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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261 | FUEL CELL SYSTEM | EP07807776.5 | 2007-09-21 | EP2065961B1 | 2014-05-14 | YUKIMASA, Akinori; OZEKI, Masataka; OHARA, Hideo; NAKAMURA, Akinari |
262 | POWER GENERATING SYSTEM AND METHOD OF OPERATING SAME | EP11849071 | 2011-12-08 | EP2551946A4 | 2014-01-08 | INOUE ATSUTAKA; TATSUI HIROSHI; MORITA JUNJI; YASUDA SHIGEKI; YUKIMASA AKINORI |
A power generation system according to the present invention includes: a fuel cell system (101) including a fuel cell (11), a case (12), a reformer (14a), and a combustor (14b); a ventilator; a controller (102); a combustion device (103); and a discharge passage (70) formed to cause the case (12) and an exhaust port (103A) of the combustion device (103) to communicate with each other and configured to discharge an exhaust gas from the fuel cell system (101) and an exhaust gas from the combustion device (103) to the atmosphere through an opening of the discharge passage (70), the opening being open to the atmosphere, and the controller (102) is configured to cause the combustion device (103) to operate when the ventilator is in a stop state and then cause the ventilator to operate when the fuel cell system (101) is activated. | ||||||
263 | POWER GENERATION SYSTEM AND METHOD FOR OPERATING SAID SYSTEM | EP12763129.9 | 2012-02-15 | EP2675009A1 | 2013-12-18 | TATSUI, Hiroshi; MORITA, Junji; YASUDA, Shigeki; YUKIMASA, Akinori; INOUE, Atsutaka |
A power generation system according to the present invention includes: a fuel cell unit (101) including a fuel cell (11), a hydrogen generator (14) having a first combustor (14b), and a case (12); a controller (102); a combustion unit (103) including a second combustor (17); and a discharge passage (70) formed to cause the case (12) and the combustion unit (103) to communicate with each other. In a case where the controller (102) causes one of the first combustor (14b) and the second combustor (17) to perform the ignition operation, the controller (102) maintains an operating state of the other combustor during the period of the ignition operation of the one combustor. |
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264 | Combustion unit for heat generator to which an additional heat generator is connected | EP07023511.4 | 2007-12-05 | EP1936287A3 | 2013-07-10 | De Sanctis, Guido |
The present invention relates to a combustion unit (1) for a primary heat generator (GT), to which a secondary generator comprising a primary generator (GT), a burner (101), a flue gas pipe (102) for the entry of combustion products from the secondary generator, a connection pipe (103) that conveys the second heat generator combustion products to said flue gas pipe (102) and a fuel-oxidizing agent mixture supply pipe (104) for combustion in said cylindrical burner (101) is connected. The cylindrical burner (101) and the flue gas pipe (102) are coaxially arranged and one placed preferably inside the other so that the flue gases they emit go through the heat exchanger (2) starting in the same part, that is, from the bottom or the top of said heat exchanger (2). The present invention also relates to various types of heat generator (GT) using this combustion unit (1). |
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265 | POWER GENERATING SYSTEM AND METHOD OF OPERATING SAME | EP11849071.3 | 2011-12-08 | EP2551946A1 | 2013-01-30 | INOUE, Atsutaka; TATSUI, Hiroshi; MORITA, Junji; YASUDA, Shigeki; YUKIMASA, Akinori |
A power generation system according to the present invention includes: a fuel cell system (101) including a fuel cell (11), a case (12), a reformer (14a), and a combustor (14b); a ventilator; a controller (102); a combustion device (103); and a discharge passage (70) formed to cause the case (12) and an exhaust port (103A) of the combustion device (103) to communicate with each other and configured to discharge an exhaust gas from the fuel cell system (101) and an exhaust gas from the combustion device (103) to the atmosphere through an opening of the discharge passage (70), the opening being open to the atmosphere, and the controller (102) is configured to cause the combustion device (103) to operate when the ventilator is in a stop state and then cause the ventilator to operate when the fuel cell system (101) is activated. |
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266 | POWER GENERATION SYSTEM AND OPERATING METHOD THEREFOR | EP11849742 | 2011-12-09 | EP2538479A4 | 2012-12-26 | TATSUI HIROSHI; MORITA JUNJI; YASUDA SHIGEKI; YUKIMASA AKINORI; INOUE ATSUTAKA |
267 | VERFAHREN ZUM BETRIEB EINER KRAFT-WÄRME-KOPPLUNGSANLAGE | EP11700747.6 | 2011-01-17 | EP2526344A2 | 2012-11-28 | FRIEDE, Wolfgang; LIMBECK, Uwe |
The invention relates to a method for operating a cogeneration plant (10), wherein a first portion of a first fuel is electrochemically converted in at least one fuel cell (21) of a fuel cell system (20) of the cogeneration plant (10), whereby electrical power and heat are generated, wherein a second portion of the first fuel, exiting the fuel cell (21) without converting, is burned in an afterburner (24) of the fuel cell system (20) after exiting the fuel cell (21), and heat is thereby generated, wherein a second fuel can be burned in a heat generator (30) of the cogeneration plant (10) and heat can thereby be generated, wherein an optimal first portion of the first fuel can be converted at an optimal operating point of the fuel cell (21). According to the invention, when a demand for heat is greater than can be generated in the fuel cell system (20) at the optimal operating point of the fuel cell (21), the first portion of the first fuel is reduced relative to the optimal operating point, so that more heat is generated in the afterburner (24) than at the optimal operating point. | ||||||
268 | Heiz- oder Brauchwasserwärmespeicher mit mindestens zwei Wärmequellen | EP06025504.9 | 2006-12-09 | EP1798486B1 | 2012-08-29 | Langer, Jens |
269 | Co-generation unit and control method of the same | EP07106113.9 | 2007-04-13 | EP1884648B1 | 2012-07-18 | Cho, Eun Jun; Ha, Sim Bok; Kim, Cheol Min; Chang, Se Dong |
Disclosed related to a co-generation comprising a heat exchanger 130 heating water; a heat transfer path 170 connected with the water heat exchanger130 to transfer heat; a hot water storage tank 80 connected with the water heat exchanger 130 and the water circulation path 81; a hot water storage water supply apparatus 82 supplying water in the hot water storage tank 80 to the water circulation path 819 a water supply path 83 connected with the water circulation path 81; a water supply apparatus 86 supplying water to the water supply path 83; and a hot water supply heat exchanger bypassing apparatus 87 and 88 bypassing the water supplied to the water circulation path 81 from the hot water storage tank 80 through the hot water supply heat exchanger 130. The co-generation of the present invention has some advantage in that the effective water boil heat is increased as supplying the cold water supplied from the water service and the hot water supplied from the hot water storage tank to the hot water supply heat exchanger 70 properly and heat exchanging with the heat medium such as an anti freezing solution and etc passing through the hot water supply heat exchanger. | ||||||
270 | Schichtenspeicher | EP03015917.2 | 2003-07-12 | EP1398591B1 | 2012-03-14 | Noll, Wolfgang |
271 | Heizungssystem mit Brennstoffzelleneinrichtung und Verfahren zum Betreiben einer Brennstoffzelleneinrichtung | EP04009468.2 | 2004-04-22 | EP1482254B1 | 2011-11-30 | Lindner, Friedrich, Dr.; Nedele, Martin, Dr.; Brinner, Andreas |
272 | A BOILER UNIT | EP09760965.5 | 2009-11-26 | EP2364512A2 | 2011-09-14 | DEVRIENDT, James; EVANS, Christopher John; MORGAN, Robert; BARNARD, Paul; GIRVAN, Bruce |
A boiler unit (100) housed in an enclosure, the boiler unit (100) configured to receive a solid state combined heat and power generating device (130). The boiler unit (100) comprises a heating device (110) to produce heat; and a control unit (120) to independently control each of the heating device (110) and the solid state combined heat and power generating device (130). The boiler unit (100) is operable without the solid state combined heat and power generating device (130) being present. | ||||||
273 | Installation for generating heat and/or electricity in buildings | EP09155920.3 | 2009-03-23 | EP2233843A1 | 2010-09-29 | Rau, Thomas Martin |
The invention relates to an installation for generating heat and/or electricity in buildings. It comprises a water supply (3), an electricity supply (2), an oxy-hydrogen generator (1) connected to the water and electricity supply to produce oxy-hydrogen from the water, in particular by means of electrolysis. At least one convertor (4 - 7), such as a combined electricity/heat producing apparatus (4), converts the energy of the oxy-hydrogen into heat and/or electricity for use in the buildings. |
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274 | FUEL CELL SYSTEM | EP07807776 | 2007-09-21 | EP2065961A4 | 2010-09-01 | YUKIMASA AKINORI; OZEKI MASATAKA; OHARA HIDEO; NAKAMURA AKINARI |
275 | Heiz- oder Brauchwasserwärmespeicher | EP06025505.6 | 2006-12-09 | EP1798487B1 | 2010-08-18 | Langer, Jens |
276 | Heat and power system combining a solid oxide fuel cell stack and a vapor compression cycle heat pump | EP08153589.0 | 2008-03-28 | EP1983596A3 | 2009-08-05 | Kelly, Sean M.; Faville, Michael T. |
A Combined Heat and Power System ("CHPS") includes a solid oxide fuel cell system and a vapor compression cycle heat pump. The CHPS improves the overall efficiency of a CHP system with respect to conversion of fuel energy to usable heat and electrical energy without need for an accessory burner-heat exchanger system. The compressor motor of the heat pump is powered by a portion of the electricity generated by the SOFC, and the thermal output of the heat pump is increased by abstraction of heat from the SOFC exhaust. This integration allows for novel and complementary operation of each type of system, with the benefits of improved overall fuel efficiency for the improved CHP system. |
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277 | GEOTHERMAL SYSTEM | EP02749807.0 | 2002-08-01 | EP1412681B1 | 2008-10-08 | Ace, Ronald Stephen |
An excavationless geothermal system for heating and cooling applications includes a potable water storage container that receives water from a water supply through a supply line and a reversible water meter. The water in the storage container is circulated through a heat pump, and when the temperature of the water in the container is increased or decreased by the heat pump, the water is returned to the supply through the reversible meter. | ||||||
278 | Combustion unit for heat generator to which an additional heat generator is connected | EP07023511.4 | 2007-12-05 | EP1936287A2 | 2008-06-25 | De Sanctis, Guido |
The present invention relates to a combustion unit (1) for a primary heat generator (GT), to which a secondary generator comprising a primary generator (GT), a burner (101), a flue gas pipe (102) for the entry of combustion products from the secondary generator, a connection pipe (103) that conveys the second heat generator combustion products to said flue gas pipe (102) and a fuel-oxidizing agent mixture supply pipe (104) for combustion in said cylindrical burner (101) is connected. The cylindrical burner (101) and the flue gas pipe (102) are coaxially arranged and one placed preferably inside the other so that the flue gases they emit go through the heat exchanger (2) starting in the same part, that is, from the bottom or the top of said heat exchanger (2). The present invention also relates to various types of heat generator (GT) using this combustion unit (1). |
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279 | Verfahren zum Betrieben einer Kombination eines Heizgeräts mit einer Brennstoffzellenanlage | EP07004854.1 | 2007-03-09 | EP1835240A3 | 2008-06-11 | Badenhop, Thomas; Berg, Joachim; Götz, Klaus; Kohlhage,Jörg; Kraus, Matthias; Oerder, Bodo; Paulus, Jochen |
Verfahren zum Betrieben einer Kombination eines Heizgeräts (12), welches über eine Vorrichtung (16, 21, 29, 30) zur Regelung des Brennstoff-Luft-Verhältnisses verfügt, mit einer Brennstoffzellenanlage, bei dem die Brennstoffzelle (8) über eine Anode (24) und eine Kathode (25) verfügt, wobei die Kathode (25) der Brennstoffzelle (8) sauerstoffführend, vorzugsweise luftführend ist, wobei das Anodenabgas der Brennstoffzelle (8) zu einer Abgasleitung (5) gefördert wird, während zumindest ein Teil des Kathodenabgases der Brennstoffzelle (8) dem Heizgerät (12) zugeführt wird und die Menge des dem Heizgerät (12) zugeführten Oxidationsmittel in Abhängigkeit des Signals der Vorrichtung (16, 21, 29, 30) zur Regelung des Brennstoff-Luft-Verhältnisses geregelt wird. |
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280 | Heiz- oder Brauchwasserwärmespeicher | EP06025505.6 | 2006-12-09 | EP1798487A3 | 2008-05-28 | Langer, Jens |
Wärmespeicher (1) für Heiz- und / oder Brauchwasser, welcher mit einer Wärmequelle (9) und mindestens einem Wärmeverbraucher (10, 7) verbunden ist, wobei der Wärmespeicher mit einer Emulsion (PCS, 2) aus Wasser und mikroverkapseltem Paraffin gefüllt ist und der Wärmespeicher (1) mit der Wärmequelle (9) und / oder dem Wärmeverbraucher (10, 7) in jeweils einem Emulsion (PCS, 2) führenden Kreislauf verbunden ist. |