| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | Cryogenic cooling system having open loop type short term cooling for superconducting field winding and method therefor | JP2002203357 | 2002-07-12 | JP2003125555A | 2003-04-25 | LASKARIS EVANGELOS TRIFON; ACKERMANN ROBERT A; WANG YU |
| PROBLEM TO BE SOLVED: To provide a cooling fluid system which can supply cryogenic cooling fluid to a high-temperature superconducting machine having high reliability. SOLUTION: This cooling fluid system includes a main cooling system (52 and 88) and a second cooling system (54). The second cooling system includes a storage apparatus (74), having first cryogenic cooling fluid (70) and at least one cooling joint (82), through which the first cryogenic cooling fluid flowing from the storage apparatus and second cryogenic cooling fluid flowing through the main cooling system are thermally linked with each other. A vent (84) is provided in a cryogenic coolant line (80). With such a constitution, even if the main cooling system is not in operation, the cryogenic cooling fluid can be supplied to a high-temperature superconducting machine. COPYRIGHT: (C)2003,JPO | ||||||
| 22 | Heat pump | JP24973599 | 1999-09-03 | JP2001074333A | 2001-03-23 | BOKU HARUSHIGE; YOSHIMI MANABU; SAKAMOTO RYUICHI; WATABE YUJI; YONEMOTO KAZUO |
| PROBLEM TO BE SOLVED: To simplify the constitution by omitting the process to evaporate water, in a heat pump utilizing the heat of condensation of steam. SOLUTION: A cycle system 12 is constituted by connecting a steam separator 20, a compressor 30, and a main heat exchanger 40 in this order. Inside the steam separator 20, air space 22 and steam space 23 are partitioned by a steam permeable film 21. Mixed air of ventilation exhaust and outdoor air is sent as heat source air into the steam space 23. The steam in the heat source air is permeated. Through the steam permeable film 21 and separated. The separated steam is sent to a main heat exchanger 40 after being compressed with a compressor 30. The steam from the compressor 30 condenses in the main heat exchanger 40, and the air to be heated in the use line 13 is heated with the heat of condensation at that time. COPYRIGHT: (C)2001,JPO | ||||||
| 23 | Refrigerating device | JP32587793 | 1993-11-29 | JPH06241606A | 1994-09-02 | HAAMAN HAAMOJIO BUIIGASU; ROORANDO RUISU ROORITSUCHI |
| PURPOSE: To provide an air-conditioning and refrigerating device to further effectively and efficiently utilize low temperature fluid. CONSTITUTION: This refrigerating device 10 comprises a heat-exchanger 46; a blower means 110 arranged such that air 116 and 122 are circulated between an air-conditioning space 14 and a heat-exchanger; a low temperature cooling device 13 containing combustible fuel 18 in a low temperature state; and a heating device 148. The low temperature characteristics of fuel are utilized such that a cooling cycle is effected and the combustible characteristics of fuel are utilized by a heating device such that a heating cycle is executed. An internal combustion engine 41. is associated with the refrigerating device, low temperature fuel is vaporized, and expanded in a vapor motor to drive the same, and expanded vaporized fuel operates an internal combustion engine. COPYRIGHT: (C)1994,JPO | ||||||
| 24 | JPS5445548Y2 - | JP7435478 | 1978-05-30 | JPS5445548Y2 | 1979-12-27 | |
| 25 | JPS5066859A - | JP11861674 | 1974-10-14 | JPS5066859A | 1975-06-05 | |
| 26 | 冷却液用途および直接蒸発冷却器の循環システム | JP2018519413 | 2016-10-14 | JP2018530733A | 2018-10-18 | ディネイジ,ポール エー |
| 蒸発冷却システムは、熱交換媒体であって、冷却液を受け取ってこの熱交換媒体を流れ去る供給空気を冷却するための熱交換媒体と、新たな冷却液を供給するための冷却液源と、冷却液を熱交換媒体に供給するための、冷却液源と連通した供給ラインと、熱交換媒体に供給された冷却液を収集するための戻り貯蔵器と、再循環された冷却液を新たな冷却液と共に熱交換媒体に提供するように、貯蔵器内に収集された冷却液を供給ラインに再循環させるための供給ライン内に設けられたポンプとを備える。そのポンプは、エダクターの形態であっても差し支えない。 | ||||||
| 27 | 冷凍装置 | JP2015527165 | 2014-07-07 | JPWO2015008452A1 | 2017-03-02 | 朋一郎 田村; 英俊 田口; 文紀 河野; 尭宏 松浦 |
| 冷凍装置(100)は、蒸発器などの容器(11)、圧縮機(12)、熱交換循環路(4)及び蓄熱流路(6)を備えている。熱交換循環路(4)は、熱交換器(20)を有し、熱交換器(20)を経由して冷媒液を循環させる循環路である。蓄熱流路(6)は、容器(11)に蓄熱するための蓄熱運転で使用される流路であって、容器(11)から流出した冷媒液が熱交換器(20)を経由することなく容器(11)に戻されるように構成されている。 | ||||||
| 28 | 冷凍装置 | JP2015527165 | 2014-07-07 | JP5935232B2 | 2016-06-15 | 田村 朋一郎; 田口 英俊; 河野 文紀; 松浦 尭宏 |
| 29 | 冷凍の改良 | JP2015542361 | 2013-11-19 | JP2016501357A | 2016-01-18 | アイレス,マイケル; クラーク,ヘンリー; ディアマン,マイケル |
| 低温エンジンシステム及び冷凍システムを含むシステムであり、低温エンジンシステムと冷凍システムは機械的に且つ/或いは熱的に互いに結合される。冷凍システムは低温エンジンシステムによって駆動され、且つ、低温エンジンシステムは冷凍システムの冷却を増進する。 | ||||||
| 30 | Cooling device for use in space | JP2012080055 | 2012-03-30 | JP2013208985A | 2013-10-10 | SATO TATSUYA; KANAZAWA RYOICHI |
| PROBLEM TO BE SOLVED: To provide a cooling device for use in space, which does not require high-purity water for cooling.SOLUTION: A cooling device for use in space includes a first flow path (13) to which coolant to be cooled is fed, a second flow path (14) which is thermally joined to the first flow path (13) and to which feed water is fed, and a water absorbing body (15) which is exposed to outer space when the cooling device for use in space is used in the outer space. The feed water is supplied through the second flow path (14) to the water absorbing body (15). The water absorbing body (15) includes a water absorbing member (15a) made of a water-absorbing material. | ||||||
| 31 | How to rapidly solidify the material containing water and equipment | JP2004260240 | 2004-09-07 | JP4791720B2 | 2011-10-12 | ベッキー アンドレアス; グルップ クリストフ; リヒター ゲルト; ヴァインツィエル ノルベルト; マイアー−ラクスフーバー ペーター; ビネン マンフレート; ヴェルツ ライナー; シュミット ラルフ; トーチュニッヒ レオ |
| A process and assembly solidifies substances containing water by direct evaporation of the water, and adsorption of the water vapour by an agent in a vacuum. The substance containing water and the absorption substance are reduced from ambient pressure to a pressure below 5 mbar (absolute) by a vacuum pump and the resulting gases are sucked through an absorption agent. The mass of the absorption agent represents at least half the mass of the water in the substance. The product solidifies in less than 20 seconds. | ||||||
| 32 | Evaporator and cooling device | JP2007302097 | 2007-11-21 | JP2009127914A | 2009-06-11 | OKADA KAZUTO; FUJISAWA AKIRA; TOSHIMA MASATAKE; NAKAYAMA YOSHIHIRO; IDE SATOSHI; IIZUKA KOICHIRO; SUDO KUNIHIKO; KURASHIGE KAZUTAKA; SAKURABA ICHIRO; HAYASHI DAISUKE; SHATO SHINJI; IKEUCHI MASAKI; ANDREASEN BLAZNIAK MARCIN; MADSBOLL HANS; SVARREGAARD-JENSEN CHRISTIAN |
| PROBLEM TO BE SOLVED: To lengthen the life of a compressor by providing a cooling device with an evaporator for cooling utilizing heat of evaporation when at least some of droplet-like or mist-like working fluid evaporates. SOLUTION: The evaporator 14 includes a filter 30 for separating a producing space S3 for producing droplet-like or mist-like cold water and a communicating space S4 communicating with a suction opening 22d from each other in a housing 22. The filter is placed in an inclined attitude so as to be away from the suction opening 22d as it goes toward the upper part of the housing, and the filter allows vapor evaporated from the droplet-like or mist-like cold water to permeate therethrough and captures the droplet-like or mist-like cold water. COPYRIGHT: (C)2009,JPO&INPIT | ||||||
| 33 | Method and apparatus for evaporative cooling within a microfluidic system | JP2008529183 | 2006-08-28 | JP2009506579A | 2009-02-12 | シェーラー,アクセル; マルテゾス,ジョージ; ラジャゴパル,アディチャ |
| Evaporative cooling is an effective and efficient method for rapidly removing heat from a system device. In accordance with the disclosure herein, a microfluidic Y-junction apparatus is provided which can produce low temperatures and can be integrated into microdevices. | ||||||
| 34 | Heat treating system | JP1711895 | 1995-02-03 | JPH0835755A | 1996-02-06 | RICHIYAADO EMU UEEBAA; DONARUDO SHII PURAISU; BAIRON II SHIYOOTO |
| PURPOSE: To obtain a heat treatment system for aircraft in which the capacity is enhanced without having any adverse effect on the performance of the aircraft. CONSTITUTION: A heat treatment system uses an expendable liquid which undergoes phase change to a vapor as waste heat is absorbed and also posses a high latent heat of vaporization. The vapor is expelled, carrying with it the waste heat. A vacuum source lowers the vapor pressure to lower the vaporization temperature. In one embodiment, regulated liquid flows into a heat exchanger having a pressure lowered through a vacuum system. Waste heat transmitted to the heat exchanger through a cooling liquid system boils up a liquid at a desired temperature. A flow regulator controls the rate of fluid flow from a pressurized reservoir to the heat exchanger. Cooling effect is attained when the liquid changes from liquid phase to gas phase to absorb heat from the cooling liquid during phase transition. | ||||||
| 35 | Cryogenic cooling device and cooling method thereon | JP18211092 | 1992-07-09 | JPH0626459A | 1994-02-01 | SAHO NORIHIDE; ISOKAMI HISASHI; YAMASHITA YASUO; KAWAKAMI HIROYUKI; KAMIIDE YASUO |
| PURPOSE:To reduce electric power necessary for cooling and improve the reliability of cooling system operation by cooling plural cryopumps installed at a neutral particle implanting device in a short time. CONSTITUTION:The cryopanels 26, 28 of plural cryopumps installed in a neutral particle implanting device are cooled by a small-sized helium refrigerating machine 23. Various types of valves and the small-sized helium refrigerating machine 23 are arranged so that cooling of the cryopanels 26, 28 from room temperature may be carried out by cold cooling of liquid nitrogen used to cool a thermal shield plate 32, cold cooling of the small-sized helium refrigerating machine 23, and cold cooling of liquid helium itself. | ||||||
| 36 | Refrigerator for automobile | JP4016787 | 1987-02-25 | JPS63207961A | 1988-08-29 | HIDAKA YOSHIHIRO |
| 37 | Decompression type refrigerator | JP24125484 | 1984-11-15 | JPS61119962A | 1986-06-07 | TAMURA SHINICHI |
| 38 | METHOD AND APPARATUS FOR EVAPORATIVE COOLING WITHIN MICROFLUIDIC SYSTEMS | PCT/US2006033653 | 2006-08-28 | WO2007027663A3 | 2007-06-21 | MALTEZOS GEORGE; RAJAGOPAL ADITYA; SCHERER AXEL |
| Evaporative cooling is an effective and efficient method for rapidly removing heat from a system device. In accordance with the disclosure herein, a microfluidic Y-junction apparatus is provided which can produce low temperatures and can be integrated into microdevices. | ||||||
| 39 | HEAT PUMP COMPRISING A COOLING MODE | PCT/EP2007010197 | 2007-11-23 | WO2008064832A2 | 2008-06-05 | SEDLAK HOLGER; KNIFFLER OLIVER |
| A heat pump comprising a cooling mode includes a cooling evaporator coupled to an advance flow and a backflow. The cooling evaporator is brought to a pressure such that a vaporization temperature of the working liguid in the backflow is below a temperature of an object to be cooled to which the backflow may be thermally coupled. In this manner, an area having vapor at high pressure is generated. This vapor is fed into a dynamic-type compressor which outputs the vapor at a low pressure and provides electrical energy in the process. The vapor at low pressure is fed to a cooling liquefier which provides vapor liquefaction at a low temperature, this temperature being lower than the temperature of the object to be cooled. The working liquid removed from the cooling evaporator due to the vaporization is refilled by a filling pump. The heat pump comprising a cooling mode also results when a specific heat pump is operated in the reverse direction, and provides cooling without any net use of electrical energy. Instead, the cooling even generates electrical energy. | ||||||
| 40 | 流体処理装置および流体処理装置によって気流を冷却する方法 | JP2016561580 | 2013-12-26 | JP6401291B2 | 2018-10-10 | アグラワル、アビチャル |
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