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    • 2. 发明授权
    • Devices, methods, and systems for control of heliostats
    • 用于控制定日镜的装置,方法和系统
    • US08739775B2
    • 2014-06-03
    • US12867552
    • 2009-02-17
    • Gil KroyzerRotem Hayut
    • Gil KroyzerRotem Hayut
    • F24J2/38
    • F24S50/20F24S20/20F24S50/00F24S2023/87F24S2201/00G05B13/028G05B15/02H01L31/0547Y02E10/41Y02E10/47Y02E10/52
    • Adherence to flux or resultant measurable parameter limits, ranges, or patterns can be achieved by directing heliostat mounted mirrors to focus on aiming points designated on the surface of a solar receiver. Different heliostats can be directed to different aiming points, and a heliostat can be directed to different aiming points at different times. The cumulative flux distribution resulting from directing a plurality of heliostats to any aiming point on a receiver surface can be predicted by using statistical methods to calculate the expected beam projection for each individual heliostat or alternatively for a group of heliostats. Control of the heliostats in a solar power system can include designating aiming points on a receiver from time to time and assigning heliostats to aiming points from time to time in accordance with an optimization goal.
    • 可以通过将定日镜安装的反射镜聚焦在指定在太阳能接收器表面上的瞄准点上来实现对通量或合成的可测量参数限制,范围或图案的依从性。 不同的定日镜可以针对不同的瞄准点,并且定日镜可以在不同的时间被定向到不同的瞄准点。 可以通过使用统计方法来计算每个单独定日镜的预期波束投影,或者替代一组定日镜,来预测将多个定日镜引导到接收器表面上的任何瞄准点所导致的累积通量分布。 太阳能发电系统中的定日镜的控制可以包括不时地指定接收器上的瞄准点,并且根据优化目标将定日镜定时地定向到瞄准点。
    • 3. 发明申请
    • SOLAR ENERGY STORAGE SYSTEM INCLUDING THREE OR MORE RESERVOIRS
    • 太阳能储存系统,包括三个或更多的储存
    • US20130307273A1
    • 2013-11-21
    • US13977691
    • 2011-11-29
    • Leon AfremovGideon Goldwine
    • Leon AfremovGideon Goldwine
    • H02K7/18
    • H02K7/18F03G6/02Y02E10/46
    • A first period may be characterized by relatively high insolation, while a second period may be characterized by relatively low insolation. At the first period, steam is generated using insolation. A portion of the steam produces electricity, while a second portion of the steam is directed to a heat exchanger in thermal communication with thermal reservoirs. A storage fluid is flowed through the heat exchanger from a first reservoir to a second reservoir and/or from the second reservoir to a third reservoir such that enthalpy in the steam second portion is transferred to the storage fluid. At a second period, the storage fluid is reverse-flowed through the heat exchanger from the third to the second reservoir and/or from the second to the first reservoir such that enthalpy in the storage fluid generates steam to produce electricity. Enthalpy during high insolation periods can thus be stored for use during low insolation periods.
    • 第一时期的特征可以是相对较高的日晒,而第二时期的特征可以是日照相对较低。 在第一个时期,使用日晒产生蒸汽。 蒸汽的一部分产生电力,而蒸汽的第二部分被引导到与热储存器热连通的热交换器。 存储流体通过热交换器从第一储存器流到第二储存器和/或从第二储存器流到第三储存器,使得蒸汽第二部分中的焓被转移到储存流体。 在第二时段,存储流体通过热交换器从第三储存器和/或从第二储存器反向流动,使得存储流体中的焓产生蒸汽以产生电力。 因此,在高日照期间的焓值可以在低日照期间储存使用。
    • 4. 发明授权
    • Solar receiver with energy flux measurement and control
    • 具有能量通量测量和控制的太阳能接收器
    • US08360051B2
    • 2013-01-29
    • US12269793
    • 2008-11-12
    • Yoel GilonGil KroyzerRotem Hayut
    • Yoel GilonGil KroyzerRotem Hayut
    • F24J2/38
    • F24S50/00F24S20/20F24S23/77F24S50/20Y02E10/41Y02E10/47
    • A solar energy collection system has a solar receiver with an external surface configured for high absorption of light incident thereon. The solar receiver also has a plurality of light-reflecting elements arranged on the external surface. The light-reflecting elements produce at least partially diffuse reflection of light energy incident thereon. Heliostats concentrate solar radiation onto the external surface of the solar receiver. An imaging device provides a digital image of at least a portion of the external surface of the solar receiver. A controller can control the heliostats in response to apparent brightness of the light-reflecting elements as represented in the digital image.
    • 太阳能收集系统具有太阳能接收器,该太阳能接收器具有被配置为高吸收入射到其上的光的外表面。 太阳能接收器还具有布置在外表面上的多个光反射元件。 光反射元件至少部分地漫反射入射到其上的光能。 日光灯将太阳辐射集中在太阳能接收器的外表面上。 成像装置提供太阳能接收器的外表面的至少一部分的数字图像。 控制器可以响应于数字图像中所示的光反射元件的表观亮度来控制定日镜。
    • 5. 发明申请
    • DEVICES, METHODS, AND SYSTEMS FOR CONTROL OF HELIOSTATS
    • 用于控制HELIOSTATS的设备,方法和系统
    • US20110036343A1
    • 2011-02-17
    • US12867552
    • 2009-02-17
    • Gil KroyzerRotem Hayut
    • Gil KroyzerRotem Hayut
    • F24J2/38F24J2/00F24J2/40
    • F24S50/20F24S20/20F24S50/00F24S2023/87F24S2201/00G05B13/028G05B15/02H01L31/0547Y02E10/41Y02E10/47Y02E10/52
    • Adherence to flux or resultant measurable parameter limits, ranges, or patterns can be achieved by directing heliostat mounted mirrors to focus on aiming points designated on the surface of a solar receiver. Different heliostats can be directed to different aiming points, and a heliostat can be directed to different aiming points at different times. The cumulative flux distribution resulting from directing a plurality of heliostats to any aiming point on a receiver surface can be predicted by using statistical methods to calculate the expected beam projection for each individual heliostat or alternatively for a group of heliostats. Control of the heliostats in a solar power system can include designating aiming points on a receiver from time to time and assigning heliostats to aiming points from time to time in accordance with an optimization goal.
    • 可以通过将定日镜安装的反射镜聚焦在指定在太阳能接收器表面上的瞄准点上来实现对通量或合成的可测量参数限制,范围或图案的依从性。 不同的定日镜可以针对不同的瞄准点,并且定日镜可以在不同的时间被定向到不同的瞄准点。 可以通过使用统计方法来计算每个单独定日镜的预期波束投影,或者替代一组定日镜,来预测将多个定日镜引导到接收器表面上的任何瞄准点所导致的累积通量分布。 太阳能发电系统中的定日镜的控制可以包括不时地指定接收器上的瞄准点,并且根据优化目标将定日镜定时地定向到瞄准点。
    • 8. 发明授权
    • Systems, methods, and devices for operating a solar thermal electricity generating system
    • 用于操作太阳能热发电系统的系统,方法和装置
    • US09255569B2
    • 2016-02-09
    • US13695145
    • 2011-05-03
    • Gabriel KaufmannLeon AfremovYona Magen
    • Gabriel KaufmannLeon AfremovYona Magen
    • F03G6/06F03G6/00F01K13/02F02C1/05F22B1/00F22B35/08F22B35/14
    • F03G6/003F01K13/02F02C1/05F03G6/065F22B1/006F22B35/08F22B35/14Y02E10/46
    • In a startup period for a solar thermal electricity generating system, a non-solar source of steam heats a downstream receiver (for example, a superheating receiver) prior to insolation being available. Insolation, once available, heats an upstream receiver (for example, an evaporator). The upstream receiver can be arranged in a recirculation loop with a steam separation drum, which may be bypassed during the initial heating of the upstream receiver by insolation. Once sufficient temperature and pressure have been reached, steam from the upstream receiver is directed to the downstream receiver by way of the steam separation drum to replace the non-solar source of steam. Heating of the downstream receiver using steam from the upstream receiver continues until a threshold temperature and pressure are reached. Insolation is then directed at both the upstream and downstream receivers to generate steam for electricity production by a turbine.
    • 在太阳能热发电系统的启动期间,非太阳能蒸汽源在日照之前加热下游接收器(例如,过热接收器)。 一旦可用,绝热加热上游接收器(例如蒸发器)。 上游接收器可以布置在具有蒸汽分离鼓的再循环回路中,蒸汽分离鼓可以在通过日照在上游接收器的初始加热期间被旁路。 一旦已经达到足够的温度和压力,来自上游接收器的蒸汽通过蒸汽分离鼓被引导到下游接收器,以取代非太阳能蒸汽源。 使用来自上游接收器的蒸汽对下游接收器进行加热,直到达到阈值温度和压力。 然后,将上游和下游接收器的绝缘指示到涡轮机产生用于电力生产的蒸汽。
    • 10. 发明申请
    • INTEGRATED SOLAR ENERGY THERMAL STORAGE SYSTEM AND METHODS
    • 集成太阳能热存储系统及方法
    • US20130292084A1
    • 2013-11-07
    • US13873319
    • 2013-04-30
    • BRIGHTSOURCE INDUSTRIES (ISRAEL) LTD.
    • Moshe LUZAlon GANANY
    • F28D20/00
    • F28D20/00F03G6/06F24S20/20F24S23/77F24S50/00F24S2023/87F28D2020/0047Y02E10/41Y02E10/46
    • A solar energy thermal storage system can include a receiver in which a first storage medium is heated by insolation. First and second thermal storage reservoirs for a second storage medium can be provided. A first heat exchanger can be configured to transfer heat in the first storage medium to the second storage medium. A buffer tank can be located at a height above the receiver and can be fluidically connected to the first heat exchanger at its inlet and the receiver at its outlet. A second heat exchanger can be configured to transfer heat between the second storage medium and pressurized water and/or steam. The use of a buffer tank in conjunction with the first storage medium increases the overall efficiency of the system and results in a higher temperature for the thermal storage system, which can be used to generate superheated steam.
    • 太阳能热存储系统可以包括其中通过日晒来加热第一存储介质的接收器。 可以提供用于第二存储介质的第一和第二储热容器。 第一热交换器可以被配置为将第一存储介质中的热量传递到第二存储介质。 缓冲罐可以位于接收器上方的高度处,并且可以在其入口处的第一热交换器和其出口处的接收器流体连接到第一热交换器。 第二热交换器可以构造成在第二存储介质和加压水和/或蒸汽之间传递热量。 与第一存储介质一起使用缓冲罐提高了系统的整体效率,并导致用于产生过热蒸汽的储热系统的较高温度。