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 |
|---|---|---|---|---|---|---|
| 301 | IMPROVED END CLAMPS FOR SOLAR SYSTEMS | EP15755836 | 2015-02-25 | EP3111552A4 | 2017-03-01 | BRAUNSTEIN RYAN; CARRE GUILLAUME; KINYON ZACHARY |
| A solar power system can include an array of solar modules. The system can include a rail and a solar module positioned at an outer end of the array. The solar module can have a frame around a periphery of the solar module. The frame can include a flange along an edge of the solar module that is disposed at the outer end of the array. The flange can project inwardly from the frame underneath the solar module. A clamp assembly can be disposed underneath the solar module and can mechanically secure the solar module to the rail. The clamp assembly can include a clamp body and a base. The clamp body and the base can cooperate to clamp the flange between the clamp body and the rail. | ||||||
| 302 | SOLAR WATER-HEATING DEVICE | EP14795039 | 2014-05-08 | EP2994702A4 | 2017-03-01 | HOCHMUTH PETER; KUN CSABA; STRAUSZ JÁNOS |
| The invention relates to a water-heating device using solar energy that consists of two flexible elastomer foil layers (2), water guiding passages (6) are created by fixing together the two foil layers (2) along fastening lines (4, 5) at a permanent distance from each other, the passages have connecting elements serving to input and output the water at the two most distant points of the passages from the point of view of water flow. According to the invention bundles (7) are formed from the neighbouring passages (6), a single bundle (7) contains two to twelve passages (6), preferably three to eight passages (6), the ends of the passages of neighbouring bundles (7) are connected to each other with one connection passage (8) or with several arranged in parallel in such a way that the one end of the passages (6) of a given bundle (7) is connected to the ends of the passages (6) of the neighbouring bundle (7) on the one side of the given bundle (7) and the other end of the passages (6) of the given bundle (7) is connected to the ends of the passages (6) of the neighbouring bundle (7) on the other side of the given bundle (7). | ||||||
| 303 | PONDS FOR COOLING AND/OR SALT RECOVERY | EP14848039 | 2014-03-28 | EP2991931A4 | 2017-03-01 | CHINLOY DAVID R; ZHANG JIANPING; STAMATIOU EVANGELOS |
| A pond for cooling and/or recovering salt from a hot aqueous solution of a salt such as potassium chloride produced by solution mining. The pond comprises a plurality of channels arranged side-by-side, each of the channels being defined by a plurality of sides. An inlet is provided in a side of a channel for receiving the aqueous solution, and an outlet is provided in a side of another one of the channels for discharging the aqueous solution. The pond has at least one dike separating the channels from one another. A gap is formed in each dike to permit the aqueous solution to flow between the channels, the gap having a length which is about 10 to about 40 percent of the length of the sides of the channels. Salt is crystallized and the solution is cooled as it passes through the channels of the pond. | ||||||
| 304 | PLASTIC PHOTOVOLTAIC MODULE FRAME AND RACK, AND COMPOSITION FOR MAKING THE SAME | EP13888020 | 2013-06-28 | EP3013901A4 | 2017-02-08 | WU SHAOFU; HUO YANLI; GUO YONGJIN; YAO WENBIN; LIN ZHIQING; CAI JIE; CHEN BIN; QI YUDONG; DU LIBO; CHEN HONGYU |
| Photovoltaic or solar module frames, racks, or frame or rack components are made from a composition comprising (A) a thermoplastic polymer, particularly a thermoplastic polyolefin, (B) a reinforcing element, particularly glass fiber, (C) a non-halogen containing, intumescent flame retardant, (D) an impact-modifier, particularly a polyolefin elastomer, (E) a coupling agent, and, optionally, (F) one or more additives such as an antioxidant, UV-stabilizer, etc. These frames provide for easy assembly without the need for screws, bolts or other metal fasteners. | ||||||
| 305 | SINGLE AXIS SOLAR TRACKING SYSTEM | EP14798438 | 2014-04-11 | EP2997316A4 | 2017-02-08 | CORIO RONALD P |
| A solar tracking system with a plurality of tracking assemblies moved by a single motor. A method and system that prevents overloading the motor or tripping a circuit breaker due to an obstructed or impeded tracker includes sensing movement of the tracker assemblies and entering into obstruction clearing modes. Obstruction clearing mode 1 (OCM1) is a high frequency adjustable mode that prompts movement for an adjustable period of time. If movement commences, the system returns to a normal mode. If there is no movement, the system enters into an obstruction clearing mode 2 (OCM2) with is an adjustable lower frequency series of attempts. If there is no movement, no further attempts are made. Each of these steps are monitored and controlled remotely. There are two types of secure connections for drivelines, torque tubes or affixing driveline linkages for high torque conditions. | ||||||
| 306 | METHOD AND SYSTEM FOR OPTIMIZING AND PROTECTING SOLAR PANELS | EP10748248 | 2010-03-02 | EP2404124A4 | 2017-01-25 | GUILLEMETTE PASCAL |
| A system and a method for optimizing and protecting solar panels, the system comprising a driving unit, a solar panel connected to the driving unit, a micro-controller controlling movements of the driving unit, a sun tracking unit sending data about the position of the sun to the micro-controller; and a shelter receiving the solar panel when the solar under control of the microcontroller. The method comprises connecting a solar panel to a driving unit connected to a microcontroller; connecting the microcontroller to a sun tracking unit sending data about the position of the sun to the microcontroller; providing a shelter; and monitoring, by the microcontroller, the driving unit into orienting the solar panel in relation to the position of the sun by rotation about at least one axis and into moving the solar panel from a deployed operating position to a sheltered non operating position into the shelter. | ||||||
| 307 | SOLAR COLLECTOR WITH HEAT SINK | EP10831177 | 2010-11-19 | EP2503261A4 | 2017-01-18 | TORRENS RASAL JOSÉ MARÍA |
| Thermal solar collector (I), with heat sink, comprising - an upper pipe (5) and a lower pipe (13) for the heat-transfer fluid, connected by a return pipe (4), - an absorber (18) made up of multiple parallel vertical pipes (12), that connect said lower pipe (13) to said upper pipe (5), and - a heat-sink device (2) fitted with a heat exchanger (3), connected to said upper pipe (5) by means of at least one thermostat bypass valve (15) to said heat-sink device (2), to prevent overheating. The upper pipe (5) for heat-transfer fluid, the heat-sink device (2) and the thermostat bypass valve (15) are contained within a single frame (14), said upper horizontal pipe (5) and said heat-sink device (2) being arranged adjacently. The thermostat valve (15) and the heat exchanger (3) are connected by an inverted siphon (8). | ||||||
| 308 | NOVEL EXPANSION COMPENSATION DEVICE AND METHOD FOR MANUFACTURE THEREOF | EP10845612 | 2010-11-11 | EP2500672A4 | 2017-01-18 | MARTINEZ SANZ NOELIA; PEREZ ULLIVARRI JAVIER ASENSIO; BOMBIN ORTEGA PABLO JOSÉ; PELAEZ FOMBELLIDA JAVIER; RICO SANCHEZ JOSÉ ANGEL; GIRONA MONTARROSO MIGUEL ANGEL |
| Novel expansion compensation device and method for manufacture thereof, of those used in solar power absorber tubes featuring a dual bellows design where the height of the waves of the bellows is not regular, but the second wave is greater (where it supports more load) and diminishes towards the ends. With this design improving the performance of the receiver is achieved because it shortens the length of the device and consequently there is more surface area receiving solar radiation as well as it decreases the necessary diameter of glass tube and therefore its cost. | ||||||
| 309 | LIGHT-CATALYZED REACTION SYSTEM BY COLLECTING SUNLIGHT | EP14825810 | 2014-06-17 | EP3023387A4 | 2017-01-04 | CHEN YILONG; YANG QINGPING; ZHANG YANFENG |
| A light-catalyzed reaction system by collecting sunlight mainly comprises a light collector, a light conduction device, and a light transmitting reactor capable of transmitting full-spectrum rays of sunlight. The light collector is fixed at the free end of a two-degree-of-freedom bracket formed by connecting a pitching main shaft to an orientation main shaft, and the orientation main shaft and the pitching main shaft can be driven respectively by separate servo motors to relatively rotate to track the sun. Multiple layers of light-collection convex lens groups are disposed on the light collector, and converging rays formed by transmission and convergence of collected sunlight through the light conduction device are directed to the light transmitting reactor. The light transmitting reactor comprises a light transmitting cylinder and a sealing cover. The sealing cover is arranged on the light transmitting cylinder, and the light transmitting cylinder is filled with a reaction solution. The system is applied to processes of light-catalyzed hydrogen production and light-catalyzed methyl alcohol and oxygen production. | ||||||
| 310 | CHEMICAL HEAT STORAGE DEVICE | EP14804949 | 2014-05-15 | EP3006882A4 | 2016-12-28 | HARIU SATOSHI; YAMASAKI TAKAFUMI |
| A chemical heat storage device heats a subject to be heated existing in a pipe. The chemical heat storage device includes a reactor that generates heat by chemically reacting with a reaction medium, an absorber that causes an absorbent to absorb and stores the reaction medium, and a connection tube 11 that is connected to the reactor and absorber, for the reaction medium to migrate through. The reactor includes a solid reaction material 9a disposed along an outer peripheral surface of a place where the subject exists in the pipe and a casing that seals the reaction material so as to form a space 9d along an outer peripheral surface of the reaction material 9a. One end of the connection tube 11 is open to the space 9d. | ||||||
| 311 | SOLAR POWER TOWER | EP14803539 | 2014-05-29 | EP3004640A4 | 2016-12-28 | JOHNSON RAYMOND JR |
| A solar power plant for generating steam is comprised of a spherical shell, the interior of which is sealed from the outside atmosphere and which is mounted adjacent the top of a vertical tower. A plurality of heliostats surrounds the tower and the direct sunrays onto the sphere for heating the same sphere. A spray nozzle within the sphere directs water supplied to it from an external source onto the interior surface of the sphere to create steam. The steam is withdrawn and directed to a turbine or the like for generating electricity. A motor rotates the sphere about its vertical axis thereby regularly exposing a different portion of the sphere to the heliostats to prevent the sphere from melting. | ||||||
| 312 | EPICATALYTIC THERMAL DIODE | EP14803740 | 2014-05-29 | EP3003547A4 | 2016-12-28 | Paradigm Energy Research Corporation |
| An Epicatalytic Thermal Diode (ETD) includes one or more ETD cells. Each cell comprises first and second surfaces with a cavity between them, which contains a gas that is epicatalytically active with respect to the pair of surfaces. The surfaces chemically interact with the gas such that the gas dissociates at a faster rate proximate to the first surface than it does proximate to the second surface. Thus, a steady-state temperature differential between the first surface and the second surface is created and maintained. In various applications, multiple ETD cells are connected in series and/or parallel. | ||||||
| 313 | HIGH SOLAR-WEIGHTED REFLECTANCE POLYMER FILM REFLECTORS | EP14760580 | 2014-03-06 | EP2964952A4 | 2016-12-14 | JORGENSEN GARY; GEE RANDALL C; WHITE DAVID |
| Provided are reflective thin film constructions including a reduced number of layers, which provides for increased solar-weighted hemispherical reflectance and durability. Reflective films include those comprising an ultraviolet absorbing abrasion resistant coating over a metal layer. Also provided are ultraviolet absorbing abrasion resistant coatings and methods for optimizing the ultraviolet absorption of an abrasion resistant coating. Reflective films disclosed herein are useful for solar reflecting, solar collecting, and solar concentrating applications, such as for the generation of electrical power. | ||||||
| 314 | CONCENTRATING SOLAR MIRROR PANEL ASSEMBLY WITH CORRUGATED STIFFENER | EP10814386 | 2010-09-01 | EP2473793A4 | 2016-12-14 | MOLNAR ATTILA; HART DUANE M; COSGROVE DYLAN T; SIMONS SCOTT E |
| A concentrating solar mirror panel assembly having a reflective sheet with a reflective major surface and an opposing major surface and a corrugated stiffener having ridges and troughs each having an outer surface with land areas, wherein the land areas of at least a portion of the ridges are joined to at least a portion of the opposing major surface of the reflective sheet. The concentrating solar mirror panel assembly is non-planar and substantially rigid. The concentrating solar mirror panel assembly is assembled such that a desired non-planar shape is maintained: either using a locking sheet or having the corrugated stiffener attached so that its principal axes of corrugation are substantially perpendicular to the axis of curvature of the assembly. Methods of making the concentrating solar mirror panel assembly are also disclosed. Concentrated solar power systems and solar collection devices are also disclosed. | ||||||
| 315 | FLAMELESS COMBO HEATER | EP14762281 | 2014-03-17 | EP2971998A4 | 2016-12-07 | BELL PATRICK G; BECKIE WILLIAM N |
| A dual heating process is performed in the absence of an open flame. Heat is created by a rotating prime mover(s) driving a fluid shear heater. Heat is also collected from a cooling system of the prime mover, and from any exhaust heat generated by the prime mover. The heat energy collected from all of these sources is transmitted through heat exchangers to a fluid where heat energy is desired. The fluid being heated may be glycol or air, depending on the type of heat desired. | ||||||
| 316 | SOLAR ENERGY COLLECTOR AND THERMAL STORAGE DEVICE | EP10822466 | 2010-10-04 | EP2486339A4 | 2016-11-30 | COLSON WENDELL B; FOGARTY DANIEL M |
| A solar energy collector and thermal storage device for placement in a building's exterior architectural opening is provided, having an insulating cavity including a first lite on the device exterior side and a second lite spaced inwardly therefrom, defining a depth of the insulating cavity, and being substantially filled with an insulating gas. A provided thermal storage cavity includes the second lite and a third lite spaced inwardly therefrom, defining a depth of the thermal storage cavity which is at least the same size as the insulating cavity depth, and is substantially filled with a thermal storage medium, which is a hydrogel adhering to the second lite and the third lite and having cohesion characteristics such that it is self supporting and maintains its shape within the thermal storage cavity. A low-emissivity coating disposed on the insulating cavity side of the second lite inhibits exterior thermal radiation transfer. | ||||||
| 317 | TRANSLUCENT PLASTIC SOLAR THERMAL COLLECTOR | EP14778119 | 2014-03-07 | EP2972002A4 | 2016-11-16 | LUFTGLASS MURRAY A; DAHM KEVIN D; GUNHEIM CLAYTON C; TASCHEK LOUIS |
| Our invention consists of two separate and discrete families of polymers, e.g. thermosetting Fiberglass Reinforced Plastics (“FRP”) and thermoplastics. Both are used as the materials of construction to fabricate solar thermal collectors. These families have the same general configuration and are based upon the same principles. Both families are used in a form that some of the walls of the collector are translucent. Both families incorporate a passage through which the thermal fluid flows. Both families make use of dyes to absorb energy from the sun in the fluid and the collector walls. Each of the families makes use of improved collector configurations and designs and special operating approaches. Each family can serve different markets for different solar thermal collectors. In particular, FRP stands alone as an emerging new category of materials for a broad range of applications including everything from novel solar thermal collectors to exotic airplanes. | ||||||
| 318 | COUPLED CHEMICAL-THERMAL SOLAR POWER SYSTEM AND METHOD | EP13847674 | 2013-10-10 | EP2909546A4 | 2016-11-16 | ERICKSON LUKE; MUREN RUSSELL |
| A CSP system is disclosed which couples a thermal and a chemical energy pathway. The thermal pathway utilizes a heat transfer fluid to collect concentrated sunlight as thermal energy at medium temperature and transfer this energy to a thermal-to-electric power cycle. In parallel, the chemical pathway uses a redox material which undergoes direct photoreduction in the receiver to store the solar energy as chemical potential. This redox material is then oxidized at very high temperatures in the power cycle in series with the thermal pathway heat exchanger. This coupling allows the receiver to perform at the high efficiencies typical of state of the art thermal power towers while simultaneously achieving the power cycle efficiencies typical of natural gas combustion plants and achieving a very high overall solar-to-electric conversion efficiency. | ||||||
| 319 | CHEMICAL REACTION HEATING SYSTEM | EP14749192 | 2014-02-10 | EP2954752A4 | 2016-11-02 | BROWN GLENN NORMAN; BRYANT EARL CLEVELAND |
| A chemical reaction heating system includes a valved mask to capture and direct carbon dioxide from a user's exhaled breath into a tube or air intake chamber, a connecting mechanism to attach and control flow of carbon dioxide stored within prefilled carbon dioxide gas cartridges or containers, a heating system device body, an intake chamber or tube to facilitate the introduction of carbon dioxide enriched air into the system, a canister body containing Group IA and IIA metal hydroxides, a heat-radiating element to direct the heat generated within the heating system device body, and an exhaust element to release the heat generated. The system performs a chemical reaction operation between carbon dioxide and Group IA and IIA metal hydroxides to create an exothermic heat reaction that achieves the ability to heat spaces and objects. | ||||||
| 320 | MODULAR STRUCTURAL SYSTEM FOR SOLAR PANEL INSTALLATION | EP13854033 | 2013-11-08 | EP2917430A4 | 2016-11-02 | CAMERON D KEVIN |
| A support structure (SS) and method for mounting SS and solar equipment on pitched roofs. Preassembled SS is installable/ removable, as a single module for reduced cost, installation time, and hazards. Optional housing for battery, electronics, and wireless equipment, is disposed in portion of preassembled SS that resides in protected interior of building. An elevated attach point on the SS optionally accepts cellular and high-frequency transceivers (for mesh network). SS penetrates roof, not on leak-prone roof face, but at roof apex using a main support coupleable to internal building structure. An interface member on the main support has a shape that is conformal to the roof apex to provide a weatherproof seal, load support, and a fulcrum to absorb equipment torque. Padded-standoffs support equipment weight on roof. Optionally, SS frame tubing acts as wire-conduit or SS frame is configured as power conductor for low-voltage, parallely-coupled, independently-troubleshootable, solar panels. | ||||||
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