序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
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101 | Mehrstufige Einrichtung mit Arbeitsfluid- und Absorptionsmittel-Kreisläufen, und Verfahren zum Betrieb einer solchen Einrichtung | EP94101668.5 | 1982-03-24 | EP0597822B1 | 1996-06-26 | Alefeld, Georg, Prof. Dr. |
102 | Mehrstufige Einrichtung mit Arbeitsfluid- und Absorptionsmittel-Kreisläufen, und Verfahren zum Betrieb einer solchen Einrichtung | EP94101668.5 | 1982-03-24 | EP0597822A3 | 1995-02-08 | Alefeld, Georg, Prof. Dr. |
Es werden mehrstufige Einrichtungen beschrieben, die mit Absorberkreisläufen arbeiten, zur Nutzbarmachung von Wärmeenergie und/oder Arbeit verwendet werden können und sich durch einen hohen Wirkungsgrad und/oder eine hohe Anpassungsfähigkeit auszeichnen. Die Einrichtungen arbeiten mit einem Arbeitsfluid, welches in einem Absorptionsmittel absorbierbar ist und enthalten als Hauptkomponenten sogenannte Austauscheinheiten und gegebenenfalls zusätzlich auch mindestens eine Druckmaschine. Unter einer "Austauscheinheit" sollen Absorber, Kondensator, Resorber, Verdampfer, Desorber und Absorber, wie sie bei Absorber- und Resorber-Maschinen üblich sind, verstanden werden; der Begriff "Druckmaschinen" soll Kompressoren und Expansionsmaschinen umfassen. Bevorzugte Ausführungsformen der vorliegenden Einrichtung sind Wärmepumpen, die sich in weiten Bereichen an veränderliche Außentemperaturen und veränderlichen Wärmebedarf anpassen lassen. |
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103 | Wärmepumpenanordnung und Verwendung eines Kältemitteldampfmotors | EP82810011.5 | 1982-01-14 | EP0056786A1 | 1982-07-28 | Schmall, Karl-Heinz |
Anordnung mit einer Wärmepumpe (1) und einem Kältemitteldampfmotor (19), welcher einerseits die Wärmepumpe antreibt und andererseits durch einen Kältemittelverdampfer (8) gespeist wird, der durch Wärmeenergie versorgt wird, welche von der Wärmepumpe abgenommen wird. |
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104 | Method of producing thermal energy by the combination of a heat engine with a heat pump | EP79102746 | 1979-08-01 | EP0008680A3 | 1980-04-02 | Schneider, August, Dr.; König, Wolfgang, Dr.; Eder, Roman |
Die Erfindung betrifft ein Verfahren zur Erzeugung von Wärmeenergie für Heizzwecke durch Kombination der Kraft-Wärme-Kopplung mit der Wärmepumpe. Der Kompres sor der Wärmepumpe wird erfindungsgemäß von einer Gegendruck-Dampfturbine oder einem Dampfmotor direkt angetrieben. Die Wärmepumpe pumpt Wärme aus einer äußeren Wärmequelle mit niedriger Temperatur in den Heiz kreislauf, danach wird die Wärmeenergie des Gegendruck- Dampfes über Wärmetauscher ebenfalls in den Heizkreislauf überführt. Das Verfahren ist unabhängig von der Art des Brennstoffs, vorzugsweise werden geringwertige Brennstoffe eingesetzt; es ermöglicht, Wärmeenergie für Heizzwecke auf wirtschaftliche, umweltfreundliche und brennstoffsparende Weise zu erzeugen. Mit dem Verfahren erreicht man einen Gesamtwirkungsgrad, der auch unter ungünstigen Verhält nissen deutlich über 100 % liegt. Das Verfahren ist bei sehr großen Leistungen anwendbar. | ||||||
105 | KRAFT-WÄRME-KRAFTWERK UND VERFAHREN ZUM BETRIEB EINES KRAFT-WÄRME-KRAFTWERKS | EP13762806.1 | 2013-09-12 | EP2900943B1 | 2018-10-31 | REISSNER, Florian; SCHÄFER, Jochen |
106 | HEAT RECOVERY AND UPGRADING METHOD AND COMPRESSOR FOR USING IN SAID METHOD | EP14739975.2 | 2014-07-01 | EP3033498B1 | 2018-04-04 | VAN BEVEREN, Petrus Carolus |
Method for coupling a first heat-requiring industrial process to a second cold-requiring industrial process, whereby a first circuit for energy recovery (1) from the first industrial process transfers heat to a second circuit for cold production (2) for the second industrial process, wherein the first circuit for energy recovery (1) the energy carrier is a binary mixture of water and ammonia that has two-phases and is compressed by a compressor (7) specifically suitable for compressing a two-phase fluid such as a compressor with a Lysholm rotor or equipped with vanes, whereby all or part of the liquid phase evaporates as a result of compression such that overheating does not occur and such that less working energy must be supplied. | ||||||
107 | DEVICE FOR ENERGY SAVING | EP14755126.1 | 2014-07-01 | EP3019717B1 | 2017-09-13 | VAN BEVEREN, Petrus, Carolus |
108 | Latent heat recovery generator system | EP10172223.9 | 2010-08-06 | EP2348197A3 | 2016-06-29 | Lee, Cheng-Chun; Kao, Hung-Yuan; Lee, Cheng-Chu |
A heat recovery generator system (1) includes a boiler (11) converting water into high-pressure steam that passes through a steam pipe (12), a turbine (13), a first pipe (10), a condenser (15), and a second pipe (102) in sequence. The steam condenses into water after passing through the condenser (15). The condensed water passes through a water pump (16), a water supply pipe (17), and a heater (18) to the boiler (11). A latent heat recovery device (2) includes a compressor (21) that outputs a coolant moving along a coolant pipe (22) passing in sequence through a first heat exchanger device (23) and a second heat exchanger device (25) and then returning to the compressor (21). A third pipe (103) branches from the first pipe (101) and is connected to a fourth pipe (104) via the second heat exchanger device (25). The coolant absorbs heat from the steam via the second heat exchanger device (25). Heat recovery water absorbs the heat released from the coolant through the first heat exchanger device (23). |
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109 | WATER PRESSURE SYSTEM OF STEAM PLANT | EP13763490 | 2013-03-12 | EP2816197A4 | 2015-11-11 | YOSHIDA FUTOSHI; MIYAKAWA SHIMPEI |
110 | DISPOSITIF DE PRODUCTION D'ÉLECTRICITÉ AVEC PLUSIEURS POMPES À CHALEUR EN SÉRIE | EP09805750.8 | 2009-12-18 | EP2379848B1 | 2014-11-26 | SARDO, Alberto |
111 | KRAFTWERK ZUR K LTEERZEUGUNG | EP03720193.6 | 2003-03-17 | EP1488080A1 | 2004-12-22 | STUHLMÜLLER, Franz |
The invention relates to a power station (1) comprising at least one steam turbine (5) and/or gas turbine (52) which is connected to at least one absorption type refrigeration machine (10) in order to produce refrigeration, whereby the absorption type refrigeration machine (10) is operated by means of steam (12) which is taken from the steam turbine (5), or by means of waste heat (AH,AH') produced by the gas turbine (52). | ||||||
112 | Mehrstufige Einrichtung mit Arbeitsfluid- und Absorptionsmittel-Kreisläufen, und Verfahren zum Betrieb einer solchen Einrichtung | EP82102473.4 | 1982-03-24 | EP0061721B1 | 1994-08-10 | Alefeld, Georg, Prof. Dr. |
113 | SYSTEM FOR CONVERTING HEAT ENERGY, PARTICULARLY FOR UTILIZING HEAT ENERGY OF THE ENVIRONMENT | EP85900168.0 | 1984-12-21 | EP0165962A1 | 1986-01-02 | LIPOVETZ, Ivan; GYÖRGYFALVAY, Peter; RIHMER, Oszkar; WILLINGER, Johann |
Système pour convertir l'énergie thermique d'une source d'une capacité pratiquement illimitée, en particulier pour utiliser l'énergie thermique de l'environnement, comportant un circuit fermé de pompe thermique connecté à un mécanisme d'actionnement (3) conçu pour les amorcer, le circuit de pompe thermique comportant un mécanisme d'évaporation (1) recevant l'énergie thermique d'un milieu extérieur pour convertir un liquide en vapeur, un mécanisme de compression (2) pour accroître la pression de la vapeur et un mécanisme de condensation (4) pour restituer le liquide à partir de la vapeur comprimée, le système étant doté d'un terminal de sortie énergétique. La caractéristique du présent système est de comporter un circuit d'entraînement fermé en contact thermique avec le mécanisme de condensation (4), ce qui produit une vapeur surchauffée pour amorcer le mécanisme d'actionnement (3), le circuit d'entraînement comportant un mécanisme pour condenser la vapeur surchauffée quittant la sortie du mécanisme d'actionnement (3) et un mécanisme de transport (6) pour amener le liquide au mécanisme de condensation (4). Le présent système est capable d'utiliser l'énergie thermique de l'environnement sans autre apport de la part d'une source d'énergie extérieure basée sur un réseau électrique ou un combustible fossile. | ||||||
114 | Power generation-refrigeration system and method of operating the same | EP79103686.6 | 1979-09-28 | EP0010210B1 | 1982-06-23 | Leonard, Louis H. |
115 | SYSTEM FOR PRODUCING HEAT SOURCE FOR HEATING OR ELECTRICITY USING MEDIUM/LOW TEMPERATURE WASTE HEAT AND METHOD FOR CONTROLLING SAME | EP14801158 | 2014-05-20 | EP3001112A4 | 2017-03-29 | KANG MIN CHEOL; LEE HYO SEOK; SEONG JONG KOOK |
A system for producing a heat source for heating or electricity, using medium/low-temperature waste heat includes: an absorption-type heat pump (100) supplied with a driving heat source and heat source water to heat a low-temperature heat medium; a regenerator heat exchange unit (210) for supplying a regenerator (110) with a driving heat source using waste heat; an evaporator heat exchange unit (220) for supplying an evaporator with heat source water; a heat medium circulation line (310) for circulating a heat medium; a generation unit (400) branching off from the heat medium circulation line (310) and producing electricity; a heat production unit (500) branching off from the heat medium circulation line (310) and supplying a heat-demanding place with a heat source for heating; and a switching valve unit (600) for controlling the flow of heat medium supplied the generation unit (400) or the heat production unit (500). | ||||||
116 | HEAT RECOVERY AND UPGRADING METHOD AND COMPRESSOR FOR USING IN SAID METHOD | EP14739975.2 | 2014-07-01 | EP3033498A1 | 2016-06-22 | VAN BEVEREN, Petrus Carolus |
Method for coupling a first heat-requiring industrial process to a second cold-requiring industrial process, whereby a first circuit for energy recovery (1) from the first industrial process transfers heat to a second circuit for cold production (2) for the second industrial process, wherein the first circuit for energy recovery (1) the energy carrier is a binary mixture of water and ammonia that has two-phases and is compressed by a compressor (7) specifically suitable for compressing a two-phase fluid such as a compressor with a Lysholm rotor or equipped with vanes, whereby all or part of the liquid phase evaporates as a result of compression such that overheating does not occur and such that less working energy must be supplied. | ||||||
117 | SYSTEM FOR PRODUCING HEAT SOURCE FOR HEATING OR ELECTRICITY USING MEDIUM/LOW TEMPERATURE WASTE HEAT AND METHOD FOR CONTROLLING SAME | EP14801158.8 | 2014-05-20 | EP3001112A1 | 2016-03-30 | KANG, Min Cheol; LEE, Hyo Seok; SEONG, Jong Kook |
A system for producing a heat source for heating or electricity, using medium/low-temperature waste heat includes: an absorption-type heat pump (100) supplied with a driving heat source and heat source water to heat a low-temperature heat medium; a regenerator heat exchange unit (210) for supplying a regenerator (110) with a driving heat source using waste heat; an evaporator heat exchange unit (220) for supplying an evaporator with heat source water; a heat medium circulation line (310) for circulating a heat medium; a generation unit (400) branching off from the heat medium circulation line (310) and producing electricity; a heat production unit (500) branching off from the heat medium circulation line (310) and supplying a heat-demanding place with a heat source for heating; and a switching valve unit (600) for controlling the flow of heat medium supplied the generation unit (400) or the heat production unit (500). |
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118 | WATER PRESSURE SYSTEM OF STEAM PLANT | EP13763490.3 | 2013-03-12 | EP2816197A1 | 2014-12-24 | YOSHIDA, Futoshi; MIYAKAWA, Shimpei |
A water hydraulic system (100) includes a steam generator (4) for evaporating water and generating steam, a steam turbine (3) to be rotated by the steam generated in the steam generator (4), for generating motive power, and a steam condenser (5) for returning the steam passing through the steam turbine (3) to a water feed passage (6) as condensate. The water hydraulic system (100) includes a water hydraulic pump (9) to be driven by rotation of the steam turbine (3), for suctioning the condensate returned from the steam condenser (5) through a suction passage (8) and discharging the condensate, a water-hydraulically driven actuator (11) to be actuated by the pressurized water discharged from the water hydraulic pump (9), for driving an auxiliary machine, and a heat pump (20) for moving heat of the water flowing through the suction passage (8) to the water flowing through the water feed passage (6). |
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119 | DISPOSITIF DE PRODUCTION D'ÉLECTRICITÉ AVEC PLUSIEURS POMPES À CHALEUR EN SÉRIE | EP09805750.8 | 2009-12-18 | EP2379848A2 | 2011-10-26 | SARDO, Alberto |
The invention relates to an electricity generation device (1) which includes: - a first heat pump (3) provided with a first closed circuit (15) containing a first heat transfer fluid, and a first heat exchanger (17) between the first heat transfer fluid and a flow of atmospheric air, in which the flow of atmospheric air transfers an amount of heat to the first heat transfer fluid, - at least one second heat pump (5) provided with a second closed circuit (23) containing a second heat transfer fluid, and a second heat exchanger (25) between the second heat transfer fluid and a third heat transfer fluid, in which the second heat transfer fluid transfers an amount of heat to the third heat transfer fluid; - means for transferring an amount of heat from the first heat transfer fluid to the second heat transfer fluid; - a third closed circuit (9) containing the third heat transfer fluid; - a turbine (11) inserted in the third closed circuit (9) and driven by the third heat transfer fluid; - an electricity generator (13) mechanically driven by the turbine (11). | ||||||
120 | Latent heat recovery generator system | EP10172223.9 | 2010-08-06 | EP2348197A2 | 2011-07-27 | Lee, Cheng-Chun; Kao, Hung-Yuan; Lee, Cheng-Chu |
A heat recovery generator system (1) includes a boiler (11) converting water into high-pressure steam that passes through a steam pipe (12), a turbine (13), a first pipe (10), a condenser (15), and a second pipe (102) in sequence. The steam condenses into water after passing through the condenser (15). The condensed water passes through a water pump (16), a water supply pipe (17), and a heater (18) to the boiler (11). A latent heat recovery device (2) includes a compressor (21) that outputs a coolant moving along a coolant pipe (22) passing in sequence through a first heat exchanger device (23) and a second heat exchanger device (25) and then returning to the compressor (21). A third pipe (103) branches from the first pipe (101) and is connected to a fourth pipe (104) via the second heat exchanger device (25). The coolant absorbs heat from the steam via the second heat exchanger device (25). Heat recovery water absorbs the heat released from the coolant through the first heat exchanger device (23). |