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 |
|---|---|---|---|---|---|---|
| 161 | 연료의 체적 탄성률 결정 방법 | KR1020167011933 | 2014-11-03 | KR101799950B1 | 2017-11-22 | 킬스트럼킴; 헬레베르그로저 |
| 고압펌프(9)의고압부및 연소엔진의실린더들(5) 내로연료를분사하기위한인젝터들(7)을구비하는연료어큐뮬레이터(8)를포함하는고압체적부(16)를구비하는커먼레일연료분사시스템(6)을구비하는연소엔진(2)의연료시스템내의연료의체적탄성률(B)을결정하는방법에서, 먼저연료시스템에기지(旣知)의체적탄성률(B0)의연료를공급하고, 고압펌프가펌프스트로크를수행하여상기인젝터들이닫혀있는상태에서, 고압체적부로지정된양(M)의연료를공급하도록, 고압펌프(9)를제어함으로써, 고압체적부의체적이결정된다. 이렇게결정된체적값이추후에다른연료에서다른연료의체적탄성률을결정하는데에사용된다. | ||||||
| 162 | 이차전지용 가스 분석장치 및 그를 이용한 가스 분석방법 | KR1020140180375 | 2014-12-15 | KR1020160072571A | 2016-06-23 | 오세영; 김종훈; 김지선 |
| 본발명에따른이차전지용가스분석장치는, 이차전지가수용되고밀폐된공간을형성하는가스분석챔버와, 이차전지를지지하며, 이차전지를충전또는방전시키도록이차전지의전극리드와연결되는충방전부와, 가스분석챔버의압력과온도를센싱하는센싱부와, 가스분석챔버내부에열을공급하되, 열량을조절하여가스분석챔버의온도를순차적으로상승시키는온도제어부를포함한다. | ||||||
| 163 | 병렬공기순환형 해수의 이산화탄소분압 연속 측정 장치 | KR1020140190196 | 2014-12-26 | KR101631867B1 | 2016-06-21 | 김성; 최해영; 오지나; 조홍연 |
| 본발명은병렬공기순환형해수의이산화탄소분압연속측정장치에관한것으로서, 구체적으로는공기평형기로부터공급되는공기를듀얼공기펌프를통해해수내의이산화탄소분압을측정하는측정기와버블도입관내로각각분리하여공급하여병렬형으로개별적으로공기순환을시키는것을특징으로하는병렬공기순환형해수의이산화탄소분압연속측정장치에관한것이다. 본발명은공기평형기를중심에두고공기순환배관을통해측정기로공급되는공기공급순환과버블순환배관으로공급되는버블공급순환을독립적으로병렬형으로구성함으로써양 순환시스템에공기를공급하는펌프의압축력과공기공급량에차이가있다하더라도플로팅부재내부의해수면의수위를일정하게유지되도록함으로써측정기에서정확하게해수의이산화탄소분압을측정할수 있도록한다는장점이있다. | ||||||
| 164 | 다채널로 석탄가스의 함유량을 측정하는 휴대용 석탄 가스 측정장치 | KR1020140172105 | 2014-12-03 | KR1020160066835A | 2016-06-13 | 이원석; 권순일; 서형준 |
| 본발명은현장에서시험시추되는석탄코어에포함되는석탄가스, 예를들어, 메탄가스의함유량을측정함으로써석탄층에포함된석탄가스의매장량을추정할수 있는석탄가스의함유량을측정하는휴대용석탄가스측정장치에관한것이다. 본발명에따른휴대용석탄가스측정장치는, 휴대가능한케이스및 상기케이스에구비되고, 석탄코어가저장된코어용기와각각연결되어석탄코어로부터방출되는석탄가스의양을측정하는다수개의가스측정부를포함하며, 상기가스측정부는, 상기석탄코어로부터배출되는석탄가스가유입되는가스유입부와, 일단이상기가스유입부에연결되고, 유입된석탄가스가이동되는가스채널과, 상기가스채널의일측에장착되어이동되는석탄가스의양을측정하는가스플로어미터와, 상기가스플로어미터를통해측정된석탄가스의양을표시하는디스플레이부및 상기가스채널의타단에연결되어측정된석탄가스를배출하는가스배출부를포함하는것을특징으로한다. | ||||||
| 165 | 기체확산층의 특성 예측 방법 | KR1020130164641 | 2013-12-26 | KR1020150076037A | 2015-07-06 | 한국일 |
| 다수의홈이형성된베이스와상기홈 상에위치하는다수의립의형상을모사하는단계; 상기베이스와립이결합한분리판의형상을모사하는단계; 상기분리판상에기체확산층을배치하는단계; 및상기모사된분리판과배치된기체확산층의양 방향에서압력을인가하여상기모사된분리판의형상과상기기체확산층의변형간의대응관계를판단하는단계를포함하는기체확산층의특성예측방법이소개된다. | ||||||
| 166 | 비파괴 검사 장치 | KR1020120125584 | 2012-11-07 | KR1020140059012A | 2014-05-15 | 이원호 |
| The present invention relates to a non-destructive inspection device: which irradiates radiation to an object to be inspected through a radiation source and then detects radiation penetrating the object in order to collect image information; which detects a unique energy spectrum of a material emitted from the object through mutual reaction with radiation in order to collect substance information; which combines the image information with the substance information in order to obtain material analysis information where the substance information of the object is indicated as a three-dimensional (3D) shape on the image information; and by calculating the material analysis information of the object in time-changing states, the non-destructive inspection device provides five different dimensional information including the 3D image information, substance information, and time-changing states of the object. | ||||||
| 167 | 오일 누출 검출기 | KR1020087028331 | 2007-04-20 | KR101357366B1 | 2014-02-03 | 욜겐센,토벤 |
| 용기의 엔진 공간에서 디젤이나 연료 오일 등의 누출을 검출하는 오일 누출 검출기는 기류가 통하는 도관(102)과, 그리고 도관에서의 스크린(108)을 포함한다. 스크린(108)은 오일 입자나 드롭렛이 지나갈 수 없도록 망으로 이루어진다. 센서(110)는 스크린을 대항하여 압력 손실을 판별하고, 그리고 센서에 동작적으로 연결된 제어 시스템(114)은 압력 손실이 기설정된 임계치를 초과하는 경우 오일 누출 경고 신호를 출력하도록 구성된다. 팬(104)은 도관을 통하여 기류를 발생시키기 위해 구비될 수 있다. 탄화 수소, 일산화탄소나 이산화탄소를 판별하는 가스 센서(112)는 선택적으로 구비된다. 용기, 엔진 공간, 디젤, 도관, 스크린, 드롭렛, 센서, 제어 시스템, 가스 센서 | ||||||
| 168 | 고무보강 스틸코드 시험장치 | KR1020130041887 | 2013-04-16 | KR101292321B1 | 2013-07-31 | 최윤환 |
| PURPOSE: A device for testing a rubber-reinforced steel cord is provided to grasp the extent of the penetration of rubber by a volume of gas penetrated through a sample, thereby improving the reliability of a test. CONSTITUTION: A device for testing a rubber-reinforced steel cord includes a frame, a sample fixing device (41), a gas supply unit, and a measuring unit. The frame includes a horizontal working surface (13a). The sample fixing device is installed on the working surface and fixes a rubber-reinforced steel cord sample by receiving the same inside. The gas supply unit fit-presses the gas into an end portion of the sample received in the sample fixing device. The measuring unit measures a volume of the gas penetrated through the sample, thereby determining the extent of the penetration of the rubber inside the rubber-reinforced steel cord. | ||||||
| 169 | 오일 누출 검출기 | KR1020087028331 | 2007-04-20 | KR1020090024126A | 2009-03-06 | 욜겐센,토벤 |
| An oil leakage detector for detecting the leakage of e.g. diesel or fuel oil in an engine room of a vessel comprises a conduit (102) for an airflow therethrough, and a screen (108) in the conduit. The screen (108) is meshed to prevent oil particles or droplets from passing therethrough. A sensor (110) determines a pressure loss across the screen, and a control system (114) operatively connected to the sensor is configured to output an oil leakage warning signal if the pressure loss exceeds a predetermined threshold value. A fan (104) may be provided for generating the airflow through the conduit. A gas sensor (112) for determining the presence of hydrocarbon, carbon monoxide or carbon dioxide is optionally provided. | ||||||
| 170 | 전지셀의 부피 변화 측정 장치 | KR1020060087132 | 2006-09-11 | KR1020080023375A | 2008-03-14 | 한창권; 이우철; 지명연 |
| A device for measuring volume variation of a battery cell is provided to measure volume variation of a battery cell when the battery cell expands due to overcharge, overdischarge, and overcurrent by using a pressure gauge. A device for measuring volume variation of a battery cell comprises a sealed container(200) and a pressure gauge(150). The sealed container has a space where the battery cell is installed, and the space is filled with the air up to predetermined pressure. The pressure gauge is installed at one side of the container, being connected with the space. When volume of the battery cell is changed, the pressure of the air in the container is changed. | ||||||
| 171 | 전지셀의 부피 변화 측정 장치 | KR1020060087131 | 2006-09-11 | KR1020080023374A | 2008-03-14 | 한창권; 이우철; 윤난지 |
| A device for measuring the volume variation of a battery cell is provided to measure volume change of the battery cell due to gas generated inside the battery cell with high precision. A device for measuring volume variation of a battery cell(130) comprises a sealed container(150), a liquid(120), a gauging tube(110), and a charging and discharging unit(140). The container receives the battery cell. The liquid is filled in the container. The gauging tube is connected with the container to measure volume change of the liquid according to volume change of the battery cell. The charging and discharging unit is connected to a plus terminal(132) and a minus terminal(134). The liquid is injected to the bottom of the gauging tube, filling the container. When predetermined test conditions are set for the battery cell through the charging and discharging unit, volume change of the battery cell causes volume of the liquid to be changed and the gauging tube measures the position of the liquid. | ||||||
| 172 | 유체 성분 농도 측정방법 및 장치 | KR1020020006475 | 2002-02-05 | KR1020030021998A | 2003-03-15 | 사토데츠야; 우샹퀴안; 기미지마데츠야 |
| PURPOSE: To provide a fluid component concentration measuring method and device enabling continuous measurement in real time, adaptable to inline monitoring, applicable to a high-pressure gas and capable of coping with measurement of various components. CONSTITUTION: A sample fluid is run in a measuring pipe 14 having a small passing hole having a certain diameter in a fluid passage, and the component concentration of the sample fluid is measured by measuring a pressure difference (P1-P2) between positions before and behind the passing hole 13 at that time and a flow rate on the downstream side of the passing hole 13. | ||||||
| 173 | SYSTEM AND METHOD FOR RAPID MEASUREMENT OF THE AIR VOID DISTRIBUTION OF FRESH CONCRETE | PCT/US2013060184 | 2013-09-17 | WO2014043709A1 | 2014-03-20 | TABB BRADEN; LEY MATTHEW TYLER; FRAZIER ROBERT MAYBERRY |
| According to an embodiment, there is provided herein a method of determining the air void distribution in a sample of fresh concrete. One embodiment of the invention determines a parameter related to air void distribution by applying a known pressure to a fresh concrete sample, measuring a first value representative of the volume under compression, releases at least a portion of the pressure, reapplies the same pressure to the sample, measures a second value representative of the volume under the second compression, and uses differential between the first and second values to estimate a parameter related to the air void distribution. | ||||||
| 174 | METHOD AND DEVICE FOR DETERMINATION OF GAS IN A LIQUID PUMPED THROUGH A PUMPING DEVICE | PCT/EP2012002201 | 2012-05-23 | WO2012163497A3 | 2013-08-29 | HEDMANN FRANK; HOCHREIN TORSTEN |
| The invention relates to a method for determination of gas in a liquid, wherein the mixture of gas and liquid is delivered by a pump and is also subjected by same to a change of volume and change of pressure, operating parameters of the pump that represent the change of volume and change of pressure are detected, and the gas fraction is determined from the operating parameters of the pump, taking a system compressibility into account, wherein the system compressibility in the gas-filled pumping device is determined by a sequence of the following steps: setting a starting pressure with a pressure sensor, recording the pump position and the pressure sensor values, moving to a second pressure level, recording the pump position and the pressure sensor values in this second position, determining the spring constant on the basis of the pairs of values, and equating the spring constant so determined with the system compressibility. The invention further relates to a device for carrying out a method for determination of gas in a pumped liquid, and to a dialysis machine that contains a corresponding device. | ||||||
| 175 | MIXING OF A MULTIPHASE FLUID | PCT/EP2012054392 | 2012-03-13 | WO2012123454A3 | 2012-12-20 | VARET GUILLAUME; NASRI DJAMEL; MONTEL FRANCOIS; DARIDON JEAN-LUC |
| The invention in particular relates to a device (10) for mixing a multiphase fluid comprising a mixing chamber (14); a mixing element (16) translatable along a central axis (18) of the mixing chamber (14), the distance between a point (P S ) of the inner surface (S) of the mixing chamber (14) and the central axis (18) being occupied between 85% and 95% by the mixing element (16) along at least one section (22) transverse to the central axis (18). The invention thus allows improved mixing of a multiphase fluid. | ||||||
| 176 | SYSTEM AND METHOD FOR DETERMINING AN AIR CONTENT, AIR RELEASE ABILITY AND FOR FOAM FORMING ON OIL SURFACES | PCT/EP0311684 | 2003-10-22 | WO2004038386A3 | 2004-07-08 | LEINEMANN MAGNUS; WETZEL ARTHUR |
| The invention relates to a system (1) for determining air content, air release ability and for forming foam on oil surfaces, in particular gear oil. The inventive system (1) comprises an air-oil mixing device (2), a differential pressure gauge (3), a supply unit (4) for conveying the oil through the conduits (5) of the air-oil mixing device (2), a compressed air supply (6) which supplies air in the conduits (5) of the air-oil mixing device (2) and a Venturi tube (9) arranged in one of conduits (5). Said differential pressure gauge (3) measures the differential pressures in the oil with the aid of at least two holes (7, 8) which are arranged in the Venturi tube (9) at a distance with respect to each other in the direction of the oil conveyance. | ||||||
| 177 | FLEXIBLE PACKAGE | EP16185684.4 | 2014-01-24 | EP3133030B1 | 2017-10-25 | ARAKI, Jun; YANAGIUCHI, Motoo; SASAKI, Noriyuki; YAJIMA, Shunsuke; GOTO, Masashi |
| 178 | DETERMINING THE PARTIAL PRESSURE OF A GAS IN A PRESSURE VESSEL | EP15723038.4 | 2015-04-28 | EP3137892A1 | 2017-03-08 | KERR, Gareth |
| There is disclosed a method and system for detemining the partial pressure of at least one gas in a mixture of gasses contained in a pressure vessel, in particular a pressure vessel in the form of a life support pressure chamber/decompression chamber, or a diving gas storage cylinder. The method comprises the steps of: coupling a gas analysis sensor (14) to a pressure vessel (10); directing a portion of the mixture of gasses in the pressure vessel to the sensor for analysis; reducing the pressure of the portion of the mixture which is to be analysed by the sensor to a level which is below the pressure in the vessel but above local atmospheric pressure; operating the sensor to measure the partial pressure of the at least one gas at the reduced pressure level; and using the partial pressure of the at least one gas, measured at the reduced pressure level, to determine the actual partial pressure of said gas in the mixture contained in the vessel. | ||||||
| 179 | APPARATUS AND METHOD FOR DETERMINING AN AMOUNT OF NON-CONDENSABLE GAS | EP16165446.2 | 2016-04-14 | EP3088862A2 | 2016-11-02 | JOHNSON, Nick; HUNT, Gareth; MCKENNA, Paul; CHANNON, Paul |
There is disclosed an apparatus 10 and method for determining an amount of non-condensable gas within a fluid flow containing both non-condensable gas and condensate liquid. The method comprises receiving the fluid flow in a fluid displacement volume 18 causing the non-condensable gas to rise within the volume 10; monitoring the liquid level of a free surface in the fluid displacement volume 18 to generate a level signal; monitoring the flow of liquid out of the fluid displacement volume 18 to generate a liquid flow signal; and determining the amount of non-condensable gas based on the level signal and the liquid flow signal.
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| 180 | AN APPARATUS FOR TEMPERATURE AND FLUID RELATIVE VAPOUR PRESSURE MEASUREMENT AND ACCOCIATED METHODS | EP13871254 | 2013-12-04 | EP2943782A4 | 2016-08-24 | BORINI STEFANO; WHITE RICHARD; SPIGONE ELISABETTA; ASTLEY MICHAEL; WEI DI; KIVIOJA JANI; RYHÄNEN TEUVO |
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