| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 61 | LOW POLLUTION POWER GENERATION SYSTEM WITH ION TRANSFER MEMBRANE AIR SEPARATION | EP03786808 | 2003-11-17 | EP1576266A4 | 2009-04-15 | VITERI FERMIN |
| A low pollution power system has an air separator (1003) to collect oxygen and a gas generator (1004) to combust the oxygen and a hydrocarbon fuel. The combustion products are then expanded through at least one turbine (1005). Diluents are also delivered to the gas generator to control temperature. | ||||||
| 62 | COMPRESSED-AIR GENERATING SYSTEM | EP05772192.0 | 2005-08-10 | EP1781915B1 | 2009-02-18 | JÖRN, Paul, J. |
| 63 | COMPRESSED-AIR GENERATING SYSTEM | EP05772192.0 | 2005-08-10 | EP1781915A1 | 2007-05-09 | JÖRN, Paul, J. |
| A system comprises an H2/O2 steam generator (2) for generating superheated steam which is either fed directly to a gas turbine (8) to bring it to a rotary speed that is sufficient to result in a compressed-air ratio in the gas turbine that allows operation of the gas turbine with a fuel, or which superheated steam is fed to a compressed-air generator (4) for generating compressed-air, wherein the generated compressed-air is fed to a compressed-air system (7), for example of an aircraft, or is used for starting a gas turbine or for other compressed-air systems. | ||||||
| 64 | DAMPFKRAFTWERK | EP04763498.5 | 2004-07-26 | EP1658418A1 | 2006-05-24 | HABERBERGER, Georg; KAIL, Christoph |
| An inventive steam power plant (1) comprises at least one steam turbine (2) and a steam generator (5), whereby a combustion chamber (19), in the direction (9) of the flow of steam (17), is mounted after a first turbine stage (11) and before a second turbine stage (13) of the steam turbine (3), and the flow of steam (9) inside a combustion chamber (19) can be heated by mixing it with a hot gas that can be produced inside said combustion chamber (19). | ||||||
| 65 | WIRKUNGSGRADERHÖHUNG VON MIT WASSERSTOFF BETRIEBENEN VERBRENNUNGSMOTOREN | EP04763752.5 | 2004-08-03 | EP1651848A1 | 2006-05-03 | ADLER, Bernhard; ADLER, Robert; DORNER, Sascha |
| Disclosed is a method for delivering a medium that is combustible in an internal combustion engine. Said medium is delivered to the internal combustion engine at hyperbaric pressure as well as at an increased temperature while combustion air is supplied before and/or at least temporarily during the delivery of said medium. According to the invention, water (5) is delivered at least temporarily together with the combustion air (1). Preferably, the water is delivered in conditions which allow substantially all the delivered water (5) to be evaporated. | ||||||
| 66 | DAMPFKRAFTWERK | EP03761451.8 | 2003-05-15 | EP1518040A1 | 2005-03-30 | HABERBERGER, Georg; KAIL, Christoph |
| The invention relates to an inventive steam power plant (1) comprising at least one steam turbine (3) and a steam generator (5). According to the invention, a firing device (7) is located downstream of the steam generator (5) and upstream of the steam turbine (3) and/or downstream of a first turbine phase (11) and upstream of a second turbine phase (13) of the steam turbine (3) in the direction (9) of the steam flow (17) and the steam flow (17) can be heated in a combustion chamber (19) of the firing device (7) by being mixed with a heating gas that can be generated in the combustion chamber (19). | ||||||
| 67 | RETROFITTING COAL-FIRED POWER GENERATION SYSTEMS WITH HYDROGEN COMBUSTORS | EP98914437.3 | 1998-04-02 | EP1015738B1 | 2003-06-25 | BANNISTER, Ronald, L.; NEWBY, Richard, A. |
| A method of retrofitting a power generation system having a coal-fired steam boiler, a steam turbine system, and a condenser comprising installing a hydrogen-fired combustion system therein having the step of replacing the coal-fired steam boiler with a hydrogen-fired combustion system such that a steam flow generated by the hydrogen-fired combustion system is directed to the steam turbine system. Another method of retrofitting a power generation system has the steps of installing a hydrogen-fired combustion system to receive the steam flow, a hydrogen stream, and an oxygen stream, and to produce a super-heated steam flow therefrom; and installing a new steam turbine system capable of receiving and expanding said super-heated steam flow and directing said expanded super-heated steam flow to at least a portion of said original steam turbine system. | ||||||
| 68 | MEHRSTUFIGER DAMPFKRAFT-/ARBEITSPROZESS FÜR DIE ELEKTROENERGIEGEWINNUNG IM KREISPROZESS SOWIE ANORDNUNG ZU SEINER DURCHFÜHRUNG | EP98966514.6 | 1998-12-09 | EP1038094A2 | 2000-09-27 | HARAZIM, Wolfgang |
| The aim of the invention is to further improve the closed cycle for generating electric power in such a way that efficiency is enhanced and general pressure and temperature requirements regarding the working fluid used are substantially reduced. The invention also seeks to provide an improved technical solution that meets the requirements of continuos operation at rated output despite fluctuations in load requirements. This is achieved through a multistep steam power operating method for generating electric power in a cycle by using an additional gaseous energy carrier to increase the pressure, the temperature and the volume of the working fluid in the cycle and by recirculating the working fluid in the cycle in such a way that continuously overheated steam is used as a working fluid. The invention can be used in the generation of electric power in a cycle. | ||||||
| 69 | RETROFITTING COAL-FIRED POWER GENERATION SYSTEMS WITH HYDROGEN COMBUSTORS | EP98914437.3 | 1998-04-02 | EP1015738A1 | 2000-07-05 | BANNISTER, Ronald, L.; NEWBY, Richard, A. |
| A method of retrofitting a power generation system having a coal-fired steam boiler, a steam turbine system, and a condenser comprising installing a hydrogen-fired combustion system therein having the step of replacing the coal-fired steam boiler with a hydrogen-fired combustion system such that a steam flow generated by the hydrogen-fired combustion system is directed to the steam turbine system. Another method of retrofitting a power generation system has the steps of installing a hydrogen-fired combustion system to receive the steam flow, a hydrogen stream, and an oxygen stream, and to produce a super-heated steam flow therefrom; and installing a new steam turbine system capable of receiving and expanding said super-heated steam flow and directing said expanded super-heated steam flow to at least a portion of said original steam turbine system. | ||||||
| 70 | Hydrogen burning turbine plant | EP98115532.8 | 1998-08-18 | EP0900921A3 | 2000-01-26 | Uematsu, Kazuo Takasago Mach. Works of Mitsubishi; Sonoda, Takashi Takasago R.& D. Cen. of Mitsubishi; Mori, Hidetaka Takasago R.& D. Cent. of Mitsubishi; Sugishita, Hideaki Takasago R.& D.C. of Mitsubishi |
Easy plant starting is provided in hydrogen burning turbine plant for burning hydrogen and oxygen to generate high temperature steam for thereby driving turbine. There is constructed a semi-closed cycle such that low temperature steam from compressor 1 enters combustion chamber 2, hydrogen and oxygen are burned in the combustion chamber 2 to become high temperature steam for thereby driving turbines 3 and the steam gives exhaust heat at heat exchanger 4 and returns to low pressure compressor 1-1. Steam from midway of the heat exchanger 4 enters low pressure turbine 6 for work therein and is condensed to water and the water from condenser 7 is heated at heat exchangers 4-4, 4-3, 4-2 to become steam for driving high pressure turbine 5 and returns to the combustion chamber 2 through the heat exchanger 4. Auxiliary boiler is provided at inlet side of the compressor 1 and the high temperature steam generated at the combustion chamber 2 at starting time is diluted and supplied into the turbine 3, hence the starting can be done smoothly. |
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| 71 | Hydrogen burning turbine plant | EP98115532.8 | 1998-08-18 | EP0900921A2 | 1999-03-10 | Uematsu, Kazuo Takasago Mach. Works of Mitsubishi; Sonoda, Takashi Takasago R.& D. Cen. of Mitsubishi; Mori, Hidetaka Takasago R.& D. Cent. of Mitsubishi; Sugishita, Hideaki Takasago R.& D.C. of Mitsubishi |
Easy plant starting is provided in hydrogen burning turbine plant for burning hydrogen and oxygen to generate high temperature steam for thereby driving turbine. There is constructed a semi-closed cycle such that low temperature steam from compressor 1 enters combustion chamber 2, hydrogen and oxygen are burned in the combustion chamber 2 to become high temperature steam for thereby driving turbines 3 and the steam gives exhaust heat at heat exchanger 4 and returns to low pressure compressor 1-1. Steam from midway of the heat exchanger 4 enters low pressure turbine 6 for work therein and is condensed to water and the water from condenser 7 is heated at heat exchangers 4-4, 4-3, 4-2 to become steam for driving high pressure turbine 5 and returns to the combustion chamber 2 through the heat exchanger 4. Auxiliary boiler is provided at inlet side of the compressor 1 and the high temperature steam generated at the combustion chamber 2 at starting time is diluted and supplied into the turbine 3, hence the starting can be done smoothly. |
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| 72 | REDUCED POLLUTION POWER GENERATION SYSTEM AND GAS GENERATOR THEREFORE | EP95934960.0 | 1995-08-24 | EP0828929A2 | 1998-03-18 | Beichel, Rudi |
| Pollution-free or low pollution, efficient, large scale electrical power generation systems, using thermal energy from combustion of hydrocarbon fuel are described herein. The pollutant-free hydrocarbon fuel (4) is combusted in a gas generator (200) with pure oxygen (1) or substantially pure oxygen that is free of nitrogen. Water (64-66) is also injected into the gas generator (200). The gas generator discharges high enthalpy steam and carbon dioxide (10) which can then be utilized in a variety of applications, including driving turbines (13, 14, 17) for power generation. The steam can be recycled into the gas generator (200) or discharged for various uses. The carbon dioxide (5) an be collected for industrial use or discharged. | ||||||
| 73 | ENERGY SUPPLY SYSTEM | EP92910573.0 | 1992-05-29 | EP0587607A1 | 1994-03-23 | Best, Frederick George |
| Système de production d'énergie qui comprend une chambre de vaporisation (10) contenant un liquide vaporisable auquel on applique de la chaleur provenant d'une source thermique (A) afin de vaporiser ledit liquide, un dispositif de conversion d'énergie (12) entraîné par le liquide vaporisé provenant de la chambre de vaporisation, produisant ainsi de l'énergie mécanique, un condensateur (14) qui condense le liquide vaporisé sortant du dispositif de conversion d'énergie (12) et un dispositif d'alimentation (15) qui renvoie le condensat résultant dans la chambre de vaporisation, une partie au moins de l'énergie mécanique produite étant utilisée pour effectuer une électrolyse d'eau destinée à séparer cette dernière en ses éléments constituants en vue d'une recombinaison ultérieure créatrice d'énergie. | ||||||
| 74 | Reaction system for closed energy supply apparatus | EP85309042.1 | 1985-12-12 | EP0189659B1 | 1988-11-09 | Wood, Palmer R. |
| 75 | SYSTEM AND METHOD FOR SUPPLYING AN ENERGY GRID WITH ENERGY FROM AN INTERMITTENT RENEWABLE ENERGY SOURCE | US15315488 | 2014-06-16 | US20180209306A1 | 2018-07-26 | Oliver Heid; Paul Beasley; Timothy Hughes |
| A system and method for supplying an energy grid with energy from an intermittent renewable energy source having a production unit for producing Hydrogen and Nitrogen, a mixing unit configured to receive and mix the Hydrogen and the Nitrogen produced by the production unit, an Ammonia source for receiving and processing the Hydrogen-Nitrogen-mixture, an Ammonia power generator for generating energy for the energy grid, a heat distribution system with one or more heat exchangers, and an Ammonia cracker, which is fluidly connected to the Ammonia storage vessel and to the Ammonia power generator, and which is configured and arranged to receive Ammonia from the Ammonia storage vessel, to effect a partial cracking of the received Ammonia to form an Ammonia-Hydrogen-mixture and to direct the Ammonia-Hydrogen-mixture to the Ammonia power generator for combustion. | ||||||
| 76 | ENERGY STORAGE DEVICE AND METHOD FOR STORING ENERGY | US15568685 | 2016-04-19 | US20180142577A1 | 2018-05-24 | Peter ORTMANN; Werner GRAF |
| An energy storage device for storing energy including: a high-temperature regenerator containing a storage material and a working gas as heat transfer medium for the purpose of exchanging heat between the storage material and the traversing working gas, a closed charging circuit for the working gas, including a first compressor, a first expander, a first recuperator having a first and a second heat exchange duct, the high-temperature regenerator and a pre-heater, wherein the first compressor is coupled to the first expander by a shaft, a discharging circuit for the working gas, and including a switch that selectively connects the high-temperature regenerator to either the charging circuit or the discharging circuit, such that the circuit containing the high-temperature regenerator forms a closed circuit. | ||||||
| 77 | Air start steam engine | US15330922 | 2016-11-17 | US09816399B2 | 2017-11-14 | Michael Jeffrey Brookman |
| A method and system using at least two different working fluids to be supplied to an expander to cause it to do mechanical work. The expander is started by providing a compressed gaseous working fluid at a sufficient pressure to the expander. At the same time the compressed gaseous working fluid is provided to the expander, a second working fluid that is liquid at ambient temperatures is provided to a heater to be heated. The second working fluid is heated to its boiling point and converted to pressurized gas Once the pressure is increased to a sufficient level, the second working fluid is injected into the expander to generate power, and the supply of the first working fluid may be stopped. After expansion in the expander, the working fluids are is exhausted from the expander, and the second working fluid may be condensed for separation from the first working fluid. Control circuitry controls the admission of the first and second working fluids responsive to monitoring the load on the expander.Waste heat in the exhaust from the expander can be used to heat or alternatively to dry an element in a device that can be operated as a desiccator to dry air when operated in a summer mode, or to heat air when operated in a winter mode. The air having been dried or alternatively heated is then ducted to an evaporative cooler which cools the dried air in summer mode and humidifies the heated air in winter mode. | ||||||
| 78 | Captive Oxygen Fuel Reactor | US15205721 | 2016-07-08 | US20170009702A1 | 2017-01-12 | Buddy Ray Paul |
| A system of captive oxygen fuel reactor to efficiently generate electricity from hydrocarbon fuel utilizes a flow of oxygen and a flow of hydrogen from an electrolysis unit and a flow of carbon monoxide in order to complete a fuel oxidizer reaction within a heat exchanger unit. The fuel oxidizer reaction emits a flow of steam and a flow of carbon dioxide from the heat exchanger unit re-direct them through a steam rotary piston motor unit, a carbon dioxide rotary piston motor unit, a steam carousel motor unit, a carbon dioxide carousel motor unit, and a duel drum motor unit to generate electrical current. The exhaust gases within the system are properly discharged and stored within respective storage containers for the use of the system or other possible requirements. | ||||||
| 79 | Apparatus And Method Of Energy Recovery For Use In A Power Generating System | US15116416 | 2014-02-04 | US20170009605A1 | 2017-01-12 | James CORBISHLEY |
| This invention relates to a method of condensing and energy recovery within a thermal power plant using the Venturi effect and gas stored under hydrostatic pressure and to an energy storage system using the method in a hydrogen and oxygen combusting turbine, where the hydrogen and oxygen gasses are produced by water electrolysis and hydrostatically pressurised and stored. | ||||||
| 80 | Devices and methods for treatment of heart failure and associated conditions | US14142274 | 2013-12-27 | US08948874B2 | 2015-02-03 | Dimitrios Georgakopoulos; Eric Grant Lovett |
| Devices and methods of use are described for identification, treatment, and/or management of heart failure and/or associated conditions. An exemplary device may include a first fluid status monitoring circuit configured to monitor a first fluid status indicator of a pulmonary fluid status associated with pulmonary edema, a second fluid status monitoring circuit configured to monitor a separate and different second fluid status indicator of a non-pulmonary fluid status, and a controller coupled to the first and second fluid status monitoring circuits, and a therapy circuit coupled to the controller. The controller is configured to use information about the first and second fluid status indicators to determine a therapy control signal to control a therapy, and the therapy circuit is configured to provide therapy in response to the therapy control signal to adjust at least one of the pulmonary fluid status or the non-pulmonary fluid status. | ||||||
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