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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201 | Cogeneration system | EP04022220.0 | 2004-09-17 | EP1541811A2 | 2005-06-15 | 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. |
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202 | Gasbeheizter Durchlaufwassererhitzer | EP00111997.3 | 2000-06-20 | EP1063475A3 | 2003-03-26 | Daiber, Klaus |
Gasbeheizter Durchlauferhitzer (1) mit einem von einem Gasbrenner (2) beheizten Wärmetauscher (3), der im Wasserweg (4) von einer Kaltwasserquelle (5) zu einem Zapfventil (9) in Serie mit einem ein Flügelrad aufweisenden Durchsatzgeber (33) angeordnet ist, wobei der Gasbrenner (2) von einer mit einem Gasventil (13) versehenen Gasleitung (14) gespeist ist und ihm eine Zündelektrode (19) mit einer elektrischen Spannungsquelle zugeordnet ist. Dem Durchsatzgeber (33) ist ein Elektrogenerator (30) zugeordnet, der Spannungsquelle für die Zündelektrode (19) vorgesehen ist, wobei ihm ein Akkumulator (27) parallelgeschaltet ist. |
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203 | WÄRMEKRAFTMASCHINE | EP98925473.5 | 1998-04-14 | EP0975920B1 | 2002-06-19 | Rossteuscher, Andreas P. |
The present invention relates to a device for heating a heat transfer medium, comprising a heating unit designed to generate a source of heat, a heat transfer area, a wall, e.g. a vessel wall or a pipe wall, between the source of heat ant the heat transfer area, as well as a selective layer on at least one side of the wall, which layer furthers the absorption by said wall of the calorific power from the source of heat and/or inhibits heat emission from said wall towards the source of heat. | ||||||
204 | VORRICHTUNG ZUR ERZEUGUNG EINER ELEKTRISCHEN SPANNUNG FÜR KOMPONENTEN EINES GASBEHEIZTEN WASSERERHITZERS | EP00982990.4 | 2000-10-12 | EP1196721A1 | 2002-04-17 | DE BOER, Evert, Nicolaas; MEIJER, Bemardus, Johanes |
The invention relates to a device for generating an electrical voltage for components of a gas-fired water heater. The inventive device comprises a heat exchanger (13), through which a water-carrying line (15) comprising an outlet valve (18) passes. A turbine of a turbine generator (30) is integrated in said line (15) and supplies electrical voltage for the components of a water heater when the outlet valve (18) is opened. The turbine of the turbine generator (30) is arranged in a bypass that leads to the line (15). | ||||||
205 | VERFAHREN ZUR DOSIERUNG DER WÄRMELEISTUNG IN WÄRME-KRAFT-KOPPELUNGSVORRICHTUNGEN UND VORRICHTUNG DAZU | EP96918571.0 | 1996-06-28 | EP0835411A1 | 1998-04-15 | Ryhiner, Daniel G. |
The thermal output of a combined heat and power generation system is regulated by varying the speed of rotation while maintaining the position of the control means of the thermal engine in its maximum efficiency range. For that purpose, the thermal engine in its full load position or efficiency optimum is brought to a lower or higher speed of rotation exclusively by respectively reducing or increasing the electric current fed into the mains, so that the efficiency of the thermal engine is not substantially affected. The electric current may be maintained at the desired frequency by frequency converters. | ||||||
206 | Katalytischer Brenner | EP97101303.2 | 1997-01-29 | EP0789188A2 | 1997-08-13 | Schuler, Alex, Dr. |
Die Erfindung betrifft einen (1) katalytischen Brenner mit Brennmittel- und Luftzuführeinrichtungen mit mindestens einem Katalysator (3) und kühlmitteldurchflossenen Wandteilen (4,5), wobei die Wärmeübertragung des ersten Katalysators auf die Wandteile im wesentlichen durch Strahlung erfolgt. |
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207 | Wasserarmatur, insbesondere für sanitäre Hausinstallationen | EP89117572.1 | 1989-09-22 | EP0361333B1 | 1991-11-21 | Hochstrasser, Ferdinand F. |
208 | MICROTURBOALTERNATEUR HYDRAULIQUE | EP86903420.0 | 1986-06-04 | EP0225358A1 | 1987-06-16 | CHARRON, Jean-Claude |
Le microturboalternateur hydraulique est formé d'un surmoulage en matière plastique qui enrobe le stator feuilleté (2) du microalternateur en ménageant une chambre d'eau intérieure (20) destinée à recevoir le rotor (1) et dont le diamètre intérieur est au moins égal au diamètre extérieur dudit rotor augmenté d'une fraction de l'épaisseur radiale d'un entrefer de forme et dimension particulières, ledit corps moulé étant fermé de façon étanche par un boîtier (14) qui délimite une chambre d'eau (22) renfermant la turbine (15) et qui communique avec la chambre (20). Application aux appareils de production d'eau chaude par le gaz fonctionnant sans veilleuse permanente. | ||||||
209 | A PYROLYSIS CHAMBER FOR TREATING DOMESTIC REFUSE AND DWELLING EQUIPPED WITH SUCH A CHAMBER | EP18175648.7 | 2015-01-09 | EP3385004A1 | 2018-10-10 | Spencer, Nik; Gibbon, Matthew; Jouhara, Hussam |
Existing approaches to refuse handling are all based on historical approaches which rely on a network of refuse collection vehicles collecting waste from individual households and delivering this to a centralised landfill or MBI location. This is highly undesirable and wasteful. An alternative process is disclosed, relying on the thermal treatment of waste and like products produced or brought in to the residential property and processed within the domestic curtilage to produce fuel or other forms of energy. Thus, domestic waste will be thermally treated at the home instead of being collected by local authorities and disposed of. The waste input material will be loaded into a domestically engineered thermal conversion unit either directly or after a pre-process such as shredding. The feedstock will be converted into fuels by a thermal treatment, such as pyrolysis. The resultant output of oil and gas can either be stored or fed into a boiler unit to be used as a fuel to produce hot water, or used to run an electricity generating unit to power the dwelling in question or for supply to a feed-in tariff. Thus, a domestic dwelling includes a thermal treatment unit for processing waste produced in the dwelling, an output of the thermal treatment unit being combusted for producing an energy output for the dwelling. A suitable pyrolysis chamber is disclosed. |
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210 | HEIZKRAFTWERK UND VERFAHREN ZUM BETRIEB EINES SOLCHEN | EP16020470.7 | 2016-11-28 | EP3327361A1 | 2018-05-30 | Peter, Kristian; Reichenbach, Franz; Minde, Adrian; Glatz-Reichenbach, Joachim |
Heizkraftwerk aufweisend ein Blockheizkraftwerk (30), eine Wärmepumpe (24) und einen Stromspeicher (18), in welchem der mittels des Blockheizkraftwerks (30) erzeugte Strom speicherbar ist, sowie Verfahren zum Betrieb eines Heizkraftwerks, bei welchem von einem Blockheizkraftwerk (30) an die Umgebung abgegebene Abwärme mit einer Temperatur von weniger als 40°C als Wärmequelle einem Verdampfer (41) einer Wärmepumpe (24) zugeführt wird. |
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211 | Speicherbehälter | EP13188222.7 | 2013-10-11 | EP2728132B1 | 2017-08-09 | Thiessen, Ludmila; Henrichs, Thomas |
212 | DEVICE FOR HEATING, GENERATING ELECTRIC POWER, AND COOLING ENCLOSED SPACES | EP06819324.2 | 2006-11-08 | EP1946008B1 | 2017-02-15 | FRACCARO, Gimmi |
213 | PROCÉDÉ DE RÉGULATION D'UNE INSTALLATION COMPRENANT DES APPAREILS DE COGÉNERATION ET DES SYSTÈMES THERMODYNAMIQUES DESTINES A LA CLIMATISATION ET/OU AU CHAUFFAGE | EP13730031.5 | 2013-06-04 | EP2856040B1 | 2016-10-05 | MOREAU, Christian |
214 | THERMISCHE SOLARANLAGE | EP09716227.5 | 2009-02-04 | EP2252839B1 | 2016-03-16 | BISGES, Michael |
215 | A BOILER UNIT | EP09760965.5 | 2009-11-26 | EP2364512B1 | 2016-01-06 | DEVRIENDT, James; EVANS, Christopher John; MORGAN, Robert; BARNARD, Paul; GIRVAN, Bruce |
216 | DOMESTIC COMBINED HEAT AND POWER SYSTEM | EP11850132 | 2011-07-19 | EP2657618A4 | 2015-08-19 | PARK CHANG KWON |
217 | PROCÉDÉ DE RÉGULATION D'UNE INSTALLATION COMPRENANT DES APPAREILS DE COGÉNERATION ET DES SYSTÈMES THERMODYNAMIQUES DESTINES A LA CLIMATISATION ET/OU AU CHAUFFAGE | EP13730031.5 | 2013-06-04 | EP2856040A1 | 2015-04-08 | MOREAU, Christian |
Method of managing a plant comprising cogenerating installations and thermodynamic systems, and a computing machine, said method comprising the following steps: a) "base data" are entered into the computing machine, comprising at least the resilience to electrical impact of the cogenerating installation, and the value of maximum intensity of the heat pump, b) "instantaneous data" are entered into said computing machine, comprising at least the state of the cogenerating installation, the state of the heat pump and the electrical power demanded by the heat pump, c) "target data" are defined, to which are assigned a respective "target value" in said computing machine, these target data comprising at least the minimum and/or maximum production of electricity by the plant, optionally the maximum consumption of electricity and of primary energy, and at least one from among: the temperatures of very hot water (T2), of hot water (T1), of cold water (T3), of evaporation of coolant fluid (T4, T5), and the electricity demand of the local network, d) the plant is regulated with the aid of said computing machine in such a way as to attain, for each of the target data selected, the target value or values which have been assigned thereto, the regulation being performed by adjustment of at least one "adjustment datum", in such a way that the current value of each target datum selected is made to approach the target value assigned to it in step c), the at least one adjustment datum comprising the electrical power provided by the cogenerating installation. | ||||||
218 | COGENERATION SYSTEM | EP12849473.9 | 2012-09-28 | EP2781853A1 | 2014-09-24 | SHIMADA, Takanori; KATOU, Motomichi; FUJII, Masashi |
In a cogeneration system (10A), a controller (20A) sets a control variable, which is a variable according to user's heat demand, on every unit time set in advance, and controls operation of the cogeneration device (11A). Further, when a heat storage quantity detected by a heat quantity detector (13) is out of a target range of the heat storage quantity set in advance, the controller (20A) changes a setting value of the control variable in a subsequent unit time, and controls operation of the cogeneration device (11A). |
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219 | BLOCKHEIZKRAFTWERK UND VERFAHREN ZU DESSEN BETRIEB | EP12810155.7 | 2012-12-12 | EP2764298A1 | 2014-08-13 | KAUTZ, Martin; METZGER, Michael; SCHÄFER, Jochen; WOLFRUM, Philipp |
The invention relates to a method for operating a combined heat and power plant (10) for the provision of electrical and thermal energy for at least one load (12, 14), wherein the retrieved heat output is increased when a threshold value for a difference between a provided and retrieved heat output is exceeded. | ||||||
220 | Optimized control of an energy supplying system or an energy consuming system | EP09169930.6 | 2009-09-10 | EP2299189B1 | 2014-07-23 | De Ridder, Fedor |