| 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 | Apparatus for testing the operation of oxygen supply equipment for aircraft | US60988045 | 1945-08-09 | US2457713A | 1948-12-28 | ROY OSBORNE RONALD; GRAHAM DUNSFORD ERNEST |
| 102 | Leak detector | US56556044 | 1944-11-28 | US2449053A | 1948-09-14 | BURNS HENRY L; THOMAS JAMES H |
| 103 | Resilient constructional element | US66636033 | 1933-04-15 | US2084116A | 1937-06-15 | JAN ZARUBA ANTONIN |
| 104 | 운항승무원용 산소시스템의 성능검측방법 및 시스템 | KR1020120066137 | 2012-06-20 | KR101769167B1 | 2017-08-17 | 구,주핑; 딩,후이팽; 후앙,레이; 왕,지안지앙; 시에,젠치앙; 주,이; 왕,롱 |
| 본발명은운항승무원용산소시스템의성능검측방법과시스템에관한것으로, 운항승무원용산소시스템의산소통내산소압력, 대기온도및 조종석온도를획득하는단계, 획득한상기산소통의산소압력, 상기대기온도및 상기조종석온도를토대로운항승무원용산소메시지를생성하는단계, 상기운항승무원용산소메시지를수신하여상기산소통내산소의표준온도에서의압력을획득하는단계, 및상기운항승무원용산소시스템의성능을판단하는단계를포함한다. | ||||||
| 105 | 호흡기 음압 적합성 검사 장치 및 방법 | KR1020167035811 | 2015-05-11 | KR1020170009960A | 2017-01-25 | 미텔스타트윌리엄에이; 레인즈칼더블유삼세; 스테인데이비드알; 아벨나탄에이; 블롬버그데이비드엠; 코웰마이클제이; 드와이어개리이; 인슬리토마스아이; 스벤슨마이클제이; 코스그로브딜란티; 라게슨켄트이; 리차오디 |
| 착용자를위한통기성공기구역을한정하고차단밸브를갖는호흡마스크본체가제공된다. 예시적인실시예에서, 마스크본체는하나이상의호흡공기공급원구성요소를수용하도록구성되는하나이상의입구포트를포함한다. 차단밸브는폐쇄위치와개방위치사이에서작동가능하고, 폐쇄위치에있을때 차단밸브는하나이상의입구포트와통기성공기구역사이의유체연통을방지하며, 차단밸브는인가된힘의부재시에개방위치로복귀한다. | ||||||
| 106 | 공기정화장치 및 그것을 위한 파과시간을 예측하는 방법 | KR1020137017620 | 2012-02-27 | KR101590087B1 | 2016-02-01 | 이시카와신고; 사사키가쿠; 다케우치히로노부; 혼다타케시 |
| 본발명은여과부의파과시간을예측할수 있는공기정화장치를제공하는것을목적으로한다. 마스크(1)를일례로하는공기정화장치가, 여과부(3)의상류측공기(40)에포함된유해가스성분의농도와, 여과부(3)를통과하는공기(40)의유량과, 공기(40)의온도와, 공기(40)의상대습도와의데이터를연산처리부(25)에입력한다. 연산처리부(25)는, 그들농도와, 유량과, 온도와, 상대습도를변수로하는파과시간의예측식이프로그램되어있어, 농도등의데이터에근거하여예측식으로부터여과부(3)의파과시간을예측한다. | ||||||
| 107 | 호흡기 부압 적합성 검사 장치 및 방법 | KR1020157023698 | 2014-01-20 | KR1020150114542A | 2015-10-12 | 미텔스타트윌리엄에이; 레인스칼더블유삼세; 스테인데이비드알; 아벨네이슨에이; 블롬버그데이비드엠; 코웰마이클제이; 드와이어개리이; 인슬리토마스아이; 스벤슨마이클제이 |
| 착용자를위한통기성공기구역을형성하고차단밸브를갖는호흡마스크본체가제공된다. 예시적인실시예에서, 마스크본체는하나이상의호흡공기원구성요소를수용하도록구성되는하나이상의입구포트를포함한다. 차단밸브는폐쇄위치와개방위치사이에서작동가능하며, 폐쇄위치에서차단밸브는하나이상의입구포트와통기성공기구역사이의유체연통을방지하고, 차단밸브는인가된힘의부존재시에개방위치로복귀한다. | ||||||
| 108 | 항공기 산소 공급 시스템의 시험 방법 | KR1019997002576 | 1998-07-16 | KR100516087B1 | 2005-09-22 | 필립스로버트존; 누난크리스토퍼 |
| 제어 신호(18)에 응답하여 수요에 따라 생성 가스 내의 변하는 농도의 산소를 공급하도록 구성된 산소 공급 장치(14), 생성 유체 흐름 내의 산소 농도 또는 부분압을 모니터하기 위한 모니터 수단(19, 20) 및 산소 공급 장치(14)에 제어 신호(18)를 제공하도록 모니터 수단에 응답하는 제어 수단(20)을 포함하는 항공기 내의 산소 공급 시스템(10)의 성능을 시험하기 위한 방법에 있어서, 제어 수단(20)은 생성 가스(15) 내의 공지된 산소 농도 또는 부분압을 공급하고 공급된 산소 농도 또는 부분압을 모니터함으로써 응답이 기대되는 산소 공급 장치(14)에 소정의 제어 신호를 제공한다. | ||||||
| 109 | 항공기 산소 공급 시스템의 시험 방법 | KR1019997002576 | 1998-07-16 | KR1020000068638A | 2000-11-25 | 필립스로버트존; 누난크리스토퍼 |
| 제어신호(18)에응답하여수요에따라생성가스내의변하는농도의산소를공급하도록구성된산소공급장치(14), 생성유체흐름내의산소농도또는부분압을모니터하기위한모니터수단(19, 20) 및산소공급장치(14)에제어신호(18)를제공하도록모니터수단에응답하는제어수단(20)을포함하는항공기내의산소공급시스템(10)의성능을시험하기위한방법에있어서, 제어수단(20)은생성가스(15) 내의알려진산소농도또는부분압을공급하고공급된산소농도또는부분압을모니터함으로써응답이기대되는산소공급장치(14)에소정의제어신호를제공한다. | ||||||
| 110 | WEARABLE MASK FIT MONITOR | EP17701620.1 | 2017-01-06 | EP3400077A1 | 2018-11-14 | FARMER, Nathaniel Rudolf; FARMER, Kenneth Rudolf, II; CALDOW, Robert |
| The respirator fit monitor described herein can be worn continuously by users so as to provide an indication as to how well their masks are fitting during use, thereby providing quantitative, wearable fit testers available for continuous use in real-life situations. The monitor includes a low-cost optical particle sensor assembly and controller unit for performing mask fit tests by comparing particle concentrations inside and outside of the mask. The fit test monitor is low cost and wearable, capable of dual sampling, capable of fit factor ratios well above 100, is battery powered and provides near real time measurements with a means for indicating the fit of the mask. The system includes wired or wireless communications for data logging, analysis and display capabilities. | ||||||
| 111 | OXYGEN SUPPLY SYSTEM WITH BUILT-IN TEST EQUIPMENT | EP16166516.1 | 2016-04-22 | EP3235545B1 | 2018-10-03 | Klose, Peter; Leuenberger, Frank |
| An oxygen supply system, in particular for a passenger aircraft, includes a container housing having a container door, a latch controller coupled to a latch of the container door and configured to control the latch to releasably open the container door, a microcontroller coupled to the latch controller and configured to output a first latch deployment signal to the latch controller to cause the latch controller to open the latch, a pressure sensor coupled to the latch controller and configured to output a second latch deployment signal to the latch controller to cause the latch controller to open the latch, and an energy storage coupled to the microcontroller and the pressure sensor, the energy storage being configured to supply the microcontroller and the pressure sensor with electrical energy. The microcontroller includes built-in test equipment (BITE), the BITE being configured to monitor and test the operability of one or more of the microcontroller, the latch controller the pressure sensor and the energy storage. | ||||||
| 112 | TEST EQUIPMENT AND METHOD FOR TESTING AN AIRCRAFT OXYGEN SYSTEM CONTROL DEVICE | EP07846897.2 | 2007-11-29 | EP2214791B1 | 2016-11-16 | QUAST, Dirk |
| 113 | MECHANICAL VENTILATION MASK FIT STATUS INDICATION | EP13771787 | 2013-04-01 | EP2833978A4 | 2015-11-04 | AHMAD SAMIR S; BALOA WELZIEN LEONARDO ALBERTO; BRAMBILLA ENRICO; CHENEY LAUREN; SEGALMAN IVA; JOHNSON SIMON |
| Indicating fit status of a mask in communication with a respiratory assistance device is disclosed. Upon initiating a therapeutic gas delivery from the respiratory assistance device to the mask, one or more measurements from respective one or more sensors of the respiratory assistance device is received. A leakage value from these measurements is derived, and a mask fit index is assigned. This is based at least upon a correlation of the leakage value to a particular sub-range of predetermined leakage values that corresponds to the mask fit index. The particular sub-range of predetermined leakage values is one among a plurality of sub-ranges, which together comprises an overall mask fit range defined at least by an ideal mask fit region, a loose mask fit region, and a tight mask fit region. A mask fit status based upon the assigned mask fit index is output to an indicator interface. | ||||||
| 114 | Test Head for Protective Mask Testing and Test Head System | EP09158681.8 | 2009-04-24 | EP2123330B1 | 2015-04-22 | Eiwen, Roland; Ehler, Björn |
| 115 | Method of testing | EP07010984.8 | 2003-12-19 | EP1897594B1 | 2013-04-24 | Peacey, David John; Phillips, Robert John |
| 116 | SYSTEMS AND METHODS FOR EVALUATING MEDICATION DELIVERY FROM VALVED HOLDING CHAMBERS WITH A FACEMASK USING A MODEL FACE | EP08856165.9 | 2008-12-05 | EP2224986A2 | 2010-09-08 | LIMBRICK, Myles; MORTON, Robert; NAGEL, Mark; MITCHELL, Jolyon; GUBBELS, Peter; WIERSEMA, Kimberly; DOYLE, Cathy; AVVAKOUMOVA, Valentina |
| Systems and methods for evaluating medication delivery from valved holding chambers (VHCs) with a facemask using a model face of a child or a model face of an infant are disclosed. Generally, the model face includes a base, an elastomer cast, an air pocket, and a mouth opening. The elastomer cast is positioned on at least a portion of a top of the base. The elastomer simulates soft tissues in a face and defines at least a nose, a chin, and a mouth sized to simulate a nose, a chin, and a mouth of a child. The air pocket is positioned between the base and the elastomer case below at least the nose, the chin, and the mouth of the elastomer cast. The mouth opening defines a passageway through the base, the air pocket, and the mouth of the elastomer cast. | ||||||
| 117 | Method of testing | EP07010984.8 | 2003-12-19 | EP1897594A3 | 2008-06-18 | Peacey, David John; Phillips, Robert John |
A method of testing a system (10) including a plurality of modules (14-17), each of which in use, produces from an air supply (11), a product gas which is one of oxygen gas and oxygen enriched gas, the method including operating a selected one of the modules (15-17) with a first module (14) or a first set of the remaining modules by providing to inlets of the selected module (15-17) and the first module (14) or the modules of the first set, an air supply (11), sensing a parameter of the product gas, produced by the selected module (15-17) and the first module (14) or modules of the first set of modules, operating the selected module (15-17) with a second module or a second set of the remaining modules, the second module or modules of the second set being different from the first module (14) or modules of the first set, and sensing the parameter of the product gas produced by the selected module and the second module or the modules of the second set, and comparing the parameter sensed with the parameter sensed while the selected module (15-17) is operated with the first module (14) or first set of modules, to determine the performance of the selected module.
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| 118 | Method of testing | EP03029368.2 | 2003-12-19 | EP1449565A1 | 2004-08-25 | Peacey, David John; Phillips, Robert John |
A method of testing a system 10 including a plurality of modules 14-17, each of which in use, produces from an air supply 11, a product gas which is one of oxygen gas and oxygen enriched gas, the method including providing to an inlet to at least one of the modules 14-17, when the module 14-17 is not in use, a restricted air supply, and at an outlet of the module 14-17, sensing at least one of the oxygen concentration and product gas pressure, and analysing the sensed oxygen concentration and/or product gas pressure during a test period to determine the potential performance of the module 14-17 in use. |
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| 119 | AUTOMATED RESPIRATOR FIT TESTING METHOD AND SYSTEM | EP01920259.7 | 2001-03-09 | EP1328322A1 | 2003-07-23 | MULLINS, Haskell, E.; MARTINSON, Paul, A.; JOHNSTON, Alan, R. |
| A system and method for the remote administration of respirator fit tests are disclosed, along with a system and method for administering qualitative respirator fit tests to two or more test subjects simultaneously. Remote administration of respirator fit tests involves the testing of test subjects located at one facility by a test administrator located at a different facility. The two facilities may be located, for example, in the same city, in different countries, etc. As a result, a single test administrator may, for example, be able to administrate fit tests with test subjects located in a variety of facilities in one day without traveling. Qualitative respirator fit testing systems and methods of the invention include multiple test stations and an aerosol generator system in fluid communication with each of the test stations. The aerosol generator system may be capable of delivering aerosol to the test stations in repeatable, selected amounts and may also be capable of delivering the aerosols to some or all of the stations simultaneously. | ||||||
| 120 | CHECKING THE OPERATION OF BREATHING EQUIPMENT | EP95926556.2 | 1995-06-26 | EP0956065B1 | 2001-11-14 | LUNDBERG, Mats |
| The invention relates to a method of checking the working and/or the state of breathing equipment prior to its use, and also to an arrangement for carrying out the method. The breathing equipment includes a control circuit which, in turn, includes a programmed microprocessor (7), a sensor (10) mounted in the breathing equipment and connected to the microprocessor, and an indicating arrangement (11) connected to the microprocessor (7). The inventive method is characterized by activating the control circuit and therewith measuring or determining at least one functional or state parameter, comparing the measured parameter value with a control value, and indicating an acceptable or unacceptable value in the indicating arrangement (11). | ||||||
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