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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21 | Steam heat storage system | US14424755 | 2013-08-27 | US09683788B2 | 2017-06-20 | Marco Olcese |
A solar plant including a solar field for production of steam, a turbine using steam, and an excess steam storage and draw off system. The system includes a latent heat thermal storage module and a liquid displacement thermal storage module including a liquid volume and a steam blanket. The modules are connected together so that the steam produced passes through the steam blanket before passing through the latent heat module, condensing, to be injected in the liquid volume, the lower part of the liquid volume being connected to the solar field and to an outlet of the turbine to let in or return cold liquid. The liquid volume acts as a liquid displacement reservoir. | ||||||
22 | 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. | ||||||
23 | SYSTEM AND METHOD FOR ACCUMULATING STEAM IN TANKS FOR SOLAR USE | US13377967 | 2010-06-18 | US20120131915A1 | 2012-05-31 | Rafael Olavarria Rodríguez-Arango; Elena García Ramírez; José Barragán Jiménez |
System and method for accumulating steam in tanks for solar use made up of two sets of Ruths tanks (1, 2), called base set and overheat set, identical to one another and each having a saturated steam inlet (3), steam injectors (10) installed inside the tank (1, 2), a steam outlet (4, 4′) with a valve (13) and drainage means (11). A heat exchanger (6) is installed between the two sets of tanks (1, 2). The method of storage consists of a tank loading stage and a tank discharging stage, the latter comprising two discharging phases, the first one from a maximum to an intermediate pressure and the second one from an intermediate to a low pressure. | ||||||
24 | INTERMEDIATE PRESSURE STORAGE SYSTEM FOR THERMAL STORAGE | US12748353 | 2010-03-26 | US20100252028A1 | 2010-10-07 | Robert Charles Mierisch; Stephen James Bisset |
In some implementations, there is provided an apparatus. The apparatus may include a first steam engine, an intermediate storage, and a second steam engine. The first steam engine may include a first inlet and a first exhaust, wherein the first inlet receives steam from a source of thermal energy. The intermediate storage may be coupled to the first exhaust, wherein the intermediate storage stores thermal energy provided by steam from the first exhaust. The second steam engine may include a second inlet coupled to the intermediate storage. Moreover, at least one of the first steam engine and the second steam engine may produce work. Furthermore, the first steam engine may be driven by the steam received from the source of thermal energy, and the second steam engine may be driven by steam from at least one of the intermediate storage and the first exhaust. Related apparatus and methods are also described. | ||||||
25 | Steam plant | US12294637 | 1937-01-29 | US2167469A | 1939-07-25 | GUNNAR WALLIN CARL |
26 | Steam power plant | US27442728 | 1928-05-02 | US1835610A | 1931-12-08 | PAGE CHARLES B |
27 | Steam plant | US56124022 | 1922-05-15 | US1634609A | 1927-07-05 | ERNST CONSTAM |
28 | ruths | US1585790D | US1585790A | 1926-05-25 | ||
29 | Steam-accumulator plant | US688425 | 1925-02-04 | US1572963A | 1926-02-16 | KARL RUTHS JOHANNES; NILS PERSSON |
30 | Steam-accumulator plant | US434325 | 1925-01-23 | US1572962A | 1926-02-16 | KARL RUTHS JOHANNES; NILS PERSSON |
31 | Steam plant | US72354924 | 1924-07-01 | US1555465A | 1925-09-29 | GEORG FORNER |
32 | APPARATUS AND METHOD OF ENERGY RECOVERY FOR USE IN A POWER GENERATING SYSTEM | EP14703408.6 | 2014-02-04 | EP3102797A1 | 2016-12-14 | Corbishley, James |
A method of condensing and energy recovery within a thermal power plant using the Venturi effect and gas stored under hydrostatic pressure, and an energy storage system using that method in a hydrogen and oxygen combusting turbine, where the hydrogen and oxygen gasses are produced by water electrolysis and hydrostatically pressurised and stored. | ||||||
33 | SYSTEM AND METHOD FOR ACCUMULATING STEAM IN TANKS FOR SOLAR USE | EP10789033.7 | 2010-06-18 | EP2444594A1 | 2012-04-25 | OLAVARRIA RODRÍGUEZ-ARANGO, Rafael; GARCÍA RAMIREZ, Elena; BARRAGÁN JIMÉNEZ, José |
System and method for accumulating steam in tanks for solar use made up of two sets of Ruths tanks (1, 2), called base set and overheat set, identical to one another and each having a saturated steam inlet (3), steam injectors (10) installed inside the tank (1, 2), a steam outlet (4, 4') with a valve (13) and drainage means (11). A heat exchanger (6) is installed between the two sets of tanks (1, 2). The method of storage consists of a tank loading stage and a tank discharging stage, the latter comprising two discharging phases, the first one from a maximum to an intermediate pressure and the second one from an intermediate to a low pressure. |
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34 | Steam boiler | EP84308189 | 1984-11-26 | EP0143636A3 | 1985-11-27 | Agata, Akihiki c/o Shin-ei K. K. |
A steam boiler having a steam accumulator connected between the boiler and a user, a flow meter provided on the nlet side of the steam accumulator, and a pressure detector brovided on the steam accumulator for detecting the internal bressure thereof, wherein the steam boiler is arranged to detect by the flow meter the steam flow rate on the inlet side of the steam accumulator, which is varied in the fashion of following the mean value of steam load, to detect the internal pressure of the steam accumulator by the pressure detector, and to calculate the steam load on the outlet side of the steam 3ccumulator by a steam load detector on the basis of signals of detected steam flow rate and pressure variation. |
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35 | Gas-and-Steam Combined-Cycle Power Plant | US15761550 | 2016-09-26 | US20180340451A1 | 2018-11-29 | Stefan Becker; Vladimir Danov; Uwe Lenk; Erich Schmid; Jochen Schäfer; Alexander Tremel |
The present disclosure relates to power plants. Various embodiments thereof may include a method for operating a gas-and-steam combined-cycle power plant. For example, some embodiments may include a method for operating a gas-and-steam combined-cycle power plant including: providing exhaust gas from a gas turbine to a steam generator; generating steam by means of the exhaust gas; driving a generator with the steam via a turbine installation to provide an electric current; removing the exhaust gas from the steam generator; and using at least a portion of heat contained in the exhaust gas downstream from the steam generator to affect an endothermic chemical reaction. | ||||||
36 | Intermediate pressure storage system for thermal storage | US12748353 | 2010-03-26 | US10047637B2 | 2018-08-14 | Robert Charles Mierisch; Stephen James Bisset |
In some implementations, there is provided an apparatus. The apparatus may include a first steam engine, an intermediate storage, and a second steam engine. The first steam engine may include a first inlet and a first exhaust, wherein the first inlet receives steam from a source of thermal energy. The intermediate storage may be coupled to the first exhaust, wherein the intermediate storage stores thermal energy provided by steam from the first exhaust. The second steam engine may include a second inlet coupled to the intermediate storage. Moreover, at least one of the first steam engine and the second steam engine may produce work. Furthermore, the first steam engine may be driven by the steam received from the source of thermal energy, and the second steam engine may be driven by steam from at least one of the intermediate storage and the first exhaust. Related apparatus and methods are also described. | ||||||
37 | STEAM TURBINE WITH STEAM STORAGE SYSTEM | US15392703 | 2016-12-28 | US20180179915A1 | 2018-06-28 | Julia Maria Kirchner; Theres Cuche; Kevin Morris |
A steam turbine system including a steam source for generating a steam flow, a high pressure turbine providing a first steam exhaust, a low pressure turbine fluidly coupled to the high pressure turbine, and, a steam storage system having an inlet for receiving a portion of the first steam exhaust from the high pressure steam turbine and storing in the steam storage system, the steam storage system having an output with a pressure relief valve for discharging a second steam exhaust to the low pressure turbine. | ||||||
38 | Systems and methods of thermal transfer and/or storage | US12885411 | 2010-09-17 | US09612059B2 | 2017-04-04 | XiaoDong Xiang; Rong Zhang |
Systems, methods, and computer-implemented embodiments consistent with the inventions herein are directed to storing and/or transferring heat. In one exemplary implementation, there is provided a system for transferring/storing heat comprised of a heat exchange/storage apparatus including a chamber, and a heat input device adapted to heat/provide a vapor into the chamber. Other exemplary implementations may include one or more features consistent with a heat output device through which a working medium/fluid passes, a thermal storage medium located within the chamber, and/or a heat exchange system that delivers a heat exchange medium/fluid to the thermal storage medium. | ||||||
39 | STEAM HEAT STORAGE SYSTEM | US14424755 | 2013-08-27 | US20150219403A1 | 2015-08-06 | Marco Olcese |
A solar plant including a solar field for production of steam, a turbine using steam, and an excess steam storage and draw off system. The system includes a latent heat thermal storage module and a liquid displacement thermal storage module including a liquid volume and a steam blanket. The modules are connected together so that the steam produced passes through the steam blanket before passing through the latent heat module, condensing, to be injected in the liquid volume, the lower part of the liquid volume being connected to the solar field and to an outlet of the turbine to let in or return cold liquid. The liquid volume acts as a liquid displacement reservoir. | ||||||
40 | METHOD FOR OPERATING A THERMOELECTRIC SOLAR PLANT | US14417116 | 2013-07-11 | US20150204315A1 | 2015-07-23 | Rafael Olavarría Rodríguez-Arango; José Maria Méndez Marcos; Maite Diago López |
Method of operating a solar thermoelectric power plant that allows operation of high-, medium- and low-pressure superheating turbines with both superheated steam and saturated steam. The plant includes energy storage in high-pressure liquid tanks. The method described allows the direct introduction of saturated steam into a superheated steam turbine. This steam may receive an intermediate reheating between the high-pressure turbine and the low- and medium-pressure turbines to achieve conditions of superheated steam. The mode of operation proposed in the invention facilitates the operation of the plant in periods without sunshine (during transient periods, such as passing clouds or night time) or during discharge of accumulators (saturated liquid tanks at high-pressure). |