| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 61 | 기계적 에너지에 의해 저온의 열에너지를 비교적 고온의 열에너지로 변환하기 위한 방법 및 그와 반대로 변환하기 위한 방법 | KR1020107002494 | 2008-07-21 | KR101539790B1 | 2015-07-28 | 아들러,베른하드 |
| 밀폐된열역학적순환과정을통과하는작동매체를이용하여기계적에너지에의해저온의열에너지를비교적고온의열에너지로변환하기위한방법및 그와반대로변환하기위한방법, 상기순환과정은 -작동매체의가역단열압축단계 -작동매체로부터나온열의등압전도단계 -작동매체의가역단열이완단계 -작동매체로열의등압공급단계를포함하는방법에있어서, 상기작동매체에작용되는원심력을증가또는감소시킴으로써상기작동매체의압력의증가또는감소가압축또는이완동안생성되고, 결과적으로작동매체의유동에너지가실질적으로압축또는이완과정동안유지된다. | ||||||
| 62 | 열을 이송하기 위한 방법 및 장치 | KR1020107025580 | 2009-04-14 | KR1020110014152A | 2011-02-10 | 스쿰스불드오게 |
| 본 발명의 목적은 원심 가압된 유체 의해 회전축에 있는 출구로부터 열, 냉기 및 압력을 발생시키기 위한 회전 장치(107)를 제공하는 것으로, 이러한 장치는 적어도 두 개의 하부-지지된 U 채널 구조체(107)를 포함하고, 외주(107)를 향한 각각의 U 채널 구조체(107)로부터의 채널들(104, 105) 중 하나는 열적으로 접촉하여 열 교환기(106)를 형성하고, 채널 중 하나(105)는 압축성 냉각 유체를 포함하고, 이 냉각 유체는 채널(105) 내에서 원심 압축으로부터 열을 발생시키며, 이 열은 외주(107)를 향한 열 교환기(106) 내의 제2 채널(104) 내의 더 낮은 온도를 갖는 가열 유체로 전달되고, 외주에서 열 교환기가 중단되며, U 채널(107)은 외주(107)를 통해 U 채널104, 105, 108, 109)을 통한 상기 유체의 이송을 위해 회전축에 입구 채널(101, 102) 및 출구 채널(111, 112)에 연결되며, 가열 유� �를 위한 출구(111) 이후 열이 활용되고, 냉각 유체(112)는 냉기가 활용되며, 출구(111) 이전에 가열 유체는 열 교환기(106)로부터 받은 열에 의해 가압되고, 냉각 유체는 열 교환기(106) 내에서 방출되는 열을 보상하기 위해 입구(102) 이전에 적응된 순환 가압에 의해 압축되고, 가열 유체의 팽창 작동은 냉각 유체의 압축 작동에 공급되는 에너지를 감소시키고, U 채널 구조체는 적절한 수단에 의해 회전되며, U 채널은 반경방향으로 배열되고, 회전축을 중심으로 균형화되어 있다.
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| 63 | 기계적 에너지에 의해 저온의 열에너지를 비교적 고온의 열에너지로 변환하기 위한 방법 및 그와 반대로 변환하기 위한 방법 | KR1020107002494 | 2008-07-21 | KR1020100051060A | 2010-05-14 | 아들러,베른하드 |
| 밀폐된열역학적순환과정을통과하는작동매체를이용하여기계적에너지에의해저온의열에너지를비교적고온의열에너지로변환하기위한방법및 그와반대로변환하기위한방법, 상기순환과정은 -작동매체의가역단열압축단계 -작동매체로부터나온열의등압전도단계 -작동매체의가역단열이완단계 -작동매체로열의등압공급단계를포함하는방법에있어서, 상기작동매체에작용되는원심력을증가또는감소시킴으로써상기작동매체의압력의증가또는감소가압축또는이완동안생성되고, 결과적으로작동매체의유동에너지가실질적으로압축또는이완과정동안유지된다. | ||||||
| 64 | SCREW COMPRESSOR ECONOMIZER PLENUM FOR PULSATION REDUCTION | EP16753798.4 | 2016-08-11 | EP3334937A1 | 2018-06-20 | VAIDYA, Amit; ROCKWELL, David M.; PILESKI, Peter J. |
| A compressor (22) has a male rotor (52), a female rotor (54), and a housing (50). The housing has a first bore (114) and a second bore (116) respectively accommodating portions of the male rotor and the female rotor. The housing has an inlet (26), an outlet (28), an economizer port (150) along at least one of the first bore and the second bore, and an external port (46) communicating with the economizer port. The housing has a chamber (152) between the economizer port and the external port having a volume of at least 0.8 liter. | ||||||
| 65 | A PROCESS AND AN APPARATUS FOR TRANSFERRING HEAT | EP16170472.1 | 2016-05-19 | EP3246638A1 | 2017-11-22 | HOOS, Frank |
A process of transferring heat from a first medium to a second medium is provided. The process comprises: An apparatus associated with the process is also provided.
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| 66 | VERFAHREN ZUM UMWANDELN THERMISCHER ENERGIE NIEDRIGER TEMPERATUR IN THERMISCHE ENERGIE HÖHERER TEMPERATUR MITTELS MECHANISCHER ENERGIE UND UMGEKEHRT | EP08782795.2 | 2008-07-21 | EP2183529B1 | 2017-05-24 | Adler, Bernhard |
| 67 | VORRICHTUNG ZUM UMWANDELN THERMISCHER ENERGIE | EP15705481.8 | 2015-01-08 | EP3092447A1 | 2016-11-16 | ADLER, Bernhard; RIEPL, Sebastian |
| The invention relates to a device (20) for converting thermal energy of a low temperature into thermal energy of a high temperature by means of mechanical energy, and vice versa, comprising a rotor (21) which is mounted so as to rotate about a rotational axis (22) and in which a flow channel is provided for a working medium that circulates in a closed circuit process, said medium being conducted outwards, relative to the rotational axis, in a compression unit (23) in order to increase pressure, and being conducted inwards, relative to the rotational axis (22), in an expansion unit (24) in order to reduce pressure. At least one heat exchanger (1") that is positioned inwardly relative to the rotational axis and at least one heat exchanger (1') that is positioned outwardly relative to the rotational axis are provided for exchanging heat between said working medium and a heat exchange medium, said heat exchangers (1'; 1") preferably being arranged substantially parallel to the rotational axis of the rotor (21), and said rotor (21) comprising a support element (51) which supports said inner (1") and/or outer heat exchanger (1') along the length such that said inner (1") and/or outer heat exchanger (1') is retained. | ||||||
| 68 | PROCESS AND APPARATUS FOR TRANSFERRING HEAT FROM A FIRST MEDIUM TO A SECOND MEDIUM | EP08708958.7 | 2008-02-13 | EP2118585B9 | 2012-01-18 | HOOS, Frank |
| A process of transferring heat from a first relatively cold medium to a second relatively hot medium features rotating a contained amount of a compressible fluid about an axis of rotation, thus generating a radial temperature gradient in the fluid, and heating the second medium by the fluid in a section of the fluid relatively far from the axis of rotation. An apparatus for carrying out the process includes a gastight drum rotatably mounted in a frame, and a first heat exchanger mounted inside the drum relatively far from the axis of rotation of the drum. | ||||||
| 69 | PROCESS AND APPARATUS FOR TRANSFERRING HEAT FROM A FIRST MEDIUM TO A SECOND MEDIUM | EP08716835.7 | 2008-02-13 | EP2118586A1 | 2009-11-18 | HOOS, Frank |
| The invention relates to a process of transferring heat from a first relatively cold medium (23) to a second relatively hot medium (22), comprising the steps of rotating a contained amount (6) of a compressible fluid about an axis of rotation, thus generating a radial temperature gradient in the fluid, and heating the second medium (22) by means of the fluid in a section of the fluid relatively far from the axis of rotation. The invention also pertains to an apparatus for carrying said process. | ||||||
| 70 | ROTATING HEAT PUMP | EP96923107.5 | 1996-07-12 | EP0838011B1 | 2000-01-19 | HAGA, Johan |
| A heat pump with a closed cooling medium circuit for transport of heat from one air flow to another, comprises an evaporator (27) provided in one air flow for evaporation of a cooling medium, a compressor for compression of the vaporiform cooling medium, a condenser (28) provided in the other air flow for condensation of the cooling medium, and a return system for condensed cooling medium from the condenser (28) to the evaporator (27). The evaporator (27), the compressor and the condenser (28) are located in a fan casing (32) and arranged to rotate about a common shaft (1), with the compressor in the middle. The compressor works according to the liquid ring principle and comprises a rotating compressor housing (17), an intermediate shaft (2) mounted eccentrically on the outside of the shaft and one or more free-running impellers (3A, 3B), thus causing the compressor housing (17) to transfer rotary energy to the impellers via the liquid ring during operation. The evaporator (27) and/or the condenser (28) each comprises an outer housing which is equipped with surfaces which project into the air flow, with the result that the evaporator (27) and/or the condenser (28) act as fans. | ||||||
| 71 | ROTATING HEAT PUMP | EP96923107.0 | 1996-07-12 | EP0838011A1 | 1998-04-29 | HAGA, Johan |
| A heat pump with a closed cooling medium circuit for transport of heat from one air flow to another, comprises an evaporator (27) provided in one air flow for evaporation of a cooling medium, a compressor for compression of the vaporiform cooling medium, a condenser (28) provided in the other air flow for condensation of the cooling medium, and a return system for condensed cooling medium from the condenser (28) to the evaporator (27). The evaporator (27), the compressor and the condenser (28) are located in a fan casing (32) and arranged to rotate about a common shaft (1), with the compressor in the middle. The compressor works according to the liquid ring principle and comprises a rotating compressor housing (17), an intermediate shaft (2) mounted eccentrically on the outside of the shaft and one or more free-running impellers (3A, 3B), thus causing the compressor housing (17) to transfer rotary energy to the impellers via the liquid ring during operation. The evaporator (27) and/or the condenser (28) each comprises an outer housing which is equipped with surfaces which project into the air flow, with the result that the evaporator (27) and/or the condenser (28) act as fans. | ||||||
| 72 | HEAT PIPE WITH IMPROVED ENERGY TRANSFER | EP96909262.0 | 1996-04-04 | EP0819237A1 | 1998-01-21 | RIFFAT, Saffa, Bashir |
| Energy transfer apparatus comprising a pipe defining first and second heat transfer regions. A heat transfer fluid is provided to circulate about the pipe to transfer heat from the first region to the second region. Energy transfer means is arranged between the first and second regions. The energy transfer means is operable by circulation of the fluid to transfer energy to or from the apparatus. | ||||||
| 73 | HEATING OR COOLING APPARATUS | EP91905780.2 | 1991-03-11 | EP0519966B1 | 1994-08-03 | HANSEN, Laurits |
| A heating or cooling apparatus includes a heat pump comprising a compressor (58), a radiator portion (68), an expansion valve (74) and a cooling portion (76), the heat pump being constructed in the form of a substantially flat, rotatable wheel (32) wherein the cooling portion (76) forms a radially inner portion (42) of the wheel and the radiator portion (68) forms a radially outer portion (44) of the wheel, the wheel having a plurality of fins (46, 48) which, when the wheel rotates, drive streams of air over the cooling portion (76) and the radiator portion (68), and a housing (2) enclosing the wheel (32) and having means for separating the streams of air and directing them in desired directions. | ||||||
| 74 | Centrifugal heat pump | EP84301402.8 | 1984-03-02 | EP0119777B1 | 1988-11-23 | Cross, William Telford; Ramshaw, Colin |
| 75 | Centrifugal heat pump | EP84301402.8 | 1984-03-02 | EP0119777A2 | 1984-09-26 | Cross, William Telford; Ramshaw, Colin |
A vapour compression heat pump is described which comprises an evaporator, a compressor and a condenser and in which at least the evaporator or the condenser is in the form of one or more rotatable plates across the thickness of which plate(s) a heat transfer takes place. Such a heat pump can be designed in compact form. |
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| 76 | Procédé de conversion de l'énergie et dispositif pour sa mise en oeuvre | EP78400133.1 | 1978-10-11 | EP0001732B1 | 1982-10-27 | Bailly du Bois, Bernard |
| 77 | TURBO-COMPRESSOR-CONDENSER-EXPANDER | PCT/US2010021631 | 2010-01-21 | WO2010090866A3 | 2011-02-17 | ROISIN BENOIT; GEFFKEN ANDREW S; GRAVES IAN E |
| This invention provides an isothermal turbocompressor and a combined turbo- compressor-condenser-expander arrangement, which includes heat-transferring blades that are mounted on, or surround, individual conduits to promote air exchange and heat transfer. In operation, the open framework rotates in free air to promote heat exchange. This optimizes contact with free air during rotation. The assembly includes a first plurality of spokes extending radially outwardly from a first central hub to an outer perimeter with first radial conduits that transport refrigerant under centrifugal force and compression from the hub to the outer perimeter. The first radial conduits include heat exchanging blades. A second plurality of spokes extend radially outwardly from a second central hub at an axial spacing from the first central hub. This second plurality of spokes each includes a second thermally-insulated conduit that transports refrigerant from the outer perimeter to the second central hub. Axial conduits extend axially at the outer perimeter, and each interconnects each first radial conduit and each second radial conduit. At least some of the plurality of axial conduits include an axial blade in thermal communication with the conduit that promotes heat exchange radially. A motor rotates a central axis of the turbo-compressor-condenser- expander. | ||||||
| 78 | AIR-CONDITIONER WITH CONDENSER/EVAPORATOR HOUSED IN FANS | PCT/KR9900378 | 1999-07-16 | WO0004327B1 | 2000-08-24 | AHN JON |
| A compact air-conditioner including an evaporator (4) disposed in a blower fan (1) and a condenser (3) disposed in a cooling fan (2). The blades of the blower fan create and cool an air flow simultaneously. The blades of the cooling fan create and heat an air flow simultaneously. A rotating shaft (6) rigidly connects the blower fan with the cooling fan. An electrically powered compressor is disposed on the rotating shaft between the blower fan and the cooling fan so that the whole compressor rotates at the same speed as the blower fan and the cooling fan rotate. A control unit (9) supplies electric power to the compressor through a slip ring (7) being disposed on the rotating shaft. An electric motor is used to drive the rotating shaft. | ||||||
| 79 | DEVICE AND METHOD FOR THE CONDITIONING OF AMBIENT AIR | PCT/EP2014000353 | 2014-02-10 | WO2014121949A3 | 2014-12-18 | MALINDRETOS LARS |
| The invention relates to a method for changing a working fluid from one state of aggregation into another. It is sought in particular to reduce the energy consumption. For this purpose, it is provided according to the invention that, in a hollow body (1) in which pressure energy can be built up, the working fluid, proceeding from a gaseous state, is set in rotation such that the working fluid is subjected to forces that cause a compression in the working fluid, whereby the working fluid is at least partially liquefied. The invention also relates to a device and an object. | ||||||
| 80 | AIR-CONDITIONER WITH CONDENSER/EVAPORATOR HOUSED IN FANS | PCT/KR9900378 | 1999-07-16 | WO0004327A3 | 2000-06-22 | AHN JON |
| A compact air-conditioner including an evaporator (4) disposed in a blower fan (1) and a condenser (3) disposed in a cooling fan (2). The blades of the blower fan create and cool an air flow simultaneously. The blades of the cooling fan create and heat an air flow simultaneously. A rotating shaft (6) rigidly connects the blower fan with the cooling fan. An electrically powered compressor is disposed on the rotating shaft between the blower fan and the cooling fan so that the whole compressor rotates at the same speed as the blower fan and the cooling fan rotate. A control unit (9) supplies electric power to the compressor through a slip ring (7) being disposed on the rotating shaft. An electric motor is used to drive the rotating shaft. | ||||||
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