子分类:
- F24J1/00: 利用放热化学反应,而非利用燃烧产生热的设备或装置(用于烹调器的入A47J36/28;自加热并入A61F {A61F7/04C};采用通过不可逆化学反应,而非通过燃烧产生热或冷的材料入C09K5/18)
- F24J2/00: 太阳热的利用,例如太阳能集热器(利用太阳能蒸馏或蒸发水入C02F 1/14;利用太阳能产生机械动力的装置入F03G 6/00;专门适用于把太阳能转换成电能的半导体器件入H01L31/00;结合有热能利用装置的光伏电池入H01L31/0525;结合有热能利用装置的光伏模块入H02S40/44)
- F24J2200/00: 预测;模拟
- F24J3/00: 其他非燃烧热的产生或利用(太阳热的利用入F24J2/00)
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 281 | METHODE DE PREVISION DE LA CONSOMMATION D'EAU CHAUDE, METHODE ET SYSTEME D'OPTIMISATION DE LA PRODUCTION D'EAU CHAUDE | EP16202190 | 2016-12-05 | EP3182343A1 | 2017-06-21 | LOMET AURORE; SUARD FRÉDÉRIC; CHEZE DAVID |
| Méthode de prévision de la consommation d'eau chaude d'une résidence équipée d'un réservoir d'eau chaude comprenant : €¢ une première prévision (201) de la variabilité de la consommation d'eau chaude intra-journalière, pour chaque jour de la semaine, comprenant la recherche d'un modèle de prévision qui présente une erreur minimale avec une mesure normalisée de consommation cumulée moyenne sur une durée d'apprentissage, ledit modèle de prévision étant déterminé à l'aide d'une somme d'une pluralité de fonctions locales, €¢ une deuxième prévision (202) de la consommation d'eau chaude journalière, €¢ une troisième prévision (203) de la consommation d'eau chaude intra-journalière, pour chaque jour de la semaine, à partir d'une combinaison de la première prévision et de la deuxième prévision. | ||||||
| 282 | MOUNTING BRACKET ASSEMBLIES AND METHODS | EP14851397 | 2014-09-29 | EP3052817A4 | 2017-06-21 | WILLIAMSON JOHN N; MCLANE KALEB W; CORIO RONALD P |
| A mounting bracket assembly comprises a flexible body including at least one top member and a flexible angled bottom member connected to the top member. The flexible body defines a beam insertion aperture between the top member and the bottom member. The mounting bracket assembly further comprises at least one clamp attached to the top member. The mounting bracket assembly may further comprise a threaded rod running through the at least one top member and a clamping nut securing the threaded rod to the top member such that rotating the clamping nut compresses the top member and grounds an electricity generating device such as a photovoltaic module. The mounting bracket assembly may further comprise an integral grounding device disposed adjacent the top member to electrically ground the electricity generating device. | ||||||
| 283 | MODULAR UNIT FOR ATTACHMENT TO SOLAR PANEL | EP14845649 | 2014-09-16 | EP3047525A4 | 2017-06-21 | WEBB ROGER; WEBB MARIA |
| A modular unit attached to a solar panel. The modular unit comprises a heat exchanger having an inlet manifold and an outlet manifold and a plurality of spaced apart galleries extending there between, a plurality of thermoelectric modules disposed between the galleries and a plurality of heat sink tiles, the thermoelectric modules bonded to the heat sink tiles and clamped into abutment with the galleries. In use the modular unit is attached to the solar panel by bonding said heat sink tiles to said solar panel. | ||||||
| 284 | DERIVING ECONOMIC VALUE FROM WASTE HEAT FROM CONCENTRATED PHOTOVOLTAIC SYSTEMS | EP11833397 | 2011-10-13 | EP2628189A4 | 2017-06-21 | KIESEWETTER DOUGLAS |
| A method and apparatus for capturing solar energy for use with a structure. A solar energy system collects solar energy, some of which is converted into electricity and some of which is stored in subterranean thermal banks. Waste heat is formed in solar cells during the conversion of solar energy into electricity. A fluid flow system is provided that transfers heat from the solar cells into a subterranean formation via wellbores that penetrate the subterranean formation. The heat remains in the formation and is selectively transferred to the structure through the fluid flow system. | ||||||
| 285 | LIGHT COLLECTION SYSTEM AND METHOD | EP10774641 | 2010-05-13 | EP2430741A4 | 2017-06-21 | SALOMON YAIR |
| The present invention is directed to light collection systems, the system comprising at least one light receiving element, selected from the group consisting of: a window, a photovoltaic element, a heating element, a light guiding element and combinations thereof, and at least one light reflector-deflector element, each element comprising a front light receiving surface, a rear surface, and a transparent volume, disposed between the front light receiving surface and the rear surface, the transparent layer being of a higher refractive index than of its surrounding, wherein the transparent volume comprises an asymmetric pattern which is configured to at least partially reflect light by internal reflection and direct the light within the element, reflect some light off said front light receiving surface, reflect, deflect and guide light within the light reflector-deflector element; and direct light through the front light receiving surface towards the at least one light receiving element. | ||||||
| 286 | BROADBAND REFLECTORS, CONCENTRATED SOLAR POWER SYSTEMS, AND METHODS OF USING THE SAME | EP09836987 | 2009-12-21 | EP2382427A4 | 2017-06-21 | HEBRINK TIMOTHY J; CLEAR SUSANNAH C; GILBERT LAURENCE R; WEBER MICHAEL F; YU TA-HUA; CHEN DANIEL TING-YUAN; SHERMAN AUDREY A |
| Broadband reflectors include a UV-reflective multilayer optical film and a VIS/IR-reflective layer. In various embodiments, the VIS/IR reflective layer may be a reflective metal layer or a multilayer optical film. Concentrated solar power systems and methods of harnessing solar energy using the broadband reflectors and optionally comprising a celestial tracking mechanism are also disclosed. | ||||||
| 287 | DEVICE AND METHOD FOR ENERGY WELL | EP10797375 | 2010-06-18 | EP2452136A4 | 2017-06-14 | KHARSEH MOHAMAD; OSSIANSSON WILLY |
| Method for increasing efficiency during heating or cooling using an energy well (1) in the form of an elongated hole the bottom of which is arranged at a greater depth than its opening, where a cooling agent streams through the well (1) in a collector conduit (3) and is heat exchanged against the material surrounding the well (1). The invention is characterised in that a tube (301) runs down into the energy well (1) from above its opening and down along the energy well (1) towards its bottom, in that the end (303) of the tube (301) facing towards the bottom of the energy well (1) is open, in that liquid is supplied through the tube (301) so that the liquid thereby streams down and out into the energy well (1) through the open end (303) of the tube (301), in that gas bubbles (305) are supplied to the liquid streaming down through the tube (301), and in that the added gas bubbles (305) are so small so that they rise more slowly in the liquid than the velocity of the liquid at the supply point. | ||||||
| 288 | HEAT RECEIVER TUBE, METHOD FOR MANUFACTURING THE HEAT RECEIVER TUBE, SOLAR COLLECTOR WITH THE HEAT RECEIVER TUBE AND METHOD FOR PRODUCING ELECTRICITY BY USING THE SOLAR COLLECTOR | EP15192558 | 2015-11-02 | EP3163212A1 | 2017-05-03 | KLAPWALD SHMULIK |
| Heat receiver tube (1) for absorbing solar energy and for transferring absorbed solar energy to a heat transfer fluid (111) which can be located inside of at least one core tube (11) of the heat receiver tube (1) is provided. The core tube (11) comprises a core tube surface (112) with at least one solar energy absorptive coating for absorbing solar radiation (2). The core tube (11) is enveloped by at least one enveloping tube (10). The enveloping tube (10) comprises at least one enveloping tube wall (101) which is at least partly transparent for the solar radiation (2). The enveloping tube wall (101) comprises at least one inner enveloping tube surface (102). The core tube (11) and the enveloping tube (10) are coaxially arranged to each other such that an inner heat receiver tube space (3) is formed which is bordered by the core tube surface (112) and the inner enveloping tube surface (102). The heat receiver tube (1) comprises at least one pressure adapting device (4) for adapting a space pressure of the inner heat receiver tube space (3). | ||||||
| 289 | TORQUE TRANSFER IN LATERALLY ENGAGING DRIVE COUPLERS EXHIBITING AXIAL MISALIGNMENT WITH DRIVEN COUPLERS | EP14822976 | 2014-07-09 | EP3019761A4 | 2017-05-03 | FUKUBA DANIEL I; SUMERS BENJAMIN D; DITTMER JEREMY P; JENKINS MERRITT J; CHU KEVIN C; RUIZ VAYARDO L |
| The present invention relates to transferring torque between a first unit, which is typically a mobile machine or a robot, and a second unit, which is typically a fixed or stationary machine. The units are arranged such that a drive coupler of the first unit designed for delivering torque about a drive axis can engage the driven coupler, which belongs to the second unit and has a driven axis, along an engagement direction that is nearly perpendicular to the direction of the driven axis. A lateral displacement mechanism in provided is the first unit to achieve a first-order coaxial alignment between the drive and driven axes. Additional measures such as compliance mechanisms are provided for improving engagement, coupling and reducing the level of axial misalignment in the apparatus and methods of the invention. | ||||||
| 290 | SYSTEM ZUM BEFESTIGEN VON MONTAGESCHIENEN | EP14758478 | 2014-05-15 | EP2997315B1 | 2017-05-03 | SCHMID BERNHARD |
| 291 | HELIOSTAT REPOSITIONING SYSTEM AND METHOD | EP11787524 | 2011-05-27 | EP2577183A4 | 2017-05-03 | CURRIER THOMAS |
| A system and method for providing real time control of a heliostat array or CPV/PV module that reduces actuation cost, the disclosure reduces the fixed cost of calibrating and repositioning an individual surface. This simultaneously removes the core engineering assumption that drives the development of large trackers, and enables a system and method to cost effectively track a small surface. In addition to lower initial capital cost, a small heliostat or solar tracker can be pre-assembled, mass-produced, and shipped more easily. Smaller mechanisms can also be installed with simple hand tools and do not require installers to rent expensive cranes or installation equipment. | ||||||
| 292 | VERSATILE UNFOLDING SOLAR DEPLOYMENT SYSTEM | EP11735182 | 2011-01-20 | EP2526617A4 | 2017-05-03 | CURRAN SEAMUS; MORGAN NATHANIEL; ALLEY NIGEL |
| A versatile solar deployment system may provide one or more scalable solar deployment units. A solar deployment unit may include a chassis, a panel support provided by the chassis, and one or more solar panels coupled to the panel support, wherein the solar panels are folded together in an undeployed position, and the solar panels are unfolded in a deployed position. Alternatively, a solar deployment unit may include a rolling mechanism providing a rotating shaft and a flexible panel. One end of the flexible panel is secured to the rotating shaft, the flexible panel is rolled around the rotating shaft to retract the flexible panel into an undeployed position, and the flexible panel is unrolled to deploy the flexible panel into a deployed position. | ||||||
| 293 | SYSTEMS AND METHODS OF GENERATING ENERGY FROM SOLAR RADIATION | EP14842519 | 2014-09-03 | EP3042134A4 | 2017-04-26 | KING JOHN D H; KRAMER NICHOLAS A; TANG ERIK E; OLSEN KRISTOFER J |
| A solar reflector assembly is provided for generating energy from solar radiation. The solar reflector assembly is configured to be deployed on a supporting body of liquid and to reflect solar radiation to a solar collector. The solar reflector assembly has an elongated tube having an inner portion to facilitate liquid ballast, made of semi-rigid material and a flat section built into a wall of the tube or attached to the wall of the tube. A reflective material attached to said flat section of the wall of the tube to reflect solar radiation. The elongated tube has an axis of rotation oriented generally parallel to a surface of a supporting body of liquid. The elongated tube may be elastically or plastically deformed by application of a torque along its length, so as to bring flat-surface normal vectors at each end of the tube largely into alignment with each other. | ||||||
| 294 | A TERRAIN COMPLIANT, ECO-FRIENDLY, MODULAR BALLAST SYSTEM WITH OPTIONAL INTEGRATED WIRE MANAGEMENT AND RACKING SYSTEM | EP14845630 | 2014-09-18 | EP3047217A4 | 2017-04-19 | MANDRY JAMES E; PELLETIER MARK; BOURQUE RAYMOND M |
| A modular ballast system for supporting objects uses tubing such as pipes of appropriate size for the required ballast. Once in place, the empty pipes are filled with a watery mix (slurry) of sand, silt, gravel, soil, cement or other generally available material to generate a majority of the ballast weight. A two piece clamping mechanism provides fixed placement attachment points suitable for attachment by supported structures. The lower piece of the clamping mechanism sits under the ballast tubing and is designed to both support and disperse the anticipated weight of the objects with minimal impact on the surface beneath it. The upper piece of the clamping mechanism mates to the lower clamping piece and completes a full 360 degree collar around the ballast tubing to create a durable clamping mechanism that both captures the weight and position of the ballast tubing and prevents the ballast tubing from shifting. | ||||||
| 295 | REFLECTING MIRROR FOR SOLAR LIGHT COLLECTION | EP14749492 | 2014-01-22 | EP2955549A4 | 2017-04-19 | UEKI SHIKI |
| The purpose of the present invention is to provide a reflecting mirror for solar light collection having excellent scratch resistance as well as excellent ease of installation and release. This reflecting mirror for solar light collection has a resin substrate, a polygonal film mirror for solar light collection having a metal reflecting layer and a surface coating layer, and a frame-shaped support member for supporting a peripheral edge part of the film mirror. | ||||||
| 296 | SLATE STYLE ROOFING SYSTEM WITH INTEGRATED SOLAR PANELS | EP11757042 | 2011-03-18 | EP2547837A4 | 2017-04-19 | SUDHIR RAILKAR; CHICH ADEM; BECK DOUGLAS |
| A roofing system includes battens and hangers for installing slate roofing shingles on a roof. Electrical conductors and other electronics are incorporated into the battens and the battens are connected together to form an electrical transmission grid beneath the shingles. Solar panels are installed in place of slate shingles in some locations on the roof and are configured to match or complement the surrounding slate shingles. Each solar panel includes a connector that connects the solar panel to the electrical transmission grid. The grid thus collects the electrical energy generated by all of the solar panels and delivers it for storage or use in a home. Microinverters may be coupled to smaller groups of the solar panels for converting their DC voltage to AC voltage and the outputs of the microinverters connected to a remote location for use or storage. | ||||||
| 297 | SOLAR ENERGY COLLECTOR AND SYSTEM FOR USING SAME | EP14849936 | 2014-05-20 | EP3052868A4 | 2017-03-29 | IM DO SUN |
| A solar energy collector includes a first member having a cavity and a longitudinal axis. The first member has a longitudinal window forming a part thereof and a body forming another part thereof. The longitudinal window is made of a material adapted to be transparent to solar radiation. The body has an exterior absorptive surface and an interior reflective surface. A second member is located within the cavity of the first member and is generally parallel to longitudinal axis of the first member. The second member is adapted to carry an energy absorbing fluid. An insulative material fills the cavity between the first member and the second member. A solar energy collection system includes the form going solar energy collector and a solar energy transmitting device for directing solar energy through the window of the collector. | ||||||
| 298 | CONCENTRATING DAYLIGHT COLLECTOR | EP11816893 | 2011-08-09 | EP2603933A4 | 2017-03-29 | FREIER DAVID G; CORRIGAN THOMAS R |
| The disclosure generally relates to concentrating daylight collectors, and in particular to concentrating daylight collectors useful for interior lighting of a building. The concentrating daylight collectors generally include a plurality of moveable reflective vanes and a Cassegrain-type concentrator section. | ||||||
| 299 | FLUID HEATER | EP15827258 | 2015-07-28 | EP3049733A4 | 2017-03-22 | ROSSI ANDREA |
| An apparatus for heating fluid includes a tank for holding fluid to be heated, and a fuel wafer in fluid communication with the fluid. The fuel wafer includes a fuel mixture including reagents and a catalyst, and an electrical resistor or other heat source in thermal communication with the fuel mixture and the catalyst. | ||||||
| 300 | SYSTEM AND METHOD OF USING GRAPHENE ENRICHED PRODUCTS FOR DISTRIBUTING HEAT ENERGY | EP14843369 | 2014-08-21 | EP3044530A4 | 2017-03-08 | BHARGAVA MANOJ |
| A system and method of using GEPs to conduct and distribute heat energy. The system includes at least one heat energy source, at least one GEP, a system for extracting heat energy through the GEP, and a system for distributing the heat energy extracted through the GEP. The present invention can include a variety of heat sources including geothermal, solar, nuclear, chemical, magmatic, or electrical energy. The present invention can include a variety of devices to engage the heat source. The present invention can also include a variety of conduits upon which graphene is applied or combined to form GEPs. The system for extracting heat energy can include a variety of devices, such as heat exchangers, boilers, turbines, thermocouples, or thermoelectric generators. The system for distributing heat energy can include a computer controlled manifold or regulator for dividing the heat energy extracted through the heat source. The system for distributing heat energy can include a variety of devices for converting the heat energy into other forms of energy including electricity, steam, mechanical, potential, kinetic, elastic, conduction, convection, chemical, nuclear, or incandescence. | ||||||
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