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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181 | Wassererwärmungssystem | EP09004634.3 | 2009-03-31 | EP2108896A3 | 2014-08-06 | Farinha, José Pedro Oliveira Lima |
Die Erfindung betrifft ein Wassererwärmungssystem nach dem Durchlaufprinzip, umfassend einen brennstoffbeheizten Wassererwärmer mit einem Brenner, einer Brennstoffzuführleitung, einem Brennstoffdosierventil, einem Wärmeübertrager, einer Kaltwasserzulaufleitung, einer Warmwasserauslaufleitung und einem Wasserschalter zur Erkennung eines Wasserdurchflusses durch den Wassererwärmer, des Weiteren umfassend mindestens eine Zapfstelle zum Zapfen von Warmwasser sowie Rohrleitungen zur hydraulischen Verbindung von Warmwasserauslaufleitung und Zapfstelle. Das erfindungsgemäße Wassererwärmungssystem ist dadurch gekennzeichnet, dass der Wassererwärmer eine Erkennungsvorrichtung zur Erkennung von Betriebszuständen und/oder Werten von Betriebsparametern des Wassererwärmers aufweist, und dass an oder in der Nähe der Zapfstelle eine Anzeigevorrichtung zur Anzeige der erkannten Betriebszustände und/oder Werte von Betriebsparametern des Wassererwärmers angeordnet ist. Mit dieser Anzeigevorrichtung erhält der Nutzer eine Information über den Betrieb des Wassererwärmers und kann seine Warmwasserzapfung dieser Information entsprechend anpassen. |
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182 | SMALL-SCALE COMBINED HEAT AND POWER SYSTEM AND METHOD FOR CONTROLLING SAME | EP11786824 | 2011-04-22 | EP2578951A4 | 2014-04-09 | MIN TAE SIK |
183 | DOMESTIC COMBINED HEAT AND POWER SYSTEM | EP11850132.9 | 2011-07-19 | EP2657618A1 | 2013-10-30 | PARK, Chang Kwon |
The present invention relates to a domestic combined heat and power system, and the domestic combined heat and power system includes a power unit, a heat-storage tank which receives waste heat of the power unit and stores heat in direct water, and a main heat exchanger which is connected to the heat-storage tank and is heated by a burner so as to use the water as hot water or heating water, in which a waste-heat heat exchanger filled with a heat-transfer medium is installed between the power unit and the heat-storage tank such that a waste-heat pipe of the power unit is arranged in the form of a coil at one side inside the waste-heat heat exchanger, and a heat-storage pipe of the heat-storage tank is arranged in the form of a coil at the other side, so that waste heat of the power unit is indirectly heat exchanged to the heat-storage tank through the heat-transfer medium; in which hot-water piping coming out from the heat-storage tank is arranged so as to be indirectly heat exchanged via a hot-water heat exchanger, and heating piping coming out from the heat-storage tank is connected to the heating water-heat exchanger, and a part of the heating piping again comes out and is arranged so as to be indirectly heat exchanged via the hot-water heat exchanger. According to the present invention, since a heat-exchange method for the power unit and the heat-storage tank is changed into an indirect heat-exchange method, costs and waste of energy consumption are reduced, and there is sharing of functions that are duplicated across the heat-storage tank and a boiler such that efficient system design is possible, variability and compatibility are enhanced, and the system volume is reduced such that installation space may be more effectively used. |
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184 | Wassererhitzer | EP07009884.3 | 2007-05-18 | EP1865272B1 | 2013-09-18 | Vegter, Derk |
185 | 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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186 | SMALL-SCALE COMBINED HEAT AND POWER SYSTEM AND METHOD FOR CONTROLLING SAME | EP11786824.0 | 2011-04-22 | EP2578951A2 | 2013-04-10 | MIN, Tae Sik |
Provided is a small-scale combined heat and power (CHP) system which is capable of using existing equipment to achieve a cooling function that maintains a temperature of a heat medium stored in a heat-medium storage tank and introduced into a waste-heat recovery heat exchanger of a CHP generator at a suitable temperature range for waste-heat recovery so as to enable the CHP generator to continuously operate and smoothly supply power without being shout down, and a method for controlling the same. The small-scale CHP system includes a CHP generator (100) comprising a waste-heat recovery heat exchanger (110) recovering waste heat generated during generation of electricity, a boiler (200) comprising a main heat exchanger (210) through which a heat medium supplied from the waste-heat recovery heat exchanger (110) passes and a combustion fan (230) supplying air toward a burner (220) for supplying combustion heat into the main heat exchanger (210), and a heat-medium storage tank (300) storing the circulated heat medium, the heat-medium storage tank (300) supplying the stored heat medium into the waste heat recovery heat exchanger (110) of the CHP generator (100). The heat-medium storage tank (300) includes a temperature-sensing unit (530) measuring the temperature of the heat medium stored in the heat-medium storage tank, and a control unit (600) controlling the combustion fan (230) to rotate and supply air into the heat medium passing through the main heat exchanger (210) when the temperature of the heat medium measured by the temperature-sensing unit (530) is greater than a first set temperature in a case where a heating and hot water load does not exist. |
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187 | KOPPLUNGSSYSTEM FÜR EINE HYBRIDENERGIEANLAGE | EP11713824.8 | 2011-04-12 | EP2564036A2 | 2013-03-06 | MUNZ, Cornelius; LAQUA, Ekkehard |
A coupling system for a hybrid energy plant including a heat-pump unit and a combined heat and power generation unit, having at least one coupling device for coupling the heat-pump unit and the combined heat and power generation unit. A device and a method provide a coupling for a heat-pump unit and a combined heat and power generation unit, in doing which, the highest possible overall efficiency and the lowest possible consumption of resources relative to already known uncoupled plants is ensured. At least one coupling device has an electrical coupling unit and/or a hydraulic coupling unit which are designed to be switchable for a coupling of the heat-pump unit and the combined heat and power generation unit. An energy-transformation system for generating heat and/or cold and a method for energy transformation having a coupling system are also provided. | ||||||
188 | Gebäudetechnische Anlage zum Heizen und/oder Kühlen | EP12178861.6 | 2012-08-01 | EP2557366A2 | 2013-02-13 | Salg, Frank; Sick, Jan-Hinrich; Spahn, Hans-Josef |
Die Erfindung betrifft eine Gebäudetechnische Anlage zum Heizen und/oder Kühlen von Gebäuden und/oder zur Warmwasserbereitung. Um den fehlerhaften Anschluss von Sensoren zu vermeiden, werden diese bereits bei der Herstellung eingebaut und konfiguriert. Die Sensoren werden durch Energie-Harvesting mit Energie versorgt und kommunizieren per Funk mit einem Steuergerät. |
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189 | STRÖMUNGSREGLER FÜR FLÜSSIGKEITEN MIT ENERGIEVERSORGUNG ÜBER DIE STRÖMUNG | EP11726043.0 | 2011-02-24 | EP2539577A2 | 2013-01-02 | Guzman, Cristobal |
The invention relates to a flow controller for fluids, having an energy supply by means of the flow of said fluid. Said flow controller consists of a supply line for the fluid and a turbine wheel which is rotationally mounted and through which the fluid flows and which drives an electric generator which charges the energy accumulator and a consumption point for the fluid. The forwarding of the liquid can be blocked by a shut-off valve which can be electrically controlled by control electronics which use at least one sensor and which can be adapted to various types of sensors and to the characteristics of the various types of consumption points and the shut-off valve, the control electronics and the sensor can be supplied with electric energy by the energy accumulator. | ||||||
190 | OPERATION METHOD FOR MICRO-COGENERATION SYSTEM | EP10820787.9 | 2010-09-08 | EP2484983A2 | 2012-08-08 | MIN, Tae-sik |
The present invention is directed to provide an operation method for a micro-cogeneration system that enables the use of heat recovered from a co-generator for both space heating and generating hot water by connecting the co-generator and a heat transfer medium channel of the boiler, thereby reducing the cost required for operating the cogeneration system, and facilitates the control of heat to be supplied in heating mode and in hot water mode. To this end, the present invention comprises: operating a co-generator (100) having a heat exchanger (110) for recovering waste heat that is produced during the power generation; performing a control operation in such a manner that a heat transfer medium supplied from the co-generator (100) is stored in a heat transfer medium reservoir tank (300) after going through a boiler (200) connected to the heat exchanger (110), and the heat transfer medium stored in the heat transfer medium reservoir tank (300) is circulated into the heat exchanger (110) of the co-generator (100); operating only the co-generator (100) when there is no heating and hot water loads; and stopping the operation of the co-generator (100) if it is determined that the temperature of the heat transfer medium inside the heat transfer medium reservoir tank (300) has reached a preset temperature. |
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191 | CONTROLLER FOR COMBINED HEAT AND POWER SYSTEM | EP10770132.8 | 2010-04-20 | EP2425108A2 | 2012-03-07 | VARIGONDA, Subbarao; PEDERSEN, Lars, M.; MIJANOVIC, Stevo; O'CALLAGHAN, Michael, G.; HALWAN, Vivek; HUZMEZAN, Mihai |
A controller for controlling a combined heat and power (CHP) system which can include one or more CHP units, can comprise a high level optimizer and one or more low level optimizers. The high level optimizer can be configured to optimize a total cost of producing heating, cooling, and electric power, by allocating total heating, cooling, and/or electric power setpoints one or more CHP unit types, based on the fuel price, CHP unit operational constraints, and/or heating, cooling, and/or electric power demand. The low level optimizer can be configured to allocate cooling, heating, and/or electric power setpoints to individual CHP units, based on the high level allocation to CHP unit types. | ||||||
192 | WATER SUPPLY SYSTEM WITH RECIRCULATION | EP10722782.9 | 2010-04-25 | EP2422021A1 | 2012-02-29 | POPPER, Shay; LITBAK, Arie; PETEL, Yaniv; GORELIC, Boris; CARMEL, Aharon; FRIEDMAN, Ram; KATZ, Moshe; LULKO, Igor |
A system for supplying hot and cold water to users in a building, the system comprising: a first mode for supplying water to users; a second mode for preparing to supply water at a desired temperature by recycling water from the hot water pipe into the cold pipe; a faucet having a mixing chamber; a hot water inlet; a cold water inlet; an outlet; and a mechanism for adapting the system to various types of users including humans and appliances | ||||||
193 | 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. | ||||||
194 | PHOTOVOLTAIKANLAGE | EP09772010.6 | 2009-07-01 | EP2304813A2 | 2011-04-06 | Die Erfindernennung liegt noch nicht vor |
A photovoltaic system (10) comprising planar photovoltaic elements (12), the top of which is hit by solar irradiation (S) such that electricity is generated that is fed into a power grid (14) and/or is supplied to a battery unit, is characterized in that a cooling coil (20) that communicates with a first heat pump via a heat pump cycle is arranged below each photovoltaic element (12). Said cooling coil (20) feeds the process heat generated during operation of the photovoltaic element (12) to the first heat pump which communicates with a first carrier medium cycle (22) containing a first carrier medium. Furthermore, a heat accumulator unit (24) containing a heat accumulating medium is arranged in the first carrier medium cycle (22), the thermal energy of the first carrier medium being transferred to the heat accumulating medium within the heat accumulator unit (24). In addition, at least one other heat consumer cycle (30) containing a second carrier medium communicates with the heat accumulator unit (24), and the thermal energy of the heat accumulating medium is transferred to the second carrier medium of the other heat consumer cycle (30) as needed. | ||||||
195 | Optimized control of an energy supplying system or an energy consuming system | EP09169930.6 | 2009-09-10 | EP2299189A1 | 2011-03-23 | De Ridder, Fedor |
The present invention relates to a fuel control system for a local energy supplying and/or an energy consuming system. The local energy system comprises at least a first controllable electrical unit outputting electrical power and generating a first heat flux within a series of time periods, a controllable fuel powered heating unit for outputting a further heat flux within the series of time periods, a controllable heat buffer for storing the heat fluxes and outputting a fourth heat flux within the series of time periods and a heat flux user thermally coupled to the heat buffer. |
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196 | Wassererhitzer | EP08017771.0 | 2008-10-10 | EP2051008A8 | 2009-06-17 | Guerreiro, João; Martins, LuÍs, Felipe, Carreto; de Sousa Vieira, Ricardo, Jorge |
Die Erfindung betrifft einen stromnetzunabhängig betriebenen Wassererhitzer mit einem Gasbrenner, mindestens einem in Abhängigkeit der Auslaufwassermenge steuerbaren Gasventil (2) sowie einer Regeleinrichtung (1), wobei eine Batterie als Spannungsversorgung und/oder eine in eine Wasserleitung integrierte, durch die Wasserströmung beim Öffnen eines Warmwasser-Auslassventils angetriebene Wasserturbine zum Erzeugen von elektrischer Spannung für Komponenten vorgesehen ist. Der Erfindung liegt daher die Aufgabe zugrunde, einen stromnetzunabhängig betriebenen Wassererhitzer insbesondere im Hinblick auf einen möglichst niedrigen Verbrauch an elektrischer Energie zu optimieren. Gekennzeichnet ist die Erfindung dadurch, dass das Gasventil (2) mit einem Piezo-Aktuator (3) versehen ist. Der Piezo-Aktuator (3) wird von der Regeleinrichtung (1) über eine Schaltung angesteuert, welche die elektrische Aktivierungsenergie für den Piezo-Aktuator(3) für das Öffnen des Gasventils (2) aus einem Speicher freigibt und welche die beim Schließen des Gasventils (2) am Piezo-Aktuator (3) frei werdende elektrische Aktivierungsenergie im Speicher aufnimmt. |
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197 | 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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198 | Vorrichtung zur elektrischen Energieversorgung von Komponenten eines Durchlaufwassererhitzers in einem Bereitschaftsbetrieb | EP05111966.7 | 2005-12-12 | EP1703224A1 | 2006-09-20 | Cardoso, Pedro; Borgmann, Franz; Martins, Luis; Fournier, Damien |
Die Erfindung betrifft eine Vorrichtung zur elektrischen Energieversorgung von Komponenten (3,4,5,6,7,8) eines gasbeheizten Durchlaufwassererhitzers (20) in einem Bereitschaftsbetrieb. Die Vorrichtung weist eine hydrodynamische Generatoreinrichtung (2) zur elektrischen Energieversorgung der Komponenten (3,4,5,6,7,8) in einem operativen Betrieb des Durchlaufwassererhitzers (20) sowie eine Energiespeichereinrichtung (9) auf, die zur elektrischen Energieversorgung eines Teils der Komponenten (3,4,5,6,7,8) in einem Bereitschaftsbetrieb des Durchlaufwassererhitzers (20) vorgesehen ist. |
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199 | Verfahren zum Erzeugen von Heizenergie | EP02017175.7 | 2002-07-31 | EP1281856B1 | 2005-07-06 | Zieher, Wolfgang |
200 | Cogeneration system | EP04022220.0 | 2004-09-17 | EP1541811A3 | 2005-06-22 | Miyauchi, Shinji; Ueda, Tetsuya; Ozeki, Masataka |
A cogeneration system of the present invention includes: a power generation system (1) equipped with a power generator (11); waste heat utilization system (2) for recovering waste heat from the power generator (11), storing the heat, and utilize the waste heat as an effective output thermal energy; and a waste heat utilization promoting system for promoting utilization of the effective output thermal energy in the waste heat utilization system (12) to avoid a stop of the system associated with a heat storage amount reaching a full amount. A waste heat utilization promoting system (3) is equipped with a stop predicting function to predict an operation stop of the power generation system (1) by comparing a current operating state with a reference pattern and computing an operation sustainable time, and a stop warning function to give the user a warning of the operation stop with an image or sound according to stop prediction information obtained. |