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 |
|---|---|---|---|---|---|---|
| 181 | SYSTEMS AND METHODS FOR EFFICIENT TWO-PHASE HEAT TRANSFER IN COMPRESSED-AIR ENERGY STORAGE SYSTEMS | US13755636 | 2013-01-31 | US20130145764A1 | 2013-06-13 | Troy O. McBride; Benjamin R. Bollinger; Jon Bessette; Alexander Bell; Dax Kepshire; Arne La Ven; Adam Rauwerdink |
| In various embodiments, foam is compressed to store energy and/or expanded to recover energy. | ||||||
| 182 | APPARATUS, METHOD AND COMPUTER PROGRAM PRODUCT FOR MOVING CARGO, AND A KIT AND METHOD FOR UPGRADING AN APPARATUS FOR MOVING CARGO | US13681113 | 2012-11-19 | US20130125540A1 | 2013-05-23 | Pekka VAINONEN; Ilkka LEPPÄNEN; Jens WACHSMUTH |
| There is provided an apparatus, method, computer program product, and a kit and method for upgrading, an apparatus for moving cargo. A bus for transmission of electrical energy, at least one load connected to the bus, said at least one load configured to transform electrical energy from the bus into movement of a cargo with respect to the apparatus energy transforming means configured to transform energy between electrical energy of the bus and potential energy of a hydraulic accumulator, wherein the apparatus is configured to store electrical energy from the bus as potential energy to the hydraulic accumulator and to supply the potential energy stored in the hydraulic accumulator as electrical energy to the at least one load. | ||||||
| 183 | SYSTEMS AND METHODS FOR FOAM-BASED HEAT EXCHANGE DURING ENERGY STORAGE AND RECOVERY USING COMPRESSED GAS | US13644476 | 2012-10-04 | US20130074488A1 | 2013-03-28 | Troy O. McBride; Benjamin Bollinger; Jon Bessette; Dax Kepshire; Arne LaVen; Adam Rauwerdink; Alexander Bell |
| In various embodiments, foam is compressed to store energy and/or expanded to recover energy. | ||||||
| 184 | SYSTEMS AND METHODS FOR FOAM-BASED HEAT EXCHANGE DURING ENERGY STORAGE AND RECOVERY USING COMPRESSED GAS | US13644497 | 2012-10-04 | US20130074485A1 | 2013-03-28 | Troy O. McBride; Benjamin Bollinger; Jon Bessette; Dax Kepshire; Arne LaVen; Adam Rauwerdink; Alexander Bell |
| In various embodiments, foam is compressed to store energy and/or expanded to recover energy. | ||||||
| 185 | Volume Booster with Stabilized Trim | US12882549 | 2010-09-15 | US20120061594A1 | 2012-03-15 | Michel K. Lovell; Ryan J. Jwanouskos; Gary L. Scott; Kenneth W. Junk; Mark Stiehl |
| A fluid flow control device includes a body having an inlet connection, an outlet connection, and a discharge port. A supply path extends between the inlet connection and the outlet connection and a booster module is disposed within the body. The booster module includes a control element and an actuator element and defines an exhaust path extending between the outlet connection and the discharge port. A supply port is disposed within the booster module along the supply path between the inlet connection and the outlet connection and at least a first damping means operatively connected to the booster module. | ||||||
| 186 | DEVICE FOR ORIENTING AN OBJECT ACCORDING TO A GIVEN SPATIAL ORIENTATION | US13207599 | 2011-08-11 | US20120041252A1 | 2012-02-16 | Jean-Sébastien Plante; Geneviève Miron; Sylvain Proulx; Patrick Chouinard; Alexandre Girard; Jean-Philippe Lucking-Bigué |
| There is disclosed a device for orienting an object according to a given spatial orientation. The device comprises a frame and a supporting member connected to the frame and adapted for supporting at least a portion of the object. The device for orienting an object comprises a plurality of fluid actuated devices for displacing the supporting member with respect to the frame. Each of the fluid actuated devices is actuatable between a first position wherein the device has a first length and a second position wherein the device has a second length. The device for orienting comprises an actuation mechanism comprising a plurality of actuating valves for actuating the corresponding fluid actuated device; wherein an actuation of at least one of the fluid actuated devices enables to displace the supporting member with respect to the frame, thereby orienting the object according to the given spatial orientation. The device for orienting may be of particular interest in the medical sector as a medical object manipulator for reaching a given target in an anatomical structure with a suitable accuracy, for example in the treatment and/or diagnosis of prostate cancer. | ||||||
| 187 | SYSTEMS AND METHODS FOR REDUCING DEAD VOLUME IN COMPRESSED-GAS ENERGY STORAGE SYSTEMS | US13080910 | 2011-04-06 | US20120000557A1 | 2012-01-05 | Troy O. McBride; Michael Neil Scott; Benjamin Bollinger; Andrew Shang; Robert Cook; Lee Doyle |
| In various embodiments, dead space and associated coupling losses are reduced in energy storage and recovery systems employing compressed air. | ||||||
| 188 | Motion imparting apparatus | US178319 | 1994-03-14 | US5605462A | 1997-02-25 | Phillip R. M. Denne |
| A control mechanism for a simulator or stabilized platform comprising constant force spring device for supporting the weight of the platform and a plurality of impulsive force generating devices preferably in the form of electromagnetic linear rams although a rotary linkage driven by an electric motor would also work. The mechanism provides an agile arrangement at relatively low cost. | ||||||
| 189 | Self-manifolding cylinders | US3422728D | 1966-10-18 | US3422728A | 1969-01-21 | BLACK DONALD M; CARFAGNO SAMUEL J |
| 190 | Device for operating bulkhead doors | US56533431 | 1931-09-26 | US1846293A | 1932-02-23 | DIEDRICH WIESE |
| 191 | Device for operating bulkhead doors | US29144228 | 1928-07-09 | US1832337A | 1931-11-17 | DIEDRICH WIESE |
| 192 | 중공형 다단식 유압 실린더 | KR1020140048548 | 2014-04-23 | KR1020150122402A | 2015-11-02 | 한연수 |
| 본발명은중공형다단식유압실린더에관한것으로, 더욱상세하게는중공을가진복수개의실린더가다단형태로연결설치되어유압에의해가장내측실린더에설치된연결대가직선운동함과동시에나머지실린더의중공에의해안내를받으면서돌출되어기계적으로강한압력을외부로전달하는중공형다단식유압실린더에관한것이다. 이러한본 발명은, 중공이형성되는고정브래킷; 일단이상기고정브래킷의일면에고정되고, 제1내통과제1외통으로구획되며, 상기제1내통은상기중공과연통되고, 상기제1외통의일측과타측에각각제1유체출입구와제1'유체출입구가형성되는제1실린더; 일단이상기제1외통의내부에구속되어상기제1외통의내부에서직선운동가능하게설치되고, 제2내통과제2외통으로구획되며, 상기제2내통은상기제1내통과연통하고, 상기제2외통의일측에상기제1외통을통해상기제1유체출입구와연통하는제2유체출입구가형성되고상기제2외통의타측에상기제1외통을통해상기제1'유체출입구와연통하는제2'유체출입구가형성되는제2실린더; 일단이상기제2실린더의제2외통내부에구속되어상기제2외통의내부에서직선운동가능하게설치되는제3실린더; 및상기제3실린더의타단내측에고정되어상기제1내통의안내에따라상기중공을출입하는연결대;를포함하여구성되어, 상기제1유체출입구로유체가유입되고상기제2유체출입구를통해유체가유출되면, 상기제1외통과상기제2외통으로유압이차례대로작용하면서상기제2실린더와상기제3실린더가차례대로직선운동하면서상기연결대가상기제1내통의안내를받아상기제2내통과상기제1내통및 상기중공을통과하여상기고정브래킷의타면으로돌출되는것을특징으로하는중공형다단식유압실린더를기술적요지로한다. | ||||||
| 193 | 작업기의 유압 시스템 | KR1020137020415 | 2012-08-21 | KR101458335B1 | 2014-11-04 | 호리이히로시 |
| 본 발명은 유압 액추에이터 제어용 파일럿 전환 밸브를 파일럿 조작하는 리모트 컨트롤 밸브의 저온 시에 있어서의 응답성의 확보를 도모할 수 있는 작업기의 유압 시스템을 제공하는 것이다. 언로드 밸브(V13)를 언로드 위치(29)로 한 상태에서, 리모트 컨트롤 밸브(PV1, PV2, PV6)에 파일럿 펌프(19)의 토출 회로(Y)로부터의 압유를 공급하는 파일럿 펌프 유로(w)에 오일을 유통시키기 위해, 파일럿 펌프(19)의 토출 회로(Y)의 오일을 파일럿 펌프 유로(w)의 종단부에 흘리는 난기 회로(H)를 설치한다. | ||||||
| 194 | 압축 공기 에너지 저장 시스템 내의 효율적인 2상 열전달을 위한 시스템 및 방법 | KR1020137033314 | 2012-05-16 | KR1020140031319A | 2014-03-12 | 맥브라이드토레이오.; 볼링거벤자민; 베셋존; 벨알렉산더; 캡샤이어닥스; 라벤아르네; 라우어딩크애담 |
| 다양한 실시예에서, 포말이 에너지를 저장하기 위해 압축되고 그리고/또는 에너지를 회수하기 위해 팽창된다. | ||||||
| 195 | 마스터 실린더 장치 및 그것을 사용한 액압 브레이크 시스템 | KR1020137024968 | 2011-02-25 | KR1020130129289A | 2013-11-27 | 이소노히로시 |
| 본 발명의 마스터 실린더 장치는, 전방측의 단부가 폐색되고, 내부를 전방실 (R1) 과 후방실 (R2) 로 구획함과 함께 자신을 관통하는 개구가 형성된 제 3 하우징 부재 (164) 를 갖는 하우징 (150) 과, 전방실 내에 배치 형성된 본체부 (180) 를 가지며, 브레이크 장치 (56) 에 공급되는 작동액을 가압하기 위한 힘을 자신에게 받아 전진하는 제 1 가압 피스톤 (152) 과, 브레이크 페달 (70) 에 가해진 조작력에 의해 전진 가능한 입력 피스톤 (156) 을 가지며, 제 1 가압 피스톤의 본체부의 후단과 제 3 하우징 부재의 사이에, 고압원 장치 (58) 로부터의 작동액이 도입되는 입력실 (R5) 과, 입력 피스톤이 하우징과 시일 끼워 맞춤됨으로써, 입력 피스톤과 수압 피스톤이 시일 끼워 맞춤되지 않고, 그들 피스톤의 사이에, 구획부에 형성된 개구를 이용하여, 그들 피스톤이 서로 마주 보는 피스톤 간실 (R8) 이 각각 형성되어 있는 것을 특징으로 한다. | ||||||
| 196 | 작업기의 유압 시스템 | KR1020137020415 | 2012-08-21 | KR1020130114707A | 2013-10-17 | 호리이히로시 |
| Provided is a hydraulic system for a work machine, which can ensure low temperature responsiveness of remote control valves that perform pilot operations of pilot operated directional control valves for controlling hydraulic actuators, respectively. In order to, with bringing an unloading valve V13 to an unloading position 29, circulate oil to a pilot pump oil passage w that supplies the pressure oil from the discharging circuit Y for a pilot pump 19 to remote control valves PV1, PV2, and PV6, a warm-up circuit H that flows the oil from the discharging circuit Y for the pilot pump 19 to a terminal of the pilot pump oil passage w is provided. | ||||||
| 197 | 방향전환수단을 구비한 강성구현장치, 이를 이용한 햅틱장치, 이를 이용한 초소형 이동체 및 그 제어방법 | KR1020090071496 | 2009-08-04 | KR1020110013837A | 2011-02-10 | 양태헌; 권동수; 김상연; 구정회 |
| PURPOSE: A rigidity realizing device, a haptic device using the same, a micro moving body and a control method are provided to convert an external force action direction to the direction conversion unit, thereby being applied to a small and narrow space. CONSTITUTION: A housing(10) accepts MRF inside and includes a through-hole. A movable member(20) is included inside the housing and moves back and forth in one straight direction in a space which the MRF is accepted. One end of a connecting member(30) is inserted to the through-hole and is connected to a movable member. Another end of the connecting member is projected to the external side of the housing. A direction conversion unit(40) is included in another end of the connecting member and converts an external force action direction. A magnetic field application unit(50) is included inside the housing and applies the magnetic field to the MRF. | ||||||
| 198 | 센서와 유변유체를 이용한 햅틱 장치, 이를 갖는 전자기기및 이를 이용한 햅틱 제공방법 | KR1020080053037 | 2008-06-05 | KR1020090126760A | 2009-12-09 | 양태헌; 권동수; 육남수; 김승찬 |
| PURPOSE: A haptic device using a sensor and rheological fluid, an electronic device having the same, and a haptic providing method using the same are provided to offer proper haptic feedback when a user grips, twists, or pulls the electronic device. CONSTITUTION: A display unit(120) like an LCD(Liquid Crystal Display) is installed to a front side of the electronic device. A sensor senses a force(110) of one direction or deformation by the force. A flexible fluid pipe(200) is contiguous to the sensor. Rheological fluid is filled inside the fluid pipe. A controller changes rigidity of the fluid pipe by applying electric power based on an output signal of the sensor. A user recognizes rigidity change of the fluid pipe. | ||||||
| 199 | 유변유체를 이용한 패시브형 햅틱 장치 및 이를 이용한햅틱 제공방법 | KR1020080047507 | 2008-05-22 | KR1020090121548A | 2009-11-26 | 양태헌; 권동수; 육남수 |
| PURPOSE: A passive haptic device using rheological fluid and a haptic providing method using thereof are provided to offer quick response to a user of an electronic device. CONSTITUTION: A position sensing unit(150) outputs a contact position signal sensing a contact of a user. The rheological fluid are filled inside fluid tubes(200). The fluid tube has a predetermined pliability. A haptic unit(170) is equipped in the lower part of the location perception part. Multiple fluid tubes are arranged in the haptic unit. The controller approves electricity to some of the fluid tubes based on the contract position signal of location perception part. The controller changes the intensity of the fluid tubes. | ||||||
| 200 | ENERGY STORAGE STRUCTURE | US15406469 | 2017-01-13 | US20180106275A1 | 2018-04-19 | Fugang YANG |
| Provided is an energy storage structure, comprising a housing and a piston. An accommodating cavity and a piston cylinder part communicating with each other are arranged within the housing. The piston is slidably and sealingly arranged within the piston cylinder part for transferring impact energy. A self-pressure of an energy storage medium, arranged within the accommodating cavity and the piston cylinder part, acts on the piston, tending to push the piston to move. An energy storage structure provided by the present invention has a simple structure, is convenient for use, and can ensure that a thrust or impact force remains unchanged or slightly changes during operation, to achieve stable release of potential energy. Moreover, the adjustment of the thrust or impact force can be achieved by changing the temperature of the energy storage medium in the accommodating cavity, thereby achieving change in total impact energy of the energy storage structure. | ||||||
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