Abstract: A driveline joint may include a driveline shaft that has a plurality of slots and a shaft coupling positioned in an interior of the driveline shaft in which the shaft coupling includes one or more openings with each of the openings corresponding to one or more respective slots of the plurality of slots included in the driveline shaft. The driveline joint may include one or more spherical bearings that are each positioned between an interior lateral surface of the driveline shaft and an exterior lateral surface of the shaft coupling and against one of the openings of the shaft coupling. The driveline joint may include one or more fasteners, wherein each of the fasteners extends through one of the slots and one of the openings of the shaft coupling.

Abstract: A driveline joint may include a driveline shaft that has a plurality of slots and a shaft coupling positioned in an interior of the driveline shaft in which the shaft coupling includes one or more openings with each of the openings corresponding to one or more respective slots of the plurality of slots included in the driveline shaft. The driveline joint may include one or more spherical bearings that are each positioned between an interior lateral surface of the driveline shaft and an exterior lateral surface of the shaft coupling and against one of the openings of the shaft coupling. The driveline joint may include one or more fasteners, wherein each of the fasteners extends through one of the slots and one of the openings of the shaft coupling.

Abstract: A thermal energy storage unit is disclosed. The system comprising: a tube having at least one inlet and at least one outlet for a first fluid; a plurality of plate-shaped or box-shaped capsules having a second fluid therein, wherein the plurality of capsules is arranged inside the tube to form a plurality of stacks of capsules; wherein: the first fluid is a heat transfer fluid for exchanging heat with the second fluid; the second fluid is a phase-change medium; wherein a plurality of defined narrow flow paths for the first fluid is provided between the capsules. The defined flow paths increase the efficiency of the system.

Abstract: A thermal energy storage is provided comprising a housing, a thermal energy storage structure arranged within the housing, the thermal energy storage structure comprising thermal energy storage elements and a plurality of dividing elements, the plurality of dividing elements being arranged such that the thermal energy storage elements are divided into a plurality of layers, a fluid inlet, the fluid inlet being in fluid communication with the housing and adapted to receive a working fluid and provide a flow of working fluid towards the housing, and a convection reducing structure arranged adjacent the thermal energy storage structure at a side of the thermal energy storage structure that faces the fluid inlet. Furthermore, a method of storing thermal energy and a steam power plant for producing electrical energy are described.

Abstract: A device and method of its production for a micro-channel thermal absorber to be used as a solar thermal collector, heat collector, or heat dissipater, extruded or continuously cast in one piece or in modular segments from a metal, plastic, or glass and assembled into panels of different structures seamlessly integrated into the envelope of a building as covering layers or structural elements. The micro-channel thermal absorber comprises an active plate, a back plate adjacent to the active plate, and a plurality of micro-channel walls arranged substantially perpendicular to the active plate and the back plate to define a plurality of fluid transport micro-channels configured to allow fluid flow there-along, wherein the micro-channel walls constitute supporting elements between the active plate and the back plate to provide structure.

Abstract: Superheated steam tower receiver with a well-defined configuration that benefits the transfer of heat between the surface of the component and the working fluid. Composed of at least four subpanels that define the circulation circuit for the steam by means of internal passages. The component is provided with saturated steam and for the production of said steam it is possible to use other solar concentrator technology. The proposed configuration minimizes the technological risks inherent in superheated steam receiver technology where drawbacks arise in the structure of the material owing to the thermal cycles to which the solar component is subjected.

Abstract: A solar energy collecting system comprises a manifold defining a closed fluid passage between a condensation point and a heating point. The manifold includes a plurality of heat exchange members configured to be in heat exchange relationship with the fluid passage at the heating point, and a heat sink at the condensation point. A plurality of solar energy collector members extend from and operably connect to the heat exchange members of the manifold. The solar energy collector members collect solar energy and transform it into heat energy. Heat energy is transferred from the solar energy collector members to the heat exchange members and to a fluid in the passage in the manifold at the heating point so as to heat the fluid into a vapor. The fluid is circulated in heat exchange relationship to the condensation point where heat energy is transferred to the heat sink so as to cool the fluid to a liquid.

Abstract: A solar hot water and recovery system includes a water loop, a refrigerant loop and a solar loop. Cross-heat exchange occurs in a first heat exchanger between the heat transfer mediums of the refrigerant loop and the solar loop to produce a super-heated fluid stream which is returned to the air conditioning or heat pump unit. Cross-heat exchange also takes place in a second heat exchanger between the now-lower temperature heat transfer medium of the solar loop and the water loop to produce a heated water stream. The main objective of the system is to superheat refrigerant and use all excess heat for heating the water. The heat exchangers are preferably housed in the same heat recovery unit and arranged so that the refrigerant heat exchange area is before the water heat exchange area, thereby maximizing solar potential.

Abstract: A solar tracking device that uses thermal actuation to rotate a solar energy device to track movement of the sun for improved solar energy output of the solar energy device. Thermal actuation is generated by concentrating solar radiation using a solar collector and solar receiver. A medium that expands when heated is in thermal communication with the solar receiver and drives an actuator for rotating the solar tracking device to follow the movement of the sun. The medium may be a phase change material such as Paraffin wax. Rotational actuation may be performed using helical slots in a main housing and cam followers coupled to a shaft extended out of the main housing. At the end of the day, a combination of gravity and/or mechanical return forces may assist in returning the system to an initial position such that it is ready to receive solar radiation the next day.

Abstract: A solar heat boiler is provided which is capable of avoiding damage to heat transfer tubes without increasing facility cost and construction cost. The solar heat boiler includes: a low-temperature heating device by which water supplied from a water supply pump is heated by heat of sunlight; a steam-water separation device by which two-phase fluid of water and steam generated in the low-temperature heating device is separated into water and steam; a high-temperature heating device by which the steam separated by the steam-water separation device is heated by the heat of sunlight; and a circulation pump by which the water separated by the steam-water separation device is supplied to the low-temperature heating device.

Abstract: A solar powered generator assembly is provided for driving a turbine using steam produced by solar power. The assembly includes a fluid tank and a fluid line having a first end and a second end each in fluid communication with the fluid tank. A fluid is positioned in the fluid tank and the fluid line. A lens focuses solar rays into a heat collector coupled to the lens. The heat collector has a reflective curved interior surface configured for reflecting solar rays to facilitate heating the heat collector. A medial portion of the fluid line is wrapped around and heated by the heat collector converting the fluid into a gaseous state. A turbine is operationally coupled to the fluid line driving the turbine to produce electrical current.

Abstract: Insolation can be used to heat a solar fluid for use in generating electricity. During periods of relatively higher insolation, excess enthalpy in a superheated solar fluid can be stored in a thermal storage system for subsequent use during periods of relatively lower insolation or at times when supplemental electricity generation is necessary. Enthalpy from superheated solar fluid can be transferred to the thermal storage system so as to heat a storage medium therein, but the enthalpy transfer can be limited such that the superheated solar fluid does not condense or only partially condenses. The remaining enthalpy in the de-superheated solar fluid can be used for other applications, such as, but not limited to, preheating the solar fluid for an evaporating solar receiver, supplementing the input to a superheating solar receiver, industrial applications, resource extraction, and/or fuel production.

Abstract: A process and an apparatus (100) for producing a superheated working fluid from a concentrating solar plant. More specifically, the process and apparatus produce superheated steam. The apparatus is designed such that it can use more than one heat transfer medium to produce the superheated working fluid. A first heat exchanger system (101) is designed to use the heat of a first heat transfer medium in order to preheat, evaporate and superheat a working fluid in a power generating working cycle (103). A second heat exchanger system (102) is designed to use the heat of a second heat transfer medium to superheat the working fluid in cycle (103).

Abstract: A hybrid solar/non-solar thermal generation system includes a solar concentrator and collector, and fiber optic cables that transfer collected solar radiation to a solar to thermal converter. The solar to thermal converter converts the solar radiation to heat that is used to augment the heating of a working fluid in a boiler. The system has particular application for use in Rankine cycle power generation plants that employ non-solar sources to heat the working fluid.

Abstract: The present invention is directed to a solar energy system including a tower having a solar radiation receiver, the solar radiation receiver including a plurality of tubes carrying a heat-transfer medium and a drum, the drum in thermal communication with the tubes, and one or more mirrors configured to reflect solar radiation onto the receiver, wherein the receiver receives the reflected solar radiation from the mirrors, thereby heating the heat transfer medium and vaporizing the heat transfer medium.

Abstract: Solar energy conversion systems and methods use solar collectors and working fluid management systems to provide both efficient and safe operation under a wide range of operating conditions. In one embodiment, a solar collector and at least one fluid accumulator preferably with an integral heat exchanger, and at least two mass flow regulator valves enable working fluid flow into and out of the fluid accumulator.

Abstract: System and method for accumulating steam in tanks for solar use made up of two sets of Ruths tanks (1, 2), called base set and overheat set, identical to one another and each having a saturated steam inlet (3), steam injectors (10) installed inside the tank (1, 2), a steam outlet (4, 4?) with a valve (13) and drainage means (11). A heat exchanger (6) is installed between the two sets of tanks (1, 2). The method of storage consists of a tank loading stage and a tank discharging stage, the latter comprising two discharging phases, the first one from a maximum to an intermediate pressure and the second one from an intermediate to a low pressure.

Abstract: Superheated steam tower receiver with a well-defined configuration that benefits the transfer of heat between the surface of the component and the working fluid. Composed of at least four subpanels that define the circulation circuit for the steam by means of internal passages. The component is provided with saturated steam and for the production of said steam it is possible to use other solar concentrator technology. The proposed configuration minimizes the technological risks inherent in superheated steam receiver technology where drawbacks arise in the structure of the material owing to the thermal cycles to which the solar component is subjected.

Abstract: Solar concentrator plant using natural-draught tower technology, in which the tower is, in turn, used as cooling system. The tower houses saturated or superheated steam receivers in cavities with different orientations, with adaptive dynamic control of the heliostat field in order to direct said receivers towards different focusing points, for the production of electricity, process heat or solar fuels or for use in thermochemical processes.

Abstract: A light receiving plate floating on the surface of tin, i.e., a low-melting-point heating medium and receiving solar beams is made of solid carbon material entirely coated with a silicon carbide film. Due to the silicon carbide film, the surface of the light receiving plate is black to realize a high absorption ratio of the solar beams. In addition, the light receiving plate is made of the silicon carbide film at least at the surface thereof, to demonstrate excellent heat resistance.

Abstract: Systems and methods for concentrating and storing solar energy are provided. A solar energy receiver for use with the systems and methods may include a container for holding a solar absorption material, such as a phase change material, and a cooled cover disposed above the container for condensing and collecting vaporized phase change material collected along an underside of the cover.

Abstract: A cavity-type solar energy receiver for generating high pressure steam, which includes panels of tubes defining a cavity within an outer enclosure. Concentrated solar energy provided by a heliostat enters the cavity opening in the enclosure and evaporates water within some of the tube panels. The evaporating tubes receive hot water from a steam drum by natural circulation and return a mixture of steam and hot water to the steam drum. Additional tube panels are positioned to receive reflected solar energy, which is used to preheat feed water and to superheat steam.

Abstract: In some implementations, there is provided an apparatus. The apparatus may include a first steam engine, an intermediate storage, and a second steam engine. The first steam engine may include a first inlet and a first exhaust, wherein the first inlet receives steam from a source of thermal energy. The intermediate storage may be coupled to the first exhaust, wherein the intermediate storage stores thermal energy provided by steam from the first exhaust. The second steam engine may include a second inlet coupled to the intermediate storage. Moreover, at least one of the first steam engine and the second steam engine may produce work. Furthermore, the first steam engine may be driven by the steam received from the source of thermal energy, and the second steam engine may be driven by steam from at least one of the intermediate storage and the first exhaust. Related apparatus and methods are also described.

Abstract: A boiler for a solar receiver includes a plurality of solar receiver panels. The panels are fluidly connected to one another by way of a steam circuit. At least one spray station is in fluid communication with the steam circuit and is configured and adapted to provide temperature cooling spray into the steam circuit to control the temperatures of the panels.

Abstract: Solar receivers and particularly to solar receivers having one or more cavities and optionally having absorptivity/reflectivity patterns on surfaces and methods of reflective material application.

Abstract: A system for effecting cooling of a coolant fluid is provided, the system comprising: a solar energy collector system; and fluid channels for the coolant fluid that are at least partially above ground level and are at least partially shaded by the solar energy collector system. The system may comprise a system for cooling a condenser coolant fluid in a thermal power plant incorporating a solar energy collector system, the system comprising: one or more solar energy reflectors; and fluid channels for the coolant fluid that are at least partially above ground level and are at least partially shaded by one or more of the solar energy reflectors. Solar energy reflector carrier arrangements for use in said system, and methods and thermal power plants utilizing said system are further provided.

Abstract: A solar energy system comprises a solar absorber in the form of a solar boiler tank with a lower working liquid region having a liquid inlet and filled with a working liquid capable of boiling under a predetermined pressure, and an upper vapor accumulation region having a vapor outlet for withdrawing from the tank a vapor created in the tank. The system further comprises vapor utilization means associated with the vapor outlet. The solar boiler tank has at least one transparent window to receive and pass towards the working liquid highly concentrated solar radiation. The system also comprises means for controlling the pressure of vapor in the vapor accumulation region to make the working liquid boil at the predetermined pressure.

Abstract: A solar energy heat exchanger includes a heat pipe that directly heats flowing water in a supplied pipe. A solar collector plate collects solar energy in one part of the heat exchanger. A portion of the heat pipe is located in the solar collector plate. A second part of the heat pipe transfers heat to water in the supply pipe. A heating system is also described. The heating system includes a solar energy heat exchanger, a hot water reservoir, and a heater to distribute heat to a building. Optional supplemental energy sources and control units to regulate operation may also be used. The heat pipe in the heat exchanger may contain capillary tubes to circulate thermally conductive media within a closed heating manifold.

Abstract: A solar energy system comprises a solar absorber in the form of a solar boiler tank with a lower working liquid region having a liquid inlet and filled with a working liquid capable of boiling under a predetermined pressure, and an upper vapor accumulation region having a vapor outlet for withdrawing from the tank a vapor created in the tank. The system further comprises vapor utilization means associated with the vapor outlet. The solar boiler tank has at least one transparent window to receive and pass towards the working liquid highly concentrated solar radiation. The system also comprises means for controlling the pressure of vapor in the vapor accumulation region to make the working liquid boil at the predetermined pressure.

Abstract: This invention reduces a molten salt, solar central receiver's size, pressure loss and cost by using a loose-tight-loose twist, twisted-tape insert inside the receiver's tubes to enhance the tube's heat transfer coefficient. This twist staging is designed to provide a higher heat transfer coefficient in the receiver's central region where the solar flux is high and a reduced pressure loss at the low solar flux entrance and exit end regions. Because the twisted-tape enhances the tube's heat transfer ability it can be made larger in diameter than a smooth bore tube at an equivalent pressure loss. This reduces the number of tubes which results in a substantial reduction in receiver cost.