子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 在太阳能水箱中聚积蒸汽的系统和方法 | CN201080027465.6 | 2010-06-18 | CN102803662B | 2015-02-25 | R·奥拉瓦里亚罗德里格斯-艾兰格; E·加西亚拉米雷斯; J·巴拉甘希梅内斯 |
| 本发明公开了一种在太阳能水箱中聚积蒸汽的系统和方法,该系统由两组路斯型水箱组成,分别为基本组水箱(1)和过热组水箱(2),基本组水箱(1)和过热组水箱(2)彼此相同并且每一组都具有:饱和蒸汽入口(3)、安装在水箱(1、2)内部的蒸汽注入器(10)、具有阀(13)的蒸汽出口(4、4’)和排出装置(11)。热交换器(6)安装在两组水箱(1、2)之间。存储的方法由水箱加载阶段和水箱排出阶段组成,水箱排出阶段包括两个排出步骤,第一步骤从最大压强降低到中间压强,第二步骤从中间压强降低到低压强。 | ||||||
| 2 | 在太阳能水箱中聚积蒸汽的系统和方法 | CN201080027465.6 | 2010-06-18 | CN102803662A | 2012-11-28 | R·奥拉瓦里亚罗德里格斯-艾兰格; E·加西亚拉米雷斯; J·巴拉甘希梅内斯 |
| 本发明公开了一种在太阳能水箱中聚积蒸汽的系统和方法,该系统由两组路斯型水箱组成,分别为基本组水箱(1)和过热组水箱(2),基本组水箱(1)和过热组水箱(2)彼此相同并且每一组都具有:饱和蒸汽入口(3)、安装在水箱(1、2)内部的蒸汽注入器(10)、具有阀(13)的蒸汽出口(4、4’)和排出装置(11)。热交换器(6)安装在两组水箱(1、2)之间。存储的方法由水箱加载阶段和水箱排出阶段组成,水箱排出阶段包括两个排出步骤,第一步骤从最大压强降低到中间压强,第二步骤从中间压强降低到低压强。 | ||||||
| 3 | Hydraulic drives for use in charging systems, ballast systems, or other systems of underwater vehicles | US15173214 | 2016-06-03 | US09834288B1 | 2017-12-05 | Gregory W. Heinen |
| An apparatus includes first and second tanks each configured to receive and store a refrigerant under pressure. The apparatus also includes at least one generator configured to receive flows of the refrigerant between the tanks and to generate electrical power based on the flows of the refrigerant. The apparatus further includes first and second hydraulic drives associated with the first and second tanks, respectively. Each hydraulic drive includes a first piston within the associated tank, a channel fluidly coupled to the associated tank and configured to contain hydraulic fluid, and a second piston within the channel and configured to move within the channel in order to vary an amount of the hydraulic fluid within the associated tank and vary a position of the first piston within the associated tank. The channel of each hydraulic drive has a cross-sectional area that is less than a cross-sectional area of the associated tank. | ||||||
| 4 | Method for controlling a thermal power plant using regulated valves | US14653447 | 2013-12-18 | US09574461B2 | 2017-02-21 | Eve Dufosse |
| A method of controlling a thermal power plant for electricity generation, said power plant comprising at least one heat source to supply thermal energy to a working fluid circulation circuit. The circuit comprises a high pressure turbine mechanically connected to an electricity generator, a high pressure regulating valve controlling the steam supply to said high pressure turbine from a high pressure superheater associated with a high pressure storage tank. The fluid supply to said high pressure storage tank from a high pressure steam generator is controlled by a high pressure supply valve, and, in response to a need for additional electrical power, the opening of the high pressure regulating valve is increased the opening of the high pressure supply valve is reduced. | ||||||
| 5 | Concentrating conventional thermal or thermodynamic solar power plant | US14744687 | 2015-06-19 | US09540943B2 | 2017-01-10 | Jean Rutten |
| A power plant comprises: (a) a liquid pressurizing unit, (b) a Pelton turbine having a rotating shaft, (c) a duct connecting the pressurizing unit to the Pelton turbine for supplying pressurized liquid to the Pelton turbine, the duct being provided with at least one injector, and (d) a generator, advantageously an alternator, capable of being driven directly by the rotating shaft of the turbine, advantageously with the interposition of a gear system. | ||||||
| 6 | Apparatus, system, and methods for mechanical energy regeneration | US14658617 | 2015-03-16 | US09394807B1 | 2016-07-19 | Sten Kreuger |
| Systems and methods for storing and retrieving thermo-mechanical energy are disclosed. The systems and methods generally include a thermodynamic loop or cycle (e.g., a reversible transcritical, trilateral, or Rankine/vapor compression cycle) that works as a heat pump in a charging mode and as a heat engine in a discharging mode. The thermodynamic loop or cycle includes a gas pressure changing device, a liquid pressure changing device, and a working fluid. The system further includes one or more heat storage devices with solid heat storage material(s). Heat is transferred between the working fluid and the solid heat storage material(s) in the high and low pressure sides of the thermodynamic cycle, respectively. | ||||||
| 7 | 集中熱力学的太陽光発電所または従来の火力発電所 | JP2015548113 | 2013-12-17 | JP2016504521A | 2016-02-12 | ルツテン,ジヤン |
| ランキン(Rankine)蒸気サイクルを使用しそしてペルトン(Pelton)水車をそれと組み合わせて、熱力学的エネルギーを機械エネルギーに変える、熱力学的太陽光発電所または火力発電所。【選択図】図4 | ||||||
| 8 | CENTRALE ÉLECTRIQUE THERMIQUE CLASSIQUE OU SOLAIRE THERMODYNAMIQUE À CONCENTRATION | EP13826989.9 | 2013-12-17 | EP2935807B1 | 2017-05-10 | RUTTEN, Jean |
| 9 | THERMAL SOLAR POWER PLANT | EP09719258.7 | 2009-03-11 | EP2279334A1 | 2011-02-02 | FORSLUND, Örjan |
| The present invention relates toa thermal solar power plant comprisinga sun panel system for transferring of solar energyto a fluid, a first accumulator tank which is connected to the sun panelsystem, whereby the fluid is arranged to circulate via tubes and valves between the first accumulator tank and the sun panel system. A turbine is connected to the first accumulator tankby means of at least one pressure regulatedvalve, and anelectricity generatoris connected to the turbine,for generation of electricity. The power plantfurther comprises a second accumulator tank which is connected to the sun panel system, whereby the fluid is arranged to circulate via tubes and valves between the second accumulator tank and the sun panel system. The second accumulator tankis connected to the turbine by means of at least one pressure regulated valve, whereby the sun panel system alternately heats up fluid which circulates between the first accumulator tank and the sun panel system, and fluid which circulates between the second accumulator tank and the sun panel system. | ||||||
| 10 | 集中熱力学的太陽光発電所または従来の火力発電所 | JP2015548113 | 2013-12-17 | JP6298072B2 | 2018-03-20 | ルツテン,ジヤン |
| 11 | 調整バルブを用いて熱パワープラントを制御する方法 | JP2015548536 | 2013-12-18 | JP6022712B2 | 2016-11-09 | ドゥフォセ,イヴ |
| 12 | 調整バルブを用いて熱パワープラントを制御する方法 | JP2015548536 | 2013-12-18 | JP2016506472A | 2016-03-03 | ドゥフォセ,イヴ |
| 本発明は、発電用の熱パワープラントを制御する方法に関し、前記パワープラントは、作動流体循環回路(1)に熱エネルギーを供給する少なくとも一つの熱源(5)を有し、前記回路は、少なくとも、発電機(6)に機械的に接続された高圧タービン(10)と、高圧貯蔵タンク(13)に対応する高圧過熱器(12)から前記高圧タービン(10)への蒸気供給を制御する高圧調整バルブ(11)であって、高圧蒸気発生器(15)から前記高圧貯蔵タンク(13)への流体供給は、高圧供給バルブ(14)により制御される、高圧調整バルブと、を有し、追加の電力の必要性に応じて、前記高圧調整バルブ(11)の開状態が高められ、前記高圧供給バルブ(14)の開状態が抑制される。 | ||||||
| 13 | Apparatus and method for periodically charging ocean vessel or other system using thermal energy conversion | US15173178 | 2016-06-03 | US10036510B2 | 2018-07-31 | Gregory W. Heinen; Pierre J. Corriveau |
| An apparatus includes multiple tanks each configured to receive and store a liquid refrigerant under pressure. The apparatus also includes one or more insulated water jackets each configured to receive and retain water around at least part of an associated one of the tanks. The apparatus further includes at least one generator configured to receive a flow of the liquid refrigerant and to generate electrical power based on the flow of the liquid refrigerant. The apparatus also includes one or more first valves configured to control the flow of the liquid refrigerant between the tanks and through the at least one generator. In addition, the apparatus includes one or more second valves configured to control a flow of the water into and out of the one or more insulated water jackets. | ||||||
| 14 | Subsurface thermal energy storage of heat generated by concentrating solar power | US15063359 | 2016-03-07 | US09897394B2 | 2018-02-20 | John Setel O'Donnell; Anthony Robert Kovscek |
| Techniques for subsurface thermal energy storage of heat generated by concentrating solar power enable smoothing of available energy with respect to daily and/or seasonal variation. Solar thermal collectors produce saturated steam that is injected into a producing or wholly/partially depleted oil reservoir that operates as a heat storage reservoir. Some of the saturated steam generated by the collectors is optionally used to generate electricity. Heat is withdrawn from the reservoir as saturated steam and is used to operate an active thermal recovery project (such as a producing thermally enhanced oil reservoir) and/or to generate electricity. Withdrawn heat is optionally augmented by heat produced by firing natural gas. The reservoir is optionally one that has been used for thermally enhanced oil recovery and thus is already warm, minimizing heat losses. | ||||||
| 15 | HYDRAULIC DRIVES FOR USE IN CHARGING SYSTEMS, BALLAST SYSTEMS, OR OTHER SYSTEMS OF UNDERWATER VEHICLES | US15173214 | 2016-06-03 | US20170349252A1 | 2017-12-07 | Gregory W. Heinen |
| An apparatus includes first and second tanks each configured to receive and store a refrigerant under pressure. The apparatus also includes at least one generator configured to receive flows of the refrigerant between the tanks and to generate electrical power based on the flows of the refrigerant. The apparatus further includes first and second hydraulic drives associated with the first and second tanks, respectively. Each hydraulic drive includes a first piston within the associated tank, a channel fluidly coupled to the associated tank and configured to contain hydraulic fluid, and a second piston within the channel and configured to move within the channel in order to vary an amount of the hydraulic fluid within the associated tank and vary a position of the first piston within the associated tank. The channel of each hydraulic drive has a cross-sectional area that is less than a cross-sectional area of the associated tank. | ||||||
| 16 | MODIFIED CO2 CYCLE FOR LONG ENDURANCE UNMANNED UNDERWATER VEHICLES AND RESULTANT CHIRP ACOUSTIC CAPABILITY | US15091415 | 2016-04-05 | US20170283021A1 | 2017-10-05 | Gregory W. Heinen |
| A carbon dioxide cycle power generation system includes storage collectively storing portions of carbon dioxide liquid and gas and a transfer connection selectively directing flow of the carbon dioxide through a turbine. The system cycles between different seawater depths in order to employ at least one of seawater pressure and seawater temperature in creating the carbon dioxide flow. Inlet/outlet control valves on variable volume tanks, positioned below movable pistons within the respective tank, selectively allow seawater into or out of a lower portion of the respective tank below the piston to pressurize the carbon dioxide therein relative to the carbon dioxide within the other tank when at depth rather than near the surface. Inhibited versus uninhibited heat transfer between storage portions and the seawater allows different seawater temperatures at depth and near the surface to create the carbon dioxide flow. Acoustic communications may be driven concurrent with the turbine. | ||||||
| 17 | Subsurface thermal energy storage of heat generated by concentrating solar power | US13730249 | 2012-12-28 | US09291367B2 | 2016-03-22 | John Setel O'Donnell; Anthony Robert Kovscek |
| Techniques for subsurface thermal energy storage of heat generated by concentrating solar power enable smoothing of available energy with respect to daily and/or seasonal variation. Solar thermal collectors produce saturated steam that is injected into a producing or wholly/partially depleted oil reservoir that operates as a heat storage reservoir. Some of the saturated steam generated by the collectors is optionally used to generate electricity. Heat is withdrawn from the reservoir as saturated steam and is used to operate an active thermal recovery project (such as a producing thermally enhanced oil reservoir) and/or to generate electricity. Withdrawn heat is optionally augmented by heat produced by firing natural gas. The reservoir is optionally one that has been used for thermally enhanced oil recovery and thus is already warm, minimizing heat losses. | ||||||
| 18 | CONCENTRATING CONVENTIONAL THERMAL OR THERMODYNAMIC SOLAR POWER PLANT | US14744687 | 2015-06-19 | US20150354398A1 | 2015-12-10 | Jean Rutten |
| A power plant comprises: (a) a liquid pressurising unit, (b) a Pelton turbine having a rotating shaft, (c) a duct connecting the pressurising unit to the Pelton turbine for supplying pressurised liquid to the Pelton turbine, the duct being provided with at least one injector, and (d) a generator, advantageously an alternator, capable of being driven directly by the rotating shaft of the turbine, advantageously with the interposition of a gear system. | ||||||
| 19 | METHOD FOR CONTROLLING A THERMAL POWER PLANT USING REGULATED VALVES | US14653447 | 2013-12-18 | US20150337688A1 | 2015-11-26 | Eve DUFOSSE |
| The invention relates to a method of controlling a thermal power plant for electricity generation, said power plant comprising at least one heat source (5) to supply thermal energy to a working fluid circulation circuit (1), said circuit comprising at least: a high pressure turbine (10) mechanically connected to an electricity generator (6), a high pressure regulating valve (11) controlling the steam supply to said high pressure turbine (10) from a high pressure superheater (12) associated with a high pressure storage tank (13), the fluid supply to said high pressure storage tank (13) from a high pressure steam generator (15) being controlled by a high pressure supply valve (14), and, in response to a need for additional electrical power, the opening of the high pressure regulating valve (11) is increased the opening of the high pressure supply valve (14) is reduced. | ||||||
| 20 | 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. | ||||||
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