio Frequency) receiver. A GPS receiver for measuring reserved water includes a supporting body(10), an RF receiver(20), a finishing material(30), a GPS receiver(40), a fixing unit(50), and a supporting rest(60). The supporting body includes a receiver hole(14), a ring type groove(13), and a bolt hole(12). The receiver hole is formed on the upper center of the supporting body around the ring type groove. The bolt hole is formed on the lower center of the supporting body. The RF receiver is inserted and fixed in the ring type groove and selectively receives RF signals from a measurement device. The finishing material seals the ring type groove. The GPS receiver is inserted and fixed in the receiver hole and receives GPS signals. The fixing unit is driven into the ground and is coupled to the bolt hole of the supporting body. The supporting rest stably supports the fixing unit on the ground. | ||||||
| 277 | LIQUID LEVEL DETECTION DEVICE AND THE MOTHOD THEREOF | KR20070024476 | 2007-03-13 | KR20070093853A | 2007-09-19 | HIS MING SHU; FENG YI DENG |
| A liquid level detection device and a method for the same are provided to monitor whether a level of a liquid fuel is within a basically set standard range to supply high reaction sensitivity in measuring the level of the liquid fuel in the liquid fuel supplying tank. A liquid level detection device(10) includes an outer case(101), a heater(102), at least one temperature sensor(104), and a liquid level calculation device(106). The liquid level detection device detects the level of a liquid fuel(14) received in a tank(12). A control valve(108) is placed between the tank and the liquid level detection device. The heater is installed inside of an inner space(100) of the liquid level detection device for heating the liquid fuel in the inside space. The temperature sensor is installed inside of the inner space of the liquid level detection device for measuring the temperature of the liquid fuel in the inner space. The liquid level calculation device calculates a temperature change rate of the liquid fuel by receiving the temperature signal of the liquid fuel to be measured by the temperature sensor and converts the calculated value into the level of the liquid fuel in the tank. | ||||||
| 278 | 용기 속 제품의 무결성을 결정하는 방법 | KR1020077012397 | 2005-11-07 | KR1020070073961A | 2007-07-10 | 호이프트베른나르트 |
| According to the invention, the integrity of a product in a container (10) may be determined by the determination of a given feature of the product by means of a first measuring method (20), whereby a first physical property of the product is investigated. The given feature is additionally determined directly or by a second measuring method (30), base on a second physical property, different from the first physical property and the values for the given feature obtained by both methods are compared. Where the product is a drink in a bottle (10) and the given feature is the filling level, the first measuring method (20) can be measurement of the filling level by means of absorption of an X-ray beam and the second measuring method (30) is measurement of the change in the resonant frequency of a high frequency tuned circuit brought about by the bottle. | ||||||
| 279 | 점성 액체 층의 부피 변화 측정 방법 | KR1019990040550 | 1999-09-21 | KR1020000023324A | 2000-04-25 | 베어하비에드워드; 해일아튜로; 쉴링마샤리 |
| PURPOSE: A volume variation measurement method of viscous liquid layer is provided to determine a volume variation of a viscous liquid in a physical or chemical reaction. CONSTITUTION: A volume variation measurement method confines a viscous liquid layer on some part of a first rigid body. The viscous liquid layer(101) has even upper surface about the first rigid body. The method measures a thickness of viscous liquid layer. The viscous liquid layer is then partially reacted. A volume variation of the reacted layer is determined as a function of a measurement value of a volume variation of the viscous liquid layer. The first rigid body has a storage part having a side wall and bottom, and has a flat surface. The viscous liquid layer is confined between the flat surface and the second rigid body. The viscous liquid is confined by using adhesive agent. Thereby, a volume variation of the viscous liquid is constantly obtained in a physical or chemical reaction. | ||||||
| 280 | MULTI-CAPACITOR LIQUID DETECTION DEVICE AND METHOD(S) OF USE | US15583431 | 2017-05-01 | US20180313969A1 | 2018-11-01 | Seyedmohammad Mirisharif |
| A multi-capacitor liquid detection device and method(s) of use is described. Embodiments of the multi-capacitor liquid detection device can include at least two capacitors being separated by a predetermined height. The multi-capacitor liquid detection device can be implemented to detect and differentiate between different types of immiscible liquids by measuring and comparing a dielectric constant between two or more capacitors. The multi-capacitor liquid detection device can be implemented to determine if a false detection of a liquid has been made by one of the capacitors. | ||||||
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