Abstract: Disclosed herein is a solar array column cap that includes a body having an opening extending along a center axis from a bottom to a top, the opening configured to receive the vertical column such that the body surrounds the vertical column. The solar array column cap further includes an upper support surface configured to receive a horizontal beam, the upper support surface being located in a plane that is non-perpendicular with the center axis.

Abstract: A protective transparent enclosure (such as a glasshouse or a greenhouse) encloses a concentrated solar power system. The concentrated solar power system includes one or more solar concentrators and one or more solar receivers. Thermal power is provided to an industrial process, electrical power is provided to an electrical distribution grid, or both. In some embodiments, the solar concentrators are parabolic trough concentrators with one or more lateral extensions. In some embodiments, the lateral extension is a unilateral extension of the primary parabolic trough shape. In some embodiments, the lateral extensions are movably connected to the primary portion. In some embodiments, the lateral extensions have a focal line separate from the focal line of the base portion. In some embodiments, the greenhouse is a Dutch Venlo style greenhouse.

Abstract: The steering and cleaning mechanism for reflector arrays includes at least one fixed rail and a movable rail slidably movable along the at least one fixed rail. The at least one fixed rail is disposed adjacent a plurality of reflectors arranged in an array. A positioning/cleaning carriage is disposed on the movable rail and slidably movable thereon. The positioning/cleaning carriage includes a positioning module and a cleaning module. The positioning/cleaning carriage is positioned over a select reflector by the combined movement of the movable rail and the carriage along the movable rail. Once positioned, the positioning module and the cleaning module are selectively actuated to both orient the target reflector in the desired position and to clean the same.

Abstract: The invention relates to a solar tracker having oleo-hydraulic cylinders that increase the rigidity of the system by keeping the two chambers of each cylinder pressurized, even while on stand-by. This makes the system more accurate, avoiding undesirable cylinder movement caused by oil compression. The system includes a circuit having at least one cylinder assembly (8,9), an oleo-hydraulic plant and a control system (5), wherein the oleo-hydraulic plant supplies the oil to the cylinders controlling the speed of movement of these latter, and the control system (5) supervises and controls the correct operation of the entire system and protects said system against possible accidents.

Abstract: Disclosed herein are examples and variations of solar energy collector system comprising an elevated linear receiver (5) and first and second reflector fields (10P, 10E) located on opposite sides of, and arranged and driven to reflect solar radiation to, the receiver (5). Also disclosed herein are examples and variations of receivers (5) and reflectors (12a) that may, in some variations, be utilized in the disclosed solar energy collector systems.

Abstract: A central distance measuring device, which can be directed at the heliostats, is used to determine the settings of the heliostats of a heliostat field. The distance measuring device measures the space between a plurality of measuring points from the measuring site and, based on this, determines the spatial alignment of the respective heliostat. A computer contains astronomical solar altitude software and controls an actuating device of the heliostat such that the heliostat assumes the alignment intended according to the solar altitude. With the invention, position sensors and/or angle sensors on the individual heliostats are avoided. All heliostats are aligned by a central computer.

Abstract: A hot beverage making device includes a boiler for heating water; a housing for accommodating the boiler and connecting element for connecting the boiler to the housing. During operation of the boiler, water is heated and water vapor bubbles are created inside the boiler. Formation of the bubbles causes varying moments about the center of mass of the boiler. The connecting element is adapted to prevent transmittal to the housing of at least a portion of the moment variations. This keeps the noise produced as a result of vibrations of the housing at an acceptable level. In particular, the connecting element is adapted to let the boiler have at least one rotational degree of freedom.

Abstract: The invention relates to a mounting frame for supporting sheet-type solar panels (12) comprising, fitted substantially vertically for anchoring by its lower end (13a) in the ground or by a fixed anchoring location (13b), a supporting mast (13) at which the solar panels (12) resting on a plane panel support (8-11) are supported by means of a supporting structure (14) and which are rotatable about the axis of the mast for azimuthal tracking.

Abstract: A solar collector includes a substrate having a top surface and a bottom surface opposite to the upper surface, a sidewall, a transparent cover, and a heat-absorbing layer. The sidewall is arranged on the top surface of the substrate. The transparent cover is disposed on the sidewall opposite to the substrate to form a sealed chamber with the substrate together. The heat-absorbing layer is disposed on the upper surface of the substrate and includes a carbon nanotube film having a plurality of carbon nanotubes. The carbon nanotubes in the carbon nanotube film are entangled with each other.

Abstract: In order to provide a method of operating a solar thermal power plant, in which a heat transfer medium is evaporated endothermally by solar radiation in an evaporator section, wherein the evaporator section comprises a plurality of evaporator branches, among which the heat transfer medium is distributed, in which method non-uniform radiation conditions of the evaporator section may be effectively taken into consideration, it is provided that the mass flow distribution at the evaporator section is controlled, wherein the mass flows are adjusted individually at all or a majority of the evaporator branches and a controlled variable is a variable characterizing a spatial energy rise in a respective evaporator branch in a region of the evaporator branch where the heat transfer medium has not yet evaporated.

Abstract: Reactors for conducting thermochemical processes with solar heat input, and associated systems and methods. A representative system includes a reactor having a reaction zone, a reactant source coupled in fluid in communication with the reactant zone, and a solar concentrator having at least one concentrator surface positionable to direct solar energy to a focal area. The system can further include an actuator coupled to the solar concentrator to move the solar concentrator relative to the sun, and a controller operatively coupled to the actuator. The controller can be programmed with instructions that direct the actuator to position the solar concentrator to focus the solar energy on the reaction zone when the solar energy is above a threshold level, and point to a location in the sky having relatively little radiant energy to cool an object when the solar energy is below the threshold level.

Abstract: In an embodiment, a method of conducting a high temperature chemical reaction that produces hydrogen or synthesis gas is described. The high temperature chemical reaction is conducted in a reactor having at least two reactor shells, including an inner shell and an outer shell. Heat absorbing particles are included in a gas stream flowing in the inner shell. The reactor is heated at least in part by a source of concentrated sunlight. The inner shell is heated by the concentrated sunlight. The inner shell re-radiates from the inner wall and heats the heat absorbing particles in the gas stream flowing through the inner shell, and heat transfers from the heat absorbing particles to the first gas stream, thereby heating the reactants in the gas stream to a sufficiently high temperature so that the first gas stream undergoes the desired reaction(s), thereby producing hydrogen or synthesis gas in the gas stream.

Abstract: A system and method are provided for continuously reorienting a solar panel array while maintaining a substantially stationary footprint for the solar panel. A cylindrically shaped knuckle is provided that is formed with a bottom surface and a top surface that is slanted relative to the bottom surface at a slant angle ?. One end of an upper pole is positioned against the top surface of the knuckle, and one end of a lower pole is positioned against the bottom surface of the knuckle. An upper and lower motor respectively connect the knuckle to the upper pole and the lower pole. These motors are used to continuously rotate the knuckle at an angular velocity ? relative to the upper and lower poles. When the knuckle rotates, the upper and lower poles remain stationary to allow the solar panel to continuously reorient while maintaining a substantially stationary footprint.

Abstract: In one embodiment, a method of assembling optical elements is provided. At least a portion of each optical element is disposed against at least a portion of a high precision surface. A structural frame is disposed adjacent the optical elements. At least two portions of the structural frame are aligned relative to each other and to the high precision surface with high precision. Adhesive is applied to adhere the structural frame to the optical elements. The adhesive is cured. In other embodiments, optical element assemblies are provided.

Abstract: A solar collector includes a substrate having a top surface and a bottom surface opposite to the upper surface, a sidewall, a transparent cover, and a heat-absorbing layer. The sidewall is arranged on the top surface of the substrate. The transparent cover is disposed on the sidewall opposite to the substrate to form a sealed chamber with the substrate together. The heat-absorbing layer is disposed on the upper surface of the substrate and includes a carbon nanotube structure.

Abstract: Solar system cleaning apparatuses and methods of cleaning solar systems are described. A solar system cleaning apparatus includes a vehicle. A first basin is mounted on the vehicle, the first basin to supply a cleaning medium to a solar module. A second basin is mounted on the vehicle, the second basin to collect the cleaning medium from the solar module. A filter is coupled to the first basin and the second basin, the filter to transfer the cleaning medium from the second basin to the first basin.

Abstract: A mirror or other reflecting surface is used for collecting and reflecting incident solar radiation. The mirror is supported for independent motion about a pair of axes. An accelerometer generates signals representative of an amount and direction of motion of the mirror about each of the axes. Motors or other drive mechanisms independently drive the mirror about each of the axes. A tracking device provides information about the current position of the Sun. A control is connected to the accelerometer, the motors and the tracking device for maintaining a predetermined optimum orientation of the mirror as the Sun moves across the sky.

Abstract: A thermal insulator includes a plurality of insulation layers with a first insulation layer spaced apart from a second insulation layer such that there is an open gap there between. At least one of the first insulation layer or the second insulation layer includes a substrate and an infrared-reflective coating on the substrate.

Abstract: An improved solar concentrating system (100) uses a two-stage arrangement of mirrors wherein the rays of the sun are reflected and concentrated to a point focus. The solar concentrator (100) may be used to increase the temperature of a substance such as metal, for use in a variety of applications including the melting of metals in a foundry furnace. The solar concentrating system (100) comprises at least two single-curved parabolic mirrors (10, 20) connected in an operable arrangement. The rays of the sun are reflected from a first single-curved parabolic mirror (10) to a second single-curved parabolic mirror (20). The plane of symmetry of the second single-curved parabolic mirror is arranged substantially orthogonal to the plane of symmetry of the first single-curved parabolic mirror thereby concentrating the rays of the sun to a point focus.

Abstract: Systems and methods for operating environmental equipment using heat absorbed by manufactured surface coverings from incident solar radiation where fluid in conduits carried in the manufactured surface covering is heated and supplied to a heat exchanger to provide heat for various environmental equipment such as a hot water supply, a turbine-driven electrical generator, a chiller, a water purification system, and/or a distillation system. Efficiencies are maximized by use of thermally conducted aggregates in the manufactured surface covering.

Abstract: A boiler for a solar receiver includes a panel support structure. A boiler stay is operatively connected to the panel support structure. A panel stay is slideably engaged to the boiler stay. A boiler panel is operatively connected to the panel stay with the panel stay being affixed to a plurality of tubes of the panel. The boiler stay and panel support assemblies are configured and adapted to slide with respect to one another to accommodate thermal expansion of the boiler panel. In certain embodiments, a pin connects the boiler stay and the panel stay, wherein the pin is removable for installation and removal of the panel from the support structure.

Abstract: The invention provides a solar water heating apparatus with double-row vacuum tubes coupled to a water tank made of stainless steel or enamel. Each of the vacuum tubes is made of an exterior tube and an interior tube separated by a vacuum. The exterior tube is transparent. The interior tube is covered with a layer of light-absorption material. When sunlight shines on the vacuum tube, the water in the tank and the water in the interior tube circulate by convection.

Abstract: Integral, thermal storage and receiver system. The system includes a heat storage medium and a receiver for capturing incoming radiation, the receiver being in thermal contact with the heat storage medium and forming an integral part of it. In a preferred embodiment, the storage medium is a molten salt and the receiver is a black body cavity formed of polyhedral structures and immersed within the molten salt.

Abstract: A structure and method of controlling building temperature are provided utilizing both solar and geo-exchange means.

Abstract: A system of passively heating water using solar energy and an absorber formed from two identical halves of molded darkened glass that are fused together. The absorber is essentially a plurality of black glass struts that are sandwiched between two black glass surfaces. The struts act as baffle plates and define cells. Water is carried through the system via the thermosiphoning effect.

Abstract: Systems and methods for disposing and supporting a solar panel array are disclosed. The embodiments comprise various combinations of cables, support columns, and pod constructions in which to support solar panels. The solar panels can incorporate single or dual tracking capabilities to enhance sunlight capture. The embodiments encourage dual land use in which installation of the systems minimizes disruption of the underlying ground. Supplemental power may be provided by vertical axis windmills integrated with the columns. Special installations of the system can include systems mounted over structures such as parking lots, roads and aqueducts.

Abstract: A solar energy collecting module includes a frame that is assembled without using screws. The peripheral frame components are joined together using locking links and one or more ribs extend along the back side of the solar panel and are coupled to opposed sides of the frame. The ribs are coupled to the frames by an edge key fastener that includes opposed first flanges and opposed second flanges, the first flanges separated from the second flanges by a gap. The edge key fastener is inserted into an opening formed in a side wall of a frame component and rotated such that the opposed first flanges are disposed behind the side wall and within the frame and the opposed second flanges are received in a corresponding cavity formed in each of opposed ends of the rib.

Abstract: The glass of the glass-metal bond contains the following ingredients in the following amounts: SiO2, 72-80 wt %; B2O3, 4-<6 wt %; Al2O3, 2-5 wt %; Na2O, 4-7 wt %; K2O, 0-3 wt %; CaO, 2.5-8 wt %; MgO, 0-2 wt %; BaO, 0-4 wt %; TiO2, 0-5 wt %; CeO2, 0-2 wt %; Fe2O3, 0-0.1 wt %; F, 0-2 wt %; and the ratio of the sum total amount of Al2O3 and B2O3 (in mol %) to the sum total amount of MgO, CaO and BaO (in mol %) in the glass is less than 5. The glass-metal bond advantageously includes a KOVAR® alloy and the glass of the aforesaid composition and connects the glass envelope tube with an inner metal absorber tube in a tube collector.

Abstract: A system for raising water from an underground source of water to an aboveground tank includes a plurality of capillary tubes for raising water from the underground source to a first water level, a pipe for raising water from the first water level to an above ground tank, the aboveground tank is painted black to absorb the sun's rays and is tilted with an elevated proximal end so that water in the tank runs down to its distal end. A tap is provided in the distal end for drawing water out of the tank. The tank also includes two one way valves, one in an upper portion of the distal end for allowing heated air to escape and one in a lower portion of the distal end to allow water to be drawn up into the tank as heated air cools. A solar powered rechargeable battery can be used to power a positive displacement pump.

Abstract: A parabolic trough solar collector system has a parabolic reflector used with an independently supported collector tube. The parabolic reflector has a reflective surface formed on a reflective surface support structure, supported by a circular support beam. This assembly rests on a plurality of support and drive rollers supported by a roller support arm, supported by a roller support column. The parabolic reflector assembly rotates against the rollers along a single axis to maintain a focus line of the parabolic reflector surface at the same location as the center of the circle described by the outer edge of the circular support beam. Located at this same focus line is the independently supported collector tube not attached to the parabolic trough reflector. The collector tube is supported on pipe roller hangers, which in turn are supported by a wire catenary system connected to support towers which straddle the parabolic reflector.

Abstract: The alignment of a parabolic trough reflector and its receiver pipe in a solar thermal field for collecting sunlight energy can be verified by acquiring an aerial image of the parabolic trough reflector from above the thermal field while passing through the sun-receiver-vertices plane of the parabolic trough reflector. By analyzing the aerial image to determine whether any reflection of the sun is visible in the parabolic trough reflector in the aerial image, one can determine whether the parabolic trough reflector and its receiver pipe is properly aligned. If a reflection of the sun is visible in the parabolic trough reflector in the aerial image, the parabolic trough reflector and its receiver pipe are out of alignment and require an adjustment.

Abstract: An air quality instrumentation system for a concentrated solar power generation system using a fluid heat transfer medium includes a pipe, a window and a spectroscope. The pipe extends from the concentrated solar power generation system and contains system air from within the concentrated solar power generation system. The window is positioned within the pipe to permit light to pass through the pipe and the system air. The spectroscope is positioned adjacent the window to assess concentration of a constituent within the system air, the concentration of the constituent providing an indication of an operating condition of the concentrated solar power generation system.

Abstract: In one aspect, the present invention is directed to a heating device comprising: a heating container (10, 12); an inlet (40, 72), through which water to be heated enters the heating container (10, 12), the inlet being disposed at a lower portion of the container (10,12); a first outlet (62, 74), through which water heated within the heating container (10,12) exits thereof, the first outlet drawing water from a high portion of the container (10, 12); and a second outlet (44, 22) for drawing water from a low portion of the container (10, 12), the second outlet being openable for releasing therethrough water including accumulated scale, thereby enabling discarding scale when accumulated in the container (10, 12).

Abstract: The present invention relates to a method and apparatus for levitating and conveying sand, dust or melting snow deposits off the surface of objects, in particular solar panels, mirrors, glass objects and the like.

Abstract: Disclosed is a controlling apparatus for use in a photovoltaic system. The photovoltaic system includes a solar cell array, an inverter and a solar tracker. The solar tracker includes a solar position sensor, a controller connected to the solar position sensor, a first motor connected to the controller for rotating the solar cell array according to the azimuth of the sun and a second motor connected to the controller for tilting the solar cell array according to the elevation of the sun. The controlling apparatus includes a central unit, a basic unit, a diagnosis unit, a maintenance unit, a security unit and a check unit.

Abstract: The invention is using a hydrogen-containing solid as an energy storage material for naval and stationary uses. The system is designed and analyzed optimally for producing thermal energy necessary to dissociate magnesium hydride which in turn produces the needed hydrogen to operate a fuel-cell and meet the electricity demand. The collected hydrogen is used to power the various energy needs of the Navy as well as of homes. In addition, the solar thermal system may also be used to provide heat to hot water, and other heating needs. The system has an overall energy efficiency between 20% and 30% with both thermal and hydrogen storage capability for overall energy storage and provides smooth energy needs of a building.

Abstract: A solar concentrator includes a plurality of separate panels positioned between opposed support rods. Tension elements extend between the support rods and mount the plurality of panels.

Abstract: Disclosed is a silicon carbide honeycomb having porosity of 5% or less but exceeding 0% and including silicon carbide and metal silicon. Also disclosed is a method of preparing a silicon carbide honeycomb. Further, disclosed is a solar receiver comprising silicon carbide and metal silicon.

Abstract: Systems and methods for disposing and supporting a solar panel array are disclosed. In one embodiment, a system for supporting a solar panel array includes the use of support columns and cables suspended between the support columns, with the solar panels received by solar panel receivers that are adapted to couple to the cables. The solar panel array may then be used to provide power as well as shelter. Cooling, lighting, security, or other devices may be added to the solar panel array. Embodiments of the invention include differing ways to support the solar panels by receivers of differing construction. Special installations of the system can include systems mounted over structure, such as parking lots, roads and aqueducts.

Abstract: Solar concentration plant placed on tower technology wherein the tower is used not only to equate the receiver devices at great height but also as a natural-draft cooling system. The tower is hollow and has a hyperboloid. structure that may exceed 200 m in height, accommodating devices for receiving saturated or superheated steam in cavities with different orientations. There is a dynamic control for adapting the heliostat field so that the heliostats can be focussed on different focal points for producing electricity, producing process heat, producing solar fuels or for application to thermochemical processes.

Abstract: Reactors for conducting thermochemical processes with solar heat input, and associated systems and methods. A system in accordance with a particular embodiment include a reactor having a reaction zone, a reactant source coupled in fluid in communication with the reactant zone, and a solar concentrator having at least one concentrator surface positionable to direct solar energy to a focal area. The system can further include an actuator coupled to the solar concentrator to move the solar concentrator relative to the sun, and a controller operatively coupled to the actuator.

Abstract: The present invention provides a solar absorptive material for a solar selective surface of an absorber of solar radiation. The solar absorptive material comprises a dispersed metallic material and a receiving boundary through which the solar radiation is received. Further, the solar absorptive material comprises a first region and a second region. The first region being located at a position closer to the receiving boundary than the second region and the first region has an average volume fraction of the dispersed metallic material that is larger than that of the second region.

Abstract: An apparatus is disclosed including: an entrance aperture for admitting light from a source; an optical collector configured to receive light admitted through the entrance aperture and concentrate the light onto a receiver element; and an optical homogenizer element configured and arranged to image the entrance aperture onto the receiver element.

Abstract: The invention concerns a wall or roof of a building, wherein at least one heat controlling element for controlling a temperature in the building is arranged in the wall or the roof to form a segment of the wall or roof, the heat controlling element comprising at least a first section and a second section, the first section comprising a heat collecting and storing material and the second section comprising a heat insulating material, wherein the heat controlling element may adopt a first configuration, in which the first section is directed towards the outside of the building and the second section is directed towards the inside of the building, and a second configuration, in which the second section is directed towards the outside of the building and the first section is directed towards the inside of the building.

Abstract: Described are methods for surface modification of an object (10) in order to increase the adhesive power of the object, wherein the surface (11) is subjected to structuring so that a multitude of projections (12) are formed, each comprising a foot part and a head part, wherein the head part comprises a front surface (13) which faces away from the surface, wherein each projection (12) is made in a size such that all front surfaces (13) project to the same vertical height above the surface (11), and form an adherent contact surface (14) which is interrupted by mutual spacing between the front surfaces (13).

Abstract: A method of collecting and redistributing energy, including receiving energy from an energy vendor at a transaction station, measuring the received energy, identifying and crediting the energy vendor, storing the received energy in an energy storage medium, identifying an energy user, dispensing energy to the energy user at a transaction station, measuring the dispensed energy, and debiting the energy user for the dispensed energy. The transaction station includes a housing, a microprocessor portion in the housing operationally connected to a computer network, an energy metering portion operationally connected to the microprocessor, an energy inlet operationally connected to the energy metering portion, an energy outlet operationally connected to the energy inlet and the energy metering portion, an energy storage operationally connected to the energy inlet and to the energy outlet, and an energy source operationally connected to the energy inlet.

Abstract: An apparatus is described for heating service water with a solar collector, comprising a service water tank (7) with a partly cylindrical jacket (8) as an absorber and an enclosure (1) which covers the service water tank (7) and forms a translucent cylindrical jacket (3), the axis of which extends parallel to the axis of the jacket (8) of the service water tank (7). In order to provide advantageous heating conditions, it is proposed that the service water tank (7) is connected in a thermally conductive manner with an absorber plate (4) forming a bottom part of the enclosure (1) and that the absorber plate (4) and the jacket (8) of the service water tank (7) are covered with a wide-meshed, thermally insulating fabric (11).

Abstract: A flexible sheet of aligned carbon nanotubes includes an array of aligned nanotubes in a free standing film form not adhered to the synthesis substrate, with a matrix infiltrated interstitially into the nanotube array with access to the nanotube tips from both the top and bottom. That is, the infiltrant is purposely limited from over-filling or coating one or both exterior top and/or bottom surfaces of the array, blocking access to the tips. A typical matrix is a polymer material.

Abstract: An aerospace platform includes a structure having a cavity and a light-transmissive portion that exposes the cavity to sunlight. The aerospace platform further includes a fluid heating system. The fluid heating system includes a fluid-carrying, thermally absorptive structure within the cavity, and a solar collector for collecting light transmitted through the light-transmissive portion and focusing the collected light onto the absorptive structure. The thermally absorptive structure has a high surface absorptivity that retains thermal energy when exposed to solar irradiance and heats fluid contained therein.

Abstract: A system and method are provided to control hydronic systems having a plurality of sources, including at least one of an on-demand source, a semi-on-demand source, and an intermittent source that are fluidly or thermally coupled to a plurality of load zones. The hydronic system device obtains performance measurements for system components to provide system metrics, including failure diagnostics, energy capture, and usage optimization. The hydronic system device may also calculate British Thermal Units produced and used by the plurality of sources and loads to calculate incentives, including renewable energy credits.