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 |
|---|---|---|---|---|---|---|
| 101 | Power receiving device, control method of power receiving device, and power feeding system | JP2012089053 | 2012-04-10 | JP2013219944A | 2013-10-24 | ARISAWA SHIGERU |
| PROBLEM TO BE SOLVED: To provide a power receiving device that can correctly detect foreign matter.SOLUTION: A power receiving device includes: a power receiving coil configured to receive power when a power feeding device supplies the power via a magnetic field; an alternating-current power supply configured to apply an alternating voltage to the power receiving coil; and a foreign matter detecting section configured to generate an amount of change in impedance of the power receiving coil from the alternating voltage and a current that is induced in the power receiving coil to which the alternating voltage is applied, and detect foreign matter between the power receiving coil and the power feeding device on the basis of the amount of change. | ||||||
| 102 | Heat transfer compositions | JP2012553388 | 2011-02-14 | JP2013519779A | 2013-05-30 | ロバート、イー.ロー |
| The invention provides a heat transfer composition consisting essentially of from about 60 to about 85% by weight of trans-1,3,3,3-tetrafluoropropene (R-1234ze(E)) and from about 15 to about 40% by weight of fluoroethane (R-161). The invention also provides a heat transfer composition comprising R-1234ze(E), R-161 and 1,1,1,2-tetrafluoroethane (R-134a). | ||||||
| 103 | Electrical energy storage recovery system and the electrical energy storage return method | JP2010506972 | 2008-04-21 | JP5037679B2 | 2012-10-03 | リュエ、ジャック |
| 104 | Electrical energy storage recovery system and the electrical energy storage return method using a piston gas compressor-expander unit | JP2010529434 | 2008-10-03 | JP5032665B2 | 2012-09-26 | リュエ、ジャック |
| 105 | Control method and turbine equipment of turbine equipment | JP2011501451 | 2009-03-27 | JP4969701B2 | 2012-07-04 | 誠 加藤; 隆 園田; 雅英 宇麼谷; 仁意 小野; 直人 杼谷; 文倫 藤井 |
| To provide a method of controlling a turbine equipment and a turbine equipment capable of carrying out a starting operation of controlling a load applied to a speed reducing portion while complying with a restriction imposed on an apparatus provided at a turbine equipment. The invention is characterized in including a speed accelerating step (S1) of increasing a revolution number by driving to rotate a compressing portion and a turbine portion by a motor by way of a speed reducing portion, a load detecting step (S2) of detecting a load applied to the speed reducing portion by a load detecting portion, and a bypass flow rate controlling step (S3) of increasing a flow rate of a working fluid bypassed from a delivery side to a suction side of the compressing portion when an absolute value of the detected load is equal to or smaller than an absolute value of a predetermined value and reducing the flow rate of the bypassed working fluid when equal to or larger than the absolute value of the predetermined value. | ||||||
| 106 | Rankine cycle integrated into absorption chiller | JP2011236558 | 2011-10-28 | JP2012097742A | 2012-05-24 | FREUND SEBASTIAN WALTER |
| PROBLEM TO BE SOLVED: To provide a power generation system using waste heat.SOLUTION: The power generation system includes: a Rankine cycle-first working fluid circulation loop comprising a heater, an expander, a recuperator, a first working fluid condenser, a desorber, a first working fluid pump, and a first working fluid comprising CO2; and an absorption chiller cycle comprising a second working fluid circulation loop, which itself comprises an evaporator, an absorber, a second working fluid pump, a desorber, a second working fluid condenser, and a second working fluid comprising a refrigerant. The Rankine cycle and the absorption chiller cycle are integrated at the desorber. The condenser of the Rankine cycle functions as the evaporator of the absorption chiller cycle. | ||||||
| 107 | Electrical energy storage recovery system and the electrical energy storage return method using a piston gas compressor-expander unit | JP2010529434 | 2008-10-03 | JP2011501026A | 2011-01-06 | リュエ、ジャック |
| 孔状耐火材料(11)を収容する第1被覆容器(1)と第2被覆容器(2)のそれぞれ上端と下端(1 1 ,2 1 ,1 2 ,2 2 )を繋ぐパイプ回路(1c,1d,2c,2d)に設けた第1ガス圧縮膨張機(30)と第2ガス圧縮膨張機(40)にガスを流すと、孔状耐火材料にガスが流れる。 第1ガス圧縮膨張機(30)と第2ガス圧縮膨張機(40)のピストン(30a,40a)は、シリンダ(30b,40b)にて並進移動し、圧縮モードまたは膨張モードで動作する。 一方のガス圧縮膨張機は、他方よりも高温のガスを収容する。 圧縮モードでは蓄積される電気エネルギE 1を消費する電気モータ(41)によって駆動され、熱力機関モードでは電気エネルギ(E R )の復帰を可能にする発電機(52)を駆動する。 電気エネルギは耐火物質に熱の形で蓄積され、蓄積した潜在的な熱エネルギは電気エネルギの形で復帰される。 | ||||||
| 108 | Electrical energy storage recovery system and the electrical energy storage return method | JP2010506972 | 2008-04-21 | JP2010527221A | 2010-08-05 | リュエ、ジャック |
| 電気エネルギを蓄積および復帰させるシステム。 本システムは、ガスと孔状耐火材料(11)を収容する第1容器(1)および第2容器(2)と、ガスと孔状耐火材料(11)は、孔状耐火材料と、第1容器および第2容器を流れるガスとの接触によって適切に熱を移送することと;他方の容器の一端に接続された容器の端部同士の間のパイプを流れるガスの圧縮装置(3b,4b)および膨張装置(3c,4c)とを備える。 本発明はまた、本発明のシステムが使用する熱エネルギの形で電気エネルギを蓄積する方法、および本発明の方法によって蓄積した熱エネルギを電気エネルギ(E R )に復帰させる方法に関する。 電気エネルギは、耐火材料内部の熱の形で蓄積され、蓄積された熱ポテンシャルエネルギは、電気エネルギの形で復帰される。 | ||||||
| 109 | Power generation method and apparatus using a hydrogen storage alloy | JP31561486 | 1986-12-23 | JPH0713469B2 | 1995-02-15 | 順一 坂口; 章 矢野間 |
| 110 | External heat absortion type closed-cycle engine | JP8422581 | 1981-06-01 | JPS57198304A | 1982-12-04 | KUME KORESHI; MIYAKI KIYOSHI; UCHIDA TAKANAO |
| PURPOSE:To attain a thermal efficiency approximate to that of theoretical Carnot cycle, by causing a no-phase-change working fluid to flow through a passage of uniform cross-sectional area between a compressor and a turbine and by increasing the velocity of the fluid to be slightly lower than the Mach number of 1 as extenal heat is received. CONSTITUTION:A closed circuit comprises a compressor 5, a passage 7, a turbine 6 and another passage 8. The passage 7 has a uniform cross-sectional area. A working fluid, which does not undergo phase changes, is supplied wit external heat Q1 through the wall 9 of the passage 7 so that the velocity of the fluid is increased to be slightly lower than the Mach number of 1. The fluid performs adiabatic expansion on the turbine 6. In the passage 8, heat is taken off from the fluid and transferred to the outside through the wall 11 as shown by Q2. After that, the velocity of the cooled working fluid is increased beyond the Mach number of 1 and the fluid flows into the compressor 5. Since the kinetic energy obtained by the velocity increase is recovered in the compression process and the frictional heat on the passage walls 9, 11 is recovered, a high efficienty approximate to that of theoretical Carono cycle is attained. | ||||||
| 111 | JPS5442049B2 - | JP668174 | 1974-01-14 | JPS5442049B2 | 1979-12-12 | |
| 112 | Method and apparatus for recovering waste heat of combustion | JP1202378 | 1978-02-07 | JPS5398534A | 1978-08-29 | HERUMUUTO BUUFUNERU |
| A method and apparatus for at least partially recovering the exhaust heat of combustion operations in which hydrogen is used at least partially during the combustion, which is stored in the form of metal hydride in a metal storage device and is released therefrom by a supply of heat energy. Exhaust heat of the combustion is supplied to the metal hydride for the release of the hydrogen while the metal storage device freed at least to a large extent of the hydrogen is utilized as storage device of latently bound heat energy whose heat energy is utilized, such latently bound heat energy being released during the filling of the metal storage device with hydrogen into metal hydride. | ||||||
| 113 | JPS515141B1 - | JP476772 | 1972-01-10 | JPS515141B1 | 1976-02-17 | |
| 114 | JPS49103035A - | JP668174 | 1974-01-14 | JPS49103035A | 1974-09-28 | |
| 115 | 탄소질 물질로부터의 스팀의 발생 방법 | KR1020127020211 | 2011-01-21 | KR101775608B1 | 2017-09-19 | 허슨제프리; 샤우스거스에프.; 허슨다니엘엠. |
| 스팀을발생시키는시스템및 방법은, 석탄의연속공급을제공하는단계, 상기석탄을제1 가공챔버에서산소및 물의존재하에연소시켜제1 생성물가스스트림을제공하는단계, 제1 열회수스팀발생기에서상기제1 생성물가스스트림으로부터열을회수하여제1 스팀산출물을제조하는단계, 상기제1 생성물가스스트림을제2 가공챔버에서산소및 물의존재하에가공하여제2 생성물가스스트림을제조하는단계, 제2 열회수스팀발생기에서상기제2 생성물가스스트림으로부터열을회수하여제2 스팀산출물을제조하는단계, 및상기제1 스팀산출물과상기제2 스팀산출물을합하는단계를포함한다. 바람직하게는, 상기합한스팀산출물은스팀터빈을구동시키는데사용되고, 상기터빈은발전기에결합된다. | ||||||
| 116 | 초임계 이산화탄소 발전 사이클과 연료전지가 연계된 시스템 | KR1020140127706 | 2014-09-24 | KR101603252B1 | 2016-03-15 | 김범주; 정훈; 유광명; 조종영; 김학선 |
| 본발명은초임계이산화탄소발전사이클과연료전지가연계된시스템에관한것으로, 이는수소를공급받는연료극과이산화탄소를공급받는공기극을구비하여전기화학반응에의해전기를생산하는연료전지스택, 이연료전지의배가스와공기를혼합하는이젝터, 혼합된배가스와공기를연소시키는촉매연소기, 이촉매연소기에서배출되는이산화탄소와수증기가유입되어회전되는터빈, 및이 터빈의회전에의해전기를발생시키는발전기를포함하여서, 배열을발생하는연료전지와초임계이산화탄소발전사이클을유기적으로연계시킴으로써, 배열의유효한이용을도모하고, 높은발전효율을달성할수 있는효과가있다. | ||||||
| 117 | 작동 유체의 손실 없이 부품 교체가 가능한 가정용 열병합 발전시스템 | KR1020140175289 | 2014-12-08 | KR101587253B1 | 2016-01-20 | 송영길; 조길제 |
| 본발명은가정용열병합발전시스템에관한것으로서, 더욱상세하게는작동유체의손실없이부품을교체할수 있는가정용열병합발전시스템에관한것이다. 본발명에따른가정용열병합발전시스템은작동유체가흐르는순환배관및 상기순환배관에설치되어상기작동유체를순환시키는순환펌프와, 상기순환배관에흐르는상기작동유체를가열하여고온·고압의가스상태로변환시키는보일러와, 오일에의해서윤활되며상기고온·고압의가스상태의상기작동유체의팽창력을회전력으로변환하는팽창기와, 상기팽창기를원동기로하여전기에너지를생산하는발전기와, 상기팽창기에서배출된저온·저압의가스상태의상기작동유체와열교환을하여, 저장된온수를가열하고, 저온·저압의가스상태의상기작동유체를저온·저압의액체상태로변환시키는온수통을포함하는가정용열병합발전시스템으로서, 상기보일러, 팽창기, 유분리기, 온수통, 순환펌프중 적어도하나의부품의상류측과하류측에각각차단밸브가설치되며, 한쌍의차단밸브중 어느하나의차단밸브와상기부품사이의순환배관에는유출포트가설치되며, 그부품이설치되지않은한 쌍의차단밸브의사이순환배관에는유입포트가설치되는것을특징으로한다. | ||||||
| 118 | 멤브레인 벽 가스화기 및 발전에서 전체 원유의 가스화를 위한 통합 공정 | KR1020147024166 | 2013-03-22 | KR101571259B1 | 2015-11-23 | 코서글루,오메르,리파; 발라구에,장-피에르 |
| 멤브레인벽 가스화반응기에서저가의미세하게분할된고체애쉬-생산물질과혼합된전체원유의부분산화를위한통합공정은수성-가스시프트반응에신가스를적용시켜더 많은수소-풍부생산물스트림을생산한다. 공정스팀및 전력은고온의신가스로부터현열가치를회수하여생산된다. | ||||||
| 119 | 해양구조물의 코퍼댐 히팅시스템 및 코퍼댐 히팅 방법 | KR1020140056661 | 2014-05-12 | KR1020150129531A | 2015-11-20 | 정원호; 이치운; 최현우 |
| 해양구조물의코퍼댐히팅시스템이개시된다. 본발명의해양구조물의코퍼댐히팅시스템은, 선체의길이방향으로 1열이상으로설치되는복수의 LNG 저장탱크의사이에마련되는코퍼댐; 및물 보다비등점이낮은유기냉매를작동유체로하여동작하는유기랭킨장치를포함하고, 유기냉매는코퍼댐의냉열을회수하여액체냉매로상 변환되는것을특징으로한다. | ||||||
| 120 | 열 에너지로부터 유용한 에너지를 생성하는 공정 | KR1020157005323 | 2013-07-23 | KR1020150038517A | 2015-04-08 | 코헨요아브 |
| 본발명은, 열적에너지로부터유용한에너지를생성하는공정에관한것이다. 수행채널(1-2-3-3'-4-1)의단일방향성흐름폐쇄회로에제한된이동입자들의전체적인집단은, 원심력장 및중력장을제외하는보존적인또는유효한보존력장에종속된다. 상기회로는 2개의나란하지않은영역들인, 회로외부의고온환경으로부터가열을위한열적교환(Q)을가능하게하는첫 번째영역(2-3)과회로외부환경으로부터, 필요한경우냉각기에의하여, 냉각을위한열적교환(Q)을가능하게하는두 번째영역(4-1)을, 제외하고는열적으로절연된다. 상기폐쇄회로는, 이동입자들의흐름을수용하여, 에너지를유용한출력에너지로변환하도록구성된로드(3'-4)를구비하여제공된다. 상기채널 (3-3') 전에그리고채널 (1-2) 뒤에위치한단일방향성흐름의회로의 2개의부분들인, 이동입자들의고온흐름을갖는일 부분과저온흐름을갖는다른부분에서, 상기로드의흐름속도벡터는상기보존적인또는유효한보존력장에평행하거나, 평행한성분을갖고, 온도가증가하는경우, 선택된이동입자들의밀도가감소한다면, 상기보존력장의방향은상기회로부분에서냉각흐름속도벡터의것 또는냉각흐름속도벡터성분과동일하며, 온도가증가하는경우선택된이동입자들의밀도가증가한다면, 반대이다. | ||||||
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