公开(公告)号：US09413290B2

公开(公告)日：2016-08-09

申请号：US14364062

申请日：2012-12-14

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES S.A.

Inventor： Manuel Gil Ortega Linares ,  Francisco Rodríguez Rubio ,  Manuel Guerrero Cano ,  Pablo Noriega Gil

IPC: G01R31/40 ,  F24J2/38 ,  G01S3/786 ,  H01L31/02 ,  H01L31/042 ,  H01L31/052 ,  F24J2/10 ,  F24J2/40

CPC classification number: H02S50/00 ,  F24S23/70 ,  F24S50/20 ,  F24S50/80 ,  G01S3/7861 ,  H01L31/02021 ,  H01L31/042 ,  H01L31/052 ,  H02S20/32 ,  H02S50/10 ,  Y02E10/47 ,  Y02E10/50

Abstract: The invention relates to a suitable control method for a system of photovoltaic concentration modules, which can be used to maintain the correct orientation of the modules in order to track the sun without requiring the use of positioning sensors. The sun is tracked by performing angular movements in relation to each of the degrees of freedom at given intervals, measuring the power or current supplied by the energy collection module(s). The estimation of the sun's position and the strategy for subsequent movements are determined as a function of the reading.

Abstract translation: 本发明涉及用于光伏浓缩模块系统的合适的控制方法，其可用于维持模块的正确定向以便跟踪太阳而不需要使用定位传感器。 通过以给定的间隔相对于每个自由度执行角运动来跟踪太阳，测量由能量采集模块提供的功率或电流。 太阳位置的估计和后续运动的策略被确定为读数的函数。

公开(公告)号：US20150323772A1

公开(公告)日：2015-11-12

申请号：US14409718

申请日：2013-06-18

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES, S.A.

Inventor： Lucia SERRANO GALLAR ,  Juan Pablo NUÑEZ BOOTELLO ,  Francisco José CERÓN GARCÍA

IPC: G02B19/00 ,  G02B5/10 ,  G02B5/09

CPC classification number: G02B19/0042 ,  F24S23/70 ,  F24S23/77 ,  F24S23/80 ,  F24S2020/16 ,  F24S2023/832 ,  F24S2023/87 ,  F24S2023/874 ,  F24S2023/876 ,  G02B5/09 ,  G02B5/10 ,  G02B19/0019 ,  G02B19/0023 ,  Y02E10/40

Abstract: Mixed heliostat field combining, in the same field, heliostats of different sizes and/or with different types of facets, all of them having at least one facet and being canted or not, and either having spherical, cylindrical, flat or quasi-flat (spherical with a high curvature radius) facets, such that the solar field is optimised in order to minimise shadows and blockages between heliostats, as a result of correct positioning of the heliostats in the field.

Abstract translation: 混合的定日镜场在相同的领域中组合不同尺寸的定日镜和/或具有不同类型的小平面，它们都具有至少一个小面并且是倾斜的或不是倾斜的，并且具有球形，圆柱形，扁平或准平坦（ 球形，具有高曲率半径）小面，使得太阳能场被优化，以便最小化定日镜之间的阴影和阻塞，这是由于定日镜在现场的正确定位的结果。

公开(公告)号：US20130333690A1

公开(公告)日：2013-12-19

申请号：US14001949

申请日：2012-02-28

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES, S.A.

Inventor： Francisco Jose Ceron Garcia ,  Emiliano Cornago Ramirez

IPC: F24J2/54

CPC classification number: F24S30/458 ,  F24S25/12 ,  Y02E10/47

Abstract: Solar tracker comprising a pedestal (1) upon which a structural support (10) is fixed for a reflective surface (15), which comprises: a fixed base (2) anchored to the floor, which comprises a flat upper surface (7) with an opening, a vertical axis mechanical rotation element (3) arranged in the opening of the flat surface (7) of the fixed base (2) and fixed to the pedestal (1) and an azimuthal rotation actuator cylinder (4) of the structural support (10), comprising a first end fixed to the floor by an anchoring means (16, 2) and a second end fixed to the mechanical rotation element (3) by fixation means, the mechanical rotation means being configured in such a way that when the actuator cylinder carries out its movement, the mechanical rotation element transmits the rotational movement of the second end of the actuator cylinder to the pedestal (1).

Abstract translation: 太阳能跟踪器，其包括基座（1），结构支撑件（10）固定在基座（1）上，用于反射表面（15），其包括：固定到地板的固定基座（2），其包括平坦的上表面（7） 开口，设置在所述固定基座（2）的平坦表面（7）的开口中并固定到所述基座（1）的垂直轴机械旋转元件（3）和所述结构的方位旋转致动器缸（4） 支撑件（10），包括通过固定装置（16,2）固定到地板的第一端和通过固定装置固定到机械旋转元件（3）的第二端，所述机械旋转装置被构造成使得 当致动器气缸执行其运动时，机械旋转元件将致动器气缸的第二端的旋转运动传递到基座（1）。

公开(公告)号：US10221477B2

公开(公告)日：2019-03-05

申请号：US15024515

申请日：2014-09-29

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES, S.A.

Inventor： Guillermo Espinosa Rueda ,  Noelia Martinez Sanz ,  Agustín Rodríguez González-Elipe ,  Pedro Castillero Durán ,  Ángel Barranco Quero ,  Francisco Yubero Valencia ,  Juan Pedro Espinos Manzorro ,  José Cotrino Bautista ,  Francisco García García

IPC: C23C14/35 ,  C23C14/58 ,  G01N33/00 ,  G01N21/78 ,  C23C14/08 ,  C23C14/22 ,  G01N31/22

Abstract: A method is provided for producing a visual hydrogen sensor and to a sensor produced in this manner, the sensor allowing the presence of hydrogen gas in a medium to be detected by the naked eye as a result of a change of color in the sensor. The method involves the deposition of thin porous layers of oxides that do not absorb visible light in their completely oxidized state which become colored when they are partially reduced. This deposition is carried out using vapor phase deposition (PVD) in a glancing angle configuration (GLAD). The method also involves the preparation of a solution of an active metal precursor capable of dissociating the hydrogen molecule and a carrier vector and the deposition of this solution on the oxide layer in order to incorporate a minimum quantity of active metal within the pores of the oxide layer in the form of nanoparticles.

公开(公告)号：US09216435B2

公开(公告)日：2015-12-22

申请号：US13758415

申请日：2013-02-04

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES, S.A.

Inventor： José María Delgado Sánchez ,  Emilio Sánchez Cortezon ,  Pedro Atienzar Corvillo ,  Ana Maria Primo Arnau ,  Hermenegildo García Gómez

IPC: C01B31/00 ,  B05D5/12 ,  H01B1/04 ,  C01B31/04 ,  B82Y30/00 ,  B82Y40/00

CPC classification number: B05D5/12 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/184 ,  C01P2006/40 ,  H01B1/04 ,  Y10T428/265 ,  Y10T428/30

Abstract: The present invention describes a method for the preparation of graphene or graphenic material films by the carbonization of biopolymers.The method comprises the following stages: preparation of an aqueous solution of a non-crystallizable water-soluble biopolymer or a derivative of said biopolymer at the suitable pH, coating of the substrate with the aqueous solution of the biopolymer prepared in the previous stage by immersion of the substrate in said solution or by using the spin coating technique, conditioning of the aqueous solution of the biopolymer by means of a hydrothermal process consisting of subjecting the coated surface to a flow of nitrogen saturated with water vapor at the temperature of between 100 and 250° C. for a time between 30 minutes and several hours, thermal decomposition of the biopolymer deposited on the substrate in the absence of oxygen at temperatures below 1200° C.

Abstract translation: 本发明描述了通过生物聚合物的碳化制备石墨烯或石墨烯材料膜的方法。 该方法包括以下阶段：在合适的pH下制备不可结晶的水溶性生物聚合物的水溶液或所述生物聚合物的衍生物，通过浸渍在前一步骤中制备的生物聚合物的水溶液涂覆基底 或通过使用旋涂技术，通过水热法调节生物聚合物的水溶液，所述水热法是将涂覆的表面经受水蒸汽饱和的氮气流在100〜 250℃在30分钟至几小时之间的时间内，在低于1200℃的温度下在不存在氧的情况下沉积在基底上的生物聚合物热分解

公开(公告)号：US20150357966A1

公开(公告)日：2015-12-10

申请号：US14655275

申请日：2013-12-18

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES, S.A.

Inventor： Pablo Noriega Gil ,  Jose Antonio Perez Garcia De Castro

IPC: H02S20/32 ,  G05B13/04 ,  G06F17/10

CPC classification number: H02S20/32 ,  F24S30/45 ,  F24S50/20 ,  F24S2050/25 ,  G01S3/7861 ,  G05B13/041 ,  G06F17/10 ,  Y02E10/47

Abstract: A method for determining corrections for platforms of solar trackers, which can be used to compensate mainly for azimuth deviation and the inclination of the tracker. Additional elevation corrections may also be able to be performed. A central processing unit acts on a driver, providing commands that take account of the corrections calculated to generate set values appropriate for the driver, thereby obtaining the correct orientation for the platform.

Abstract translation: 一种用于确定太阳能跟踪器平台校正的方法，其可以用于主要补偿方位偏差和跟踪器的倾斜度。 还可以执行附加的高程校正。 中央处理单元作用于驱动器，提供考虑到所校正的命令，以生成适合于驾驶员的设定值，从而获得平台的正确方位。

公开(公告)号：US20150298083A1

公开(公告)日：2015-10-22

申请号：US14647787

申请日：2013-11-28

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES, S.A.

Inventor： Salvador VALENZUELA RUBIO ,  Hipólito LOBATO SÁNCHEZ ,  Miguel TRIGUEROS GONZÁLES ,  Miguel Ángel CRUZ ROMERO ,  Cristina PRIETO RIOS

IPC: B01F15/06 ,  C09K5/10 ,  B01F15/00 ,  B01F3/12 ,  B01F15/02

CPC classification number: B01F15/06 ,  B01F3/12 ,  B01F13/0032 ,  B01F15/00396 ,  B01F15/0243 ,  B01F15/065 ,  B01F2015/062 ,  C09K5/10

Abstract: The invention relates to a portable mixing platform for producing a heat-transfer fluid on site and on an industrial scale, said fluid consisting of a eutectic mixture of diphenyl (DP) and diphenyl oxide (DPO). The platform includes a device that stores DPO in liquid state, a device for supplying DP in solid state, a mixing device in which both components are mixed in liquid state and in the right amount for forming a eutectic mixture, and a device for inerting and treating gases which maintains the DPO and mixing devices under inert atmosphere, as well as drawing the gases vented from both devices to pass said gases through an activated-carbon filter prior to expelling same into the atmosphere. The present invention also relates to the method for producing the eutectic mixture of DP and DPO using the described portable mixing platform.

Abstract translation: 本发明涉及用于在现场和工业规模上生产传热流体的便携式混合平台，所述流体由二苯基（DP）和二苯基氧化物（DPO）的共晶混合物组成。 该平台包括将DPO储存在液态中的装置，用于以固态供给DP的装置，混合装置，其中两种成分以液态混合，并以合适的量混合形成共晶混合物;以及装置，用于惰化和 处理在惰性气氛下维持DPO和混合装置的气体，以及从两个装置排出的气体，以便在将其排入大气之前将所述气体通过活性炭过滤器。 本发明还涉及使用所述便携式混合平台来生产DP和DPO的共晶混合物的方法。

公开(公告)号：US20150241135A1

公开(公告)日：2015-08-27

申请号：US14433574

申请日：2013-10-03

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES, S.A.

Inventor： Aleix Jove Llovera ,  Cristina Prieto Rios

IPC: F28D20/00

CPC classification number: F28D20/0034 ,  F01K3/00 ,  F22B1/028 ,  F22B1/10 ,  F22B33/18 ,  F28D7/16 ,  F28D20/021 ,  F28D2021/0061 ,  F28F9/0275 ,  Y02E60/145

Abstract: Thermal storage system and its charging and discharging process using a heat-transfer fluid. The system includes a phase change storage material contained in a casing that is penetrated by heat exchanger tubes (3), preferably vertical ones, connected at their lower end with at least one lower chamber (62) via lower sub-chambers (62′) which include a series of injectors (9) for enabling the heat-transfer fluid to be inserted in gas form; at the upper end, these tubes (3) connect via upper sub-chambers (61′) with at least one upper chamber (61) which in turn is connected to a boiler (1) from which downpipes (8) extend via which heat-transfer fluid in liquid form circulates, located outside of the casing, connecting the aforementioned boiler (1) to the lower chamber (62), which enables the natural circulation of the heat-transfer fluid within the system.

Abstract translation: 热存储系统及其使用传热流体的充放电过程。 该系统包括：壳体内的相变储存材料，该相变储存材料通过下部分室（62'）在其下端与至少一个下室（62）连接的热交换器管（3）穿透，优选垂直的， 其包括用于使得传热流体能够以气体形式插入的一系列喷射器（9）; 在上端，这些管（3）经由上部副室（61'）与至少一个上部室（61）连接，上部室（61）又连接到锅炉（1），水管（8）从该室 液体形式的转移流体位于壳体外部循环，将上述锅炉（1）连接到下部室（62），从而能够使系统内的传热流体自然循环。

公开(公告)号：US20150152239A1

公开(公告)日：2015-06-04

申请号：US14412334

申请日：2013-07-03

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES, S.A.

Inventor： Núria Guilera Grandes ,  Laura López García ,  Laia Francesch De Castro ,  José María Delgado García ,  Emilio Sánchez Cortezón

IPC: C08K3/28 ,  C09D129/04 ,  C09D139/06 ,  C08K5/06 ,  C09D133/02

CPC classification number: C08K3/28 ,  B82Y30/00 ,  C01B21/0728 ,  C01P2004/62 ,  C01P2004/64 ,  C01P2006/22 ,  C08K5/06 ,  C08K2003/282 ,  C09D129/04 ,  C09D133/02 ,  C09D139/06 ,  H01L31/03923 ,  Y02E10/541

Abstract: The present invention relates to formulations comprising aluminum nitride nanoparticles, at least one dispersant and at least one aqueous solvent, to the method for obtaining said formulations as well as to their use for obtaining a leveling barrier layer.

Abstract translation: 本发明涉及包含氮化铝纳米颗粒，至少一种分散剂和至少一种含水溶剂的制剂，用于获得所述制剂的方法以及其用于获得流平屏障层的制剂。

公开(公告)号：US10514530B2

公开(公告)日：2019-12-24

申请号：US14409718

申请日：2013-06-18

Applicant: ABENGOA SOLAR NEW TECHNOLOGIES, S.A.

Inventor： Lucia Serrano Gallar ,  Juan Pablo Nuñez Bootello ,  Francisco José Cerón García

IPC: G02B19/00 ,  G02B5/09 ,  G02B5/10 ,  F24S23/70 ,  F24S23/77 ,  F24S20/00

Abstract: Mixed heliostat field combining, in the same field, heliostats of different sizes and/or with different types of facets, all of them having at least one facet and being canted or not, and either having spherical, cylindrical, flat or quasi-flat (spherical with a high curvature radius) facets, such that the solar field is optimised in order to minimise shadows and blockages between heliostats, as a result of correct positioning of the heliostats in the field.