| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 41 | SYSTEMS AND METHODS OF THERMAL TRANSFER AND/OR STORAGE | US12885411 | 2010-09-17 | US20110120673A1 | 2011-05-26 | 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. | ||||||
| 42 | Solar thermal power system | US12030065 | 2008-02-12 | US07735323B2 | 2010-06-15 | Charles L. Bennett |
| A solar thermal power generator includes an inclined elongated boiler tube positioned in the focus of a solar concentrator for generating steam from water. The boiler tube is connected at one end to receive water from a pressure vessel as well as connected at an opposite end to return steam back to the vessel in a fluidic circuit arrangement that stores energy in the form of heated water in the pressure vessel. An expander, condenser, and reservoir are also connected in series to respectively produce work using the steam passed either directly (above a water line in the vessel) or indirectly (below a water line in the vessel) through the pressure vessel, condense the expanded steam, and collect the condensed water. The reservoir also supplies the collected water back to the pressure vessel at the end of a diurnal cycle when the vessel is sufficiently depressurized, so that the system is reset to repeat the cycle the following day. The circuital arrangement of the boiler tube and the pressure vessel operates to dampen flow instabilities in the boiler tube, damp out the effects of solar transients, and provide thermal energy storage which enables time shifting of power generation to better align with the higher demand for energy during peak energy usage periods. | ||||||
| 43 | Solar Thermal Power System | US12030065 | 2008-02-12 | US20090199557A1 | 2009-08-13 | Charles L. Bennett |
| A solar thermal power generator includes an inclined elongated boiler tube positioned in the focus of a solar concentrator for generating steam from water. The boiler tube is connected at one end to receive water from a pressure vessel as well as connected at an opposite end to return steam back to the vessel in a fluidic circuit arrangement that stores energy in the form of heated water in the pressure vessel. An expander, condenser, and reservoir are also connected in series to respectively produce work using the steam passed either directly (above a water line in the vessel) or indirectly (below a water line in the vessel) through the pressure vessel, condense the expanded steam, and collect the condensed water. The reservoir also supplies the collected water back to the pressure vessel at the end of a diurnal cycle when the vessel is sufficiently depressurized, so that the system is reset to repeat the cycle the following day. The circuital arrangement of the boiler tube and the pressure vessel operates to dampen flow instabilities in the boiler tube, damp out the effects of solar transients, and provide thermal energy storage which enables time shifting of power generation to better align with the higher demand for energy during peak energy usage periods. | ||||||
| 44 | Power-producing system | US17582827 | 1927-03-16 | US1774293A | 1930-08-26 | BERNHARD SCHOTTELIUS |
| 45 | Steam-accumulator apparatus for steam plants | US33511419 | 1919-11-01 | US1501623A | 1924-07-15 | KARL RUTHS JOHANNES |
| 46 | APPARATUS AND METHOD OF ENERGY RECOVERY FOR USE IN A POWER GENERATING SYSTEM | EP14703408.6 | 2014-02-04 | EP3102797B1 | 2018-10-17 | Corbishley, James |
| 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. | ||||||
| 47 | Anlage zur Nutzung von Wärmeenergie | EP13157647.2 | 2013-03-04 | EP2730755B1 | 2017-09-27 | Bommer, Rolf |
| 48 | Anlage zur Nutzung von Wärmeenergie | EP13157647.2 | 2013-03-04 | EP2730755A3 | 2014-07-02 | Bommer, Rolf |
Die Erfindung betrifft eine Anlage zur Nutzung von Wärmeenergie, mit einem Druckbehälter (10), mit einem Rotationskolbenmotor (12), der zumindest eine Arbeitskammer (32) mit zwei Einlässen (13, 15) und zwei Auslässen (14, 16) aufweist, mit einer Überdruckleitung (11), die den Druckbehälter (10) mit den Einlässen (13, 15) verbindet, und mit einem an den Rotationskolbenmotor (12) angebundenen Generator (27) und/oder einer an den Rotationskolbenmotor (12) angebundene Kältemaschine (24), sowie einen Rotationskolbenmotor (12) für eine solche Anlage.
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| 49 | Anlage zur Nutzung von Wärmeenergie | EP13157647.2 | 2013-03-04 | EP2730755A2 | 2014-05-14 | Bommer, Rolf |
Die Erfindung betrifft eine Anlage zur Nutzung von Wärmeenergie, mit einem Druckbehälter (10), mit einem Rotationskolbenmotor (12), der zumindest eine Arbeitskammer (32) mit zwei Einlässen (13, 15) und zwei Auslässen (14, 16) aufweist, mit einer Überdruckleitung (11), die den Druckbehälter (10) mit den Einlässen (13, 15) verbindet, und mit einem an den Rotationskolbenmotor (12) angebundenen Generator (27) und/oder einer an den Rotationskolbenmotor (12) angebundene Kältemaschine (24), sowie einen Rotationskolbenmotor (12) für eine solche Anlage.
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| 50 | STEAM STORAGE SYSTEM FOR ARTIFICIAL SOLAR ISLAND | EP09708771.2 | 2009-02-06 | EP2315918A2 | 2011-05-04 | HINDERLING, Thomas |
| A system [500] for producing solar energy at a desired temperature and pressure range includes a primary energy source [501] that is used in a Clausius Rankine cycle, with the primary energy source connected to and proximate to a plurality of solar collectors [520]. More particularly, at least one steam storage tank [501] feeds the expansion step of the Clausius Rankine cycle. This enables the system [500] to reliably supply energy during times when the solar collectors receive little or no radiation. According to one aspect of the invention, the solar collectors [520] reside on an artificial island [510a, 510b, 510c], preferably sea-based, or offshore, so that the steam storage tank [501a, 501b, 501c] can be located well below sea level. This enables the use of compressive forces from the sea water to counteract the outwardly directed pressure caused by the steam contained in the steam storage tank [501a, 501b, 501c]. Moreover, this storage tank [501c] may have a dual-walled structure [501d, 501e], for insulation purposes, and may be operatively connected to a sea level condenser [501i] to produce sweet water. Still further, steam from the steam storage tank [501] can be used to drive one or more absorption chiller devices housed within an absorption chiller unit [530a] that is operatively connected to an air conditioning system [530b]. And these structures can be located on the roof of a building [530] so as to supply air conditioning to the building [530]. | ||||||
| 51 | Steam boiler | EP84308189.4 | 1984-11-26 | EP0143636A2 | 1985-06-05 | 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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| 52 | STEAM TURBINE WITH STEAM STORAGE SYSTEM | EP17205005.6 | 2017-12-01 | EP3346101A1 | 2018-07-11 | KIRCHNER, Julia Maria; CUCHE, Theres; MORRIS, Kevin |
A steam turbine system (14, 200) including a steam source for generating a steam flow, a high-pressure turbine (16, 206) providing a first steam exhaust (208), a low-pressure turbine (18, 210) fluidly coupled to the high-pressure turbine (206), and, a steam storage system (212) having an inlet (216) for receiving a portion (214) of the first steam exhaust (208) from the high-pressure steam turbine (16, 206) and storing in the steam storage system (212), the steam storage system (212) having an output with a pressure relief valve for discharging a second steam exhaust (222) to the low-pressure turbine (18, 210).
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| 53 | VERFAHREN ZUM BETREIBEN EINES GAS-UND-DAMPF-KOMBINATIONSKRAFTWERKS | EP16778264.8 | 2016-09-26 | EP3344858A1 | 2018-07-11 | BECKER, Stefan; DANOV, Vladimir; LENK, Uwe; SCHMID, Erich; SCHÄFER, Jochen; TREMEL, Alexander |
| The invention relates to a method for operating a gas-and-steam combined cycle power station (10) in which exhaust gas is produced by a gas turbine (12) and is supplied to a steam generator (20), wherein hot steam is produced using the exhaust gas supplied to said steam generator (20) and by means of said steam generator (20), and this steam serves to drive at least one generator (30) using at least one turbine device (22) in order to provide electrical current. The exhaust gas supplied to the steam generator (20) is conducted away from said steam generator (20), and at least one portion of the heat contained in the exhaust gas, downstream of the steam generator (20), is used to initiate an endothermic chemical reaction. | ||||||
| 54 | INTERMEDIATE PRESSURE STORAGE SYSTEM FOR THERMAL STORAGE | EP10756978 | 2010-03-26 | EP2411672A4 | 2017-08-09 | MIERISCH ROBERT CHARLES; BISSET STEPHEN JAMES |
| 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. | ||||||
| 55 | METHOD FOR OPERATING A THERMOELECTRIC SOLAR PLANT | EP13822579 | 2013-07-11 | EP2876265A4 | 2016-03-16 | OLAVARRÍA RODRÍGUEZ-ARANGO RAFAEL; MÉNDEZ MARCOS JOSÉ MARÍA; DIAGO LÓPEZ MAITE |
| 56 | METHOD FOR OPERATING A THERMOELECTRIC SOLAR PLANT | EP13822579.2 | 2013-07-11 | EP2876265A1 | 2015-05-27 | OLAVARRÍA RODRÍGUEZ-ARANGO, Rafael; MÉNDEZ MARCOS, José María; DIAGO LÓPEZ, Maite |
SUMMARY 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 needs to have energy storage in high-pressure steam tanks. The method described allows the direct introduction of saturated steam into a superheated steam turbine. This steam receives 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 steam tanks at high-pressure). |
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| 57 | INTERMEDIATE PRESSURE STORAGE SYSTEM FOR THERMAL STORAGE | EP10756978.2 | 2010-03-26 | EP2411672A2 | 2012-02-01 | MIERISCH, Robert, Charles; BISSET, Stephen, James |
| 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. | ||||||
| 58 | 가스 및 증기 복합 사이클 발전소를 동작시키기 위한 방법 | KR20187012968 | 2016-09-26 | KR20180063299A | 2018-06-11 | |
| 본발명은가스및 증기복합사이클발전소(10)를동작시키기위한방법에관한것으로, 가스및 증기복합사이클발전소(10)에서, 가스터빈(12)으로부터의배기가스를사용하여고온증기가생성되고, 고온증기는, 전류를생성하기위해적어도하나의터빈디바이스(22)를사용하여적어도하나의발생기(30)를구동시키는역할을하며, 상기방법은: - 생성된증기의적어도일 부분을분기(branching off)시키고그리고분기된증기를증기어큐뮬레이터(34)에저장하는단계; 증기어큐뮬레이터(34)에저장된증기의적어도일 부분을상기증기어큐뮬레이터(34) 밖으로인도하는단계; - 증기어큐뮬레이터(34) 밖으로인도된증기를, 발열화학반응동안릴리즈된열을사용하여가열하는단계; 및 - 가열된증기를터빈디바이스(22)로인도하는단계를포함하며, 터빈디바이스(22)는공급되는가열된증기를사용하여구동된다. | ||||||
| 59 | 가스-및-스팀 복합 사이클 전력 스테이션을 동작시키기 위한 방법 | KR20187012953 | 2016-09-26 | KR20180059938A | 2018-06-05 | |
| 본발명은, 가스-및-스팀복합사이클전력스테이션(10)을동작시키기위한방법에관한것이며, 이가스-및-스팀복합사이클전력스테이션(10)에서, 배기가스가가스터빈(12)에의해생산되어스팀생성기(20)에공급되고, 상기스팀생성기(20)에공급된배기가스를사용하여그리고상기스팀생성기(20)에의하여뜨거운스팀이생산되며, 이스팀은, 전류를제공하기위하여, 적어도하나의터빈디바이스(22)를사용하여적어도하나의발전기(30)를구동하는역할을한다. 스팀생성기(20)에공급된배기가스는상기스팀생성기(20)로부터배출되며, 스팀생성기(20)의하류에서, 배기가스에포함된열의적어도일 부분은, 흡열화학반응을개시하기위해사용된다. | ||||||
| 60 | 증기 보일러 장치 | KR2019840012244 | 1984-11-27 | KR2019890004585Y1 | 1989-07-08 | 아가다아끼히꼬 |
| 내용 없음. | ||||||
