Abstract: A luminescent solar concentrator including a light-guiding slab containing a luminescent material that generates light emissions in response to received sunlight, spaced-apart outcoupling structures that provide a distributed outcoupling of the light emissions through predetermined locations on one of the “broadside” (e.g., upper or lower) surfaces of the light-guiding slab, and optical elements positioned to redirect the outcoupled light emissions such that the light emissions are concentrated onto a predetermined target (e.g., a PV cell). Each optical element includes a collimating surface portion and optional returner surface.

Abstract: A solar concentrator assembly is disclosed. The solar concentrator assembly comprises a first reflective device having a first reflective front side and a first rear side, a second reflective device having a second reflective front side and a second rear side, the second reflective device positioned such that the first reflective front side faces the second rear side, and a support assembly coupled to and supporting the first and second reflective devices, the second reflective device positioned to be vertically offset from the first reflective device.

Abstract: A solar collector including a linear receiver and an array of linear mirrors positioned to concentrate sunlight onto the linear receiver, with all of the mirrors in the array tracking solar motion in a direction perpendicular to the longitudinal axis of the receiver, a fraction of the mirrors tracking solar motion in a direction parallel to the longitudinal axis of the receiver and a two-axis steering mechanism adapted to combine the linear images formed by each linear mirror into a single linear image that remains focused on the linear receiver as the mirrors rotate about the two axes, with the linear receiver incorporating a secondary concentrator, and concentrated sunlight heating an atmospheric-pressure gas-phase heat-transfer fluid.

Abstract: A collector system (12) is disclosed that comprises a row of linearly conjoined collector structures (13). The collector system is arranged to be located at a level above a field of reflectors (10) and to receive solar radiation reflected from the reflectors within the field. The collector structure (13) comprises an inverted trough (16) and, located within the trough, a plurality of longitudinally extending absorber tubes (30) that, in use, are arranged to carry a heat exchange fluid. The absorber tubes (30) are supported side-by-side within the trough and each absorber tube has a diameter that is small relative to the aperture of the trough. The ratio of the diameter of each absorber tube to the trough aperture dimension is of the order of 0.01:1.00 to 0.10:1:00 and, thus, a plurality of absorber tube functions, in the limit, effectively to simulate a flat plate absorber.

Abstract: A solar concentrator comprises an incidence surface, a first reflective curved surface corresponding to the incidence surface, a second reflective curved surface disposed in a center part of the incidence surface, and a concentrating part disposed in a center part of the first reflective curved surface and corresponding to the second reflective curved surface, wherein the incidence surface, the first reflective curved surface, the second reflective curved surface, and the concentrator include a substantially same material from each other.

Abstract: A solar energy collecting system arranged to gradually and stepwise heat a thermal fluid in thermal receivers, interconnected via an insulated tube and configured in parallel serially connected subgroups. The receivers are heated by optical elements arranged to reflect solar radiation upon the receivers, aligned according to specified temporal-spatial patterns, relating to the terrain and the solar motion. Receivers and optical elements may be positioned at specified locations and heights that maximize the energy yield. The configuration of the receivers and the optical elements may be adapted to storage and transport requirements. The system is highly modular and efficient in energy production and storage.

Abstract: It enhances heat collecting efficiency of sunlight received by heliostats. It is a solar light collecting method in a multi-tower beam-down light collecting system, including a tower selection. The multi-tower beam-down light collecting system is a system in which, in a field where a plurality of beam-down light collecting towers are present, light primarily reflected by heliostats 1 around each tower 4 is secondarily reflected by a reflector 3 at a top part of the tower 4 and is collected on a receiver 3 on the ground, and the tower selection is a process in which, assuming that the heliostat 1 in a given position receives sunlight and reflects the sunlight toward each of optionally selected two of the towers 4, 4, a light receiving quantity on the receiver 3 of each of the towers 4 is compared, and one of the towers 4 in which the light receiving quantity is relatively large is selected to reflect the sunlight toward the one of the towers 4.

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: A solar collection system having a secondary reflector is provided. The secondary reflector may be located above a field of primary reflectors and below a solar receiver. The secondary reflector may form a portion of an ellipse or macrofocal ellipse and be operable to reflect at least a portion of the solar radiation reflected by the primary reflectors onto the solar receiver. The secondary reflector may be disposed away from the solar receiver and associated tertiary reflectors such that it does not intercept reflected solar radiation from the outer primary reflectors that would otherwise have struck the solar receiver and tertiary reflectors had the secondary reflector not been present.

Abstract: The present application provides a primary reflector in a solar collection system. The primary reflector includes a first reflective section that can reflect solar rays onto a first focal line, a second reflective section on the left side of the first reflective section, and a third reflective section on the right side of the first reflective section. The second reflective section can reflect solar rays to the right side of the first focal line. The third reflective section can reflect solar rays to the left side of the first focal line.

Abstract: A parabolic primary mirror (10) has a concave specular surface (12) that is constructed and positioned to receive solar energy and focus it towards a focal point. A secondary mirror (14) having a convex specular surface (16) is constructed and positioned to receive focused solar energy from the primary mirror and focus it onto an annular receiver (18). The annular receiver (18) may include an annular array of optical elements (100) constructed to receive solar energy from the secondary specular surface (14) and focus it onto a ring of discrete areas. A ring of solar-to-electrical conversion units are positioned on the ring of discrete areas.

Abstract: Provided is a device for supporting a center reflector stably and firmly. The device improves the setting density of heliostats and is capable of reducing the blocking and the shadowing of the beams of light reflected by the heliostats. In a beam down system solar generation device, the center reflector is attached, in a cantilever manner, to a supporting post standing upright. A pylon is provided to stand on the top of the supporting post. A stay member is attached to the pylon and is used for fixing the center reflector. A second stay member is provided to support the supporting post. This second stay member connects: the pylon; a jut extending out from the back side of the supporting post; and a base.

Abstract: A solar panel system (10) comprising a solar panel (12) to be fixedly located such as to receive sunlight from a first direction (A), and a light guidance device (15) having an inlet (16) for receiving sunlight and an outlet (18) for projecting light, said light guidance device (15) having an operative or in use condition in which it is positioned with its inlet (16) directed in a second direction (B), and with its outlet (18) directed to project light therefrom towards the solar panel (12).

Abstract: The present invention is that of a solar energy system that uses a light-guide solar panel (LGSP) to trap light inside a dielectric or other transparent panel and propagates the light to one of the panel edges for harvesting by a solar energy collector such as a photovoltaic cell. This allows for very thin modules whose thickness is comparable to the height of the solar energy collector. This eliminates the depth requirements inherent in traditional concentrated photovoltaic solar energy systems.

Abstract: Solar energy may be harvested utilizing arrays of solar collectors, supported and articulated to follow movement of the sun. Particular systems include arrays of solar collectors mounted on an elevation-azimuth tracking structure. From the ground up, embodiments of this system may include a Ground Interface, a Base, an Upper Truss, and a Collector. The system is designed to transmit loads with minimal deflection from the surface of the collector to the ground, while tracking the position of the sun across the sky. The use of structural, actuator, and collector elements with a minimum amount of low-cost materials, and which are able to be mass produced, allows large scale deployment of the system at reduced cost.

Abstract: A system for releasing and capturing gases from a regolith material has a frame that is movable to define a capture space on a regolith material. A mirror captures solar energy, and focuses energy through a lens and on a regolith defined within the captured space. Apparatus is provided for capturing released gas. A method of operating such a system is also disclosed and claimed. In addition, a method of forming structural material is also disclosed and claimed.

Abstract: A hybrid solar lighting distribution system and components having at least one hybrid solar concentrator, at least one fiber receiver, at least one hybrid luminaire, and a light distribution system operably connected to each hybrid solar concentrator and each hybrid luminaire. A controller operates all components.

Abstract: A novel method of concentrating solar energy using wave generators is disclosed. The systems and methods enable the collection of energy over large area at high efficiencies and the concentrating of energy at a target for use and transfer.

Abstract: A solar concentrator having a concentrator element for collecting input light, a redirecting component with a plurality of incremental steps for receiving the light and also for redirecting the light, and a waveguide including a plurality of incremental portions enabling collection and concentration of the light onto a receiver. Other systems replace the receiver by a light source so system optics can provide illumination.

Abstract: Certain embodiments make use of an array of passive primary concentrators positioned on the ground that provide primary concentrated solar radiation from below to an array of tracking secondary concentrators. The secondary concentrators further concentrate the solar radiation to one or more centralized receivers. The solar concentrator system may include apparatus for collection of solar radiation, concentration, and the absorbance of the concentrated solar energy. Some embodiments of the solar concentrator system include a large field of passive horizontal primary concentrators, overhead tracking secondary concentrators, and one or more receivers, which convert solar radiation into usable products or energy, such as electricity.

Abstract: 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. A solar reflector assembly comprises an inflatable elongated tube having an upper portion formed at least partially of flexible material and a lower ballast portion formed at least partially of flexible material. A reflective sheet is coupled to a 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.

Abstract: A solar collection apparatus includes a housing with a first opening, a second opening, and a partially-mirrored floor. The device includes fins with first and second end segments and curved bodies. Both sides of the fin bodies have the same curvature, and both sides are mirrored. The curved bodies of the fins all have the same curvature. The floor and the second end segments of the fins together define a light pipe. Light impinging on the first opening of the housing is directed into the light pipe by reflection between adjacent faces of adjacent fins. The second end segments of the fins prevent the light within the light pipe from exiting the light pipe in the first direction. Light within the light pipe exits the light pipe at the second opening, where it may be stored, or may be directed to a solar energy device such as a solar cell, turbine, or vehicle heater.

Abstract: The present invention is that of a solar energy system that uses a light-guide solar panel (LGSP) to trap light inside a dielectric or other transparent panel and propagates the light to one of the panel edges for harvesting by a solar energy collector such as a photovoltaic cell. This allows for very thin modules whose thickness is comparable to the height of the solar energy collector. This eliminates eliminating the depth requirements inherent in traditional concentrated photovoltaic solar energy systems.

Abstract: The invention concerns a non-tracking solar collector which includes laterally spaced, radiation-transmitting prisms (26) which are wedge-shaped in cross-section. Each prism (26) has major side surfaces (28, 30) converging at an acute angle (32) to a relatively narrow end (34) of the prism (26), and an opposite, relatively wide end (36). For each prism (26) there is a refractor (22), typically a linear refractor such as a linear Fresnel lens, arranged over the prism (26) to refract solar radiation incident thereon onto the major side surfaces (28, 30) of the prism (26), as the sun moves relative to the earth, at angles allowing such radiation to enter the prism (26) and be internally reflected towards a target (38) at the relatively wide (36) end of the prism (26). The refractors (22) are spaced laterally apart from one another, possibly by intermediate, radiation transmitting panels (24) which are continuous with the refractors (22).

Abstract: Provided herein are linear solar reflectors and collectors, and methods of efficiently constructing such reflectors and collectors. The reflectors are made using reflective laminate sheets, which can be reinforced by tension-bearing strips. Methods and apparatuses for installing the sheets from a roll dispensing the sheets carried on a deployment vehicle are disclosed, as well as methods and apparatuses for assembling and constructing various collector components, methods and apparatuses for tensioning the reflective laminate sheets, methods and apparatus for passively changing the focal length of the reflectors while controlling their movement to track the sun, and methods and apparatuses for compensating for temperature changes in system components for moving the collectors, are provided.

Abstract: A solar collecting apparatus for collecting solar energy in a heat transfer fluid includes an upper header member, a lower header member, and a plurality of collector tubes, each collector tube connected at an upper end thereof to the upper header member and connected at a lower end thereof to the lower header member. The collector tubes are arranged such that axes of the collector tubes form an array wherein no three adjacent axes are on the same plane, typically in a cylindrical or like array.

Abstract: A solar collector system including solar elements connected to form an array for intercepting the sun's radiation, a compression element that is positioned substantially perpendicular to the array, and pairs of cables that run from opposite sides of the array to the compression element to mutually stabilize each portion of the array to which the pair of cables connects. A support structure is provided for securing the array to a fixed structure. A tracking system further provides the system with two degrees of freedom for tracking the array with the sun's movement.

Abstract: An apparatus for collecting sunlight includes a primary focus reflector, a secondary parallelization reflector, and a connection mechanism. The primary focus reflector has an inner rounded surface, an outer plane formed on an edge of the inner rounded surface, and a through-hole formed at a center of the inner rounded surface. The primary focus reflector collects sunlight on a focus in front of the inner rounded surface. The secondary parallelization reflector is disposed near the focus in front of the primary focus reflector and reflects the sunlight, having been reflected by the primary focus reflector towards the through-hole as parallel light. The connection mechanism connects the secondary parallelization reflector to the primary focus reflector to be secured near the focus. The apparatus further includes a power generation module disposed behind the reflectors. The apparatus has improved light collection and power generation efficiency.

Abstract: This invention absorbs available heat from the flue gas of an existing building's heating system and heat from the sun. The heat is absorbed and stored in a heat-collecting sphere of special design. The absorbed heat collected in the sphere is transferred, by the conventional refrigeration cycle, to the heat exchanger located at the air inlet to the building heating system. The refrigerant liquid is sprayed into the collecting sphere, as it absorbs heat, it evaporates and changes into a gas. The refrigerant compressor transfers the gas from the heat-collector to the heat exchanger. The existing heater fan draws air across the heat exchanger finned coil removing heat from the refrigerant. The refrigerant gas gives up heat and is condensed. The heated air combines with the existing furnace air to heat the existing building. The refrigerant liquid from the heat exchanger is transferred to the heat-collecting sphere spray nozzles.

Abstract: A solar concentrator having a concentrator element for collecting input light, a reflective component with a plurality of incremental steps for receiving the light and also for redirecting the light, and a waveguide including a plurality of incremental portions enabling collection and concentration of the light.

Abstract: A solar concentrator having a concentrator element for collecting input light, a redirecting component with a plurality of incremental steps for receiving the light and also for redirecting the light, and a waveguide including a plurality of incremental portions enabling collection and concentration of the light onto a receiver. Other systems replace the receiver by a light source so system optics can provide illumination.

Abstract: A parabolic primary mirror (10) has a concave specular surface (12) that is constructed and positioned to receive solar energy and focus it towards a focal point. A secondary mirror (14) having a convex specular surface (16) is constructed and positioned to receive focused solar energy from the primary mirror and focus it onto an annular receiver (18). The annular receiver (18) may include an annular array of optical elements (100) constructed to receive solar energy from the secondary specular surface (14) and focus it onto a ring of discrete areas. A ring of solar-to-electrical conversion units are positioned on the ring of discrete areas.

Abstract: A collector for propagating incident radiation is disclosed. The collector may comprise a light directing component coupled to a buffer component, a first propagation component coupled to the buffer component and configured to transmit the incident radiation into a collector region through one of a plurality of windows, and an optical transport assembly coupled to an end of the collector region and having a second propagation component. Each light directing component may be configured to redirect the incident radiation from a first direction to a second direction, and the collector region may include a plurality of regions exhibiting a refractive index value that gradually transitions from about 1.5 to about 2.0. The second propagation component may be further configured to retain the incident radiation.

Abstract: A system is provided for maximizing solar energy utilization by moving a solar panel to track movement of the sun from sunrise to sunset. Preferably, the solar panel is inclined from the horizontal plane by a fixed angle of about ten degrees. And, movements of the solar panel are accomplished, daily, in accordance with a programmed schedule of consecutive cycles. In this schedule, each cycle has a start time (i.e. sunrise) and a start point that is determined by the sun's direction from the solar panel.

Abstract: A solar collection apparatus includes a housing with a first opening, a second opening, and a partially-mirrored floor. The device includes fins with first and second end segments and curved bodies. Both sides of the fin bodies have the same curvature, and both sides are mirrored. The curved bodies of the fins all have the same curvature. The floor and the second end segments of the fins together define a light pipe. Light impinging on the first opening of the housing is directed into the light pipe by reflection between adjacent faces of adjacent fins. The second end segments of the fins prevent the light within the light pipe from exiting the light pipe in the first direction. Light within the light pipe exits the light pipe at the second opening, where it may be stored, or may be directed to a solar energy device such as a solar cell, turbine, or vehicle heater.

Abstract: The present embodiments provide methods and systems to homogenize illumination on a target.

Abstract: A solar concentrator having a concentrator element for collecting input light, a reflective component with a plurality of incremental steps for receiving the light and also for redirecting the light, and a waveguide including a plurality of incremental portions enabling collection and concentration of the light.

Abstract: A solar concentrator includes a mirror 24 having a frame 27 connected with a lever 55, a train 36 supporting the frame 27 and the lever 55, a first control cable 28 connected with the frame 27, and a second control cable 30 connected with the lever 55. A first locomotive 35 moves the train along a curvilinear path to keep the mirror 24 opposite the sun. The first control cable 28 controls pitch of the mirror 24 and the second control cable 30 controls yaw of the mirror 24. When a concentrator includes a plurality of mirrors 24 they are preferably controlled collectively by pulling all of the first control cables 28 with one motor to control pitch and by pulling all of the second control cables 30 with one motor to control yaw. Sunlight focused on the receiver 20 preferably boils water to form steam that is transmitted to a turbine connected to a generator for producing electricity.

Abstract: A collector for propagating incident radiation to a remote location. The collector comprises, a light directing component coupled to a buffer component, a first propagation component coupled to the buffer component and configured to transmit the incident radiation into a collector region through one of a plurality of windows, and an optical transport assembly coupled to an end of the collector region and having a second propagation component. Each light directing component is configured to redirect the incident radiation from a first direction to a second direction, and the collector region includes a plurality of regions exhibiting a refractive index value that gradually transitions from about 1.5 to about 2.0. The second propagation component is further configured to retain the incident radiation.

Abstract: A method to enhance oil shale, oil sand, asphaltic crude oil, or other high viscosity crude oil production by using a solar blackbody waveguide to heat these formations in situ. A parabolic mirror collects and directs the solar flux into a vertical shaft of a well drilled into the formation. This vertical shaft is lined with a reflective sleeve that reflects nearly all of the sunlight down into the well bore. The reflective sleeve ends at the top of the formation so that below this point, the solar flux is permitted to make successive reflections with the interior of the metal well casing or solar blackbody waveguide coil. The coil absorbs the solar flux, converting it to heat. Heat from the coil is transferred by conduction into the formation and allowing the formation to be produced by traditional methods.

Abstract: A hybrid solar lighting system and components having at least one hybrid solar concentrator, at least one fiber receiver, at least one hybrid luminaire, and a light distribution system operably connected to each hybrid solar concentrator and each hybrid luminaire. A controller operates each component.

Abstract: The present invention includes a radiation collector configured to collect incident radiation. The radiation collector includes a radiation directing component configured to redirect the incident radiation, a buffer component configured to receive the radiation redirected by the radiation directing component, and a propagation component configured to receive the radiation from the buffer component and to propagate the radiation towards a first end of the propagation component.

Abstract: Method and system for converting solar energy into electrical energy utilizing serially coupled multijunction-type photovoltaic cells in conjunction with a form of spectral cooling. The latter cooling is carried out by removing ineffective solar energy components from impinging concentrated light, inter alia, through the utilization of dichroics or the conversion of ineffective solar energy components to effective energy components by means of luminescence, phosphorescence, or fluorescence. Ineffective solar energy components are described as those exhibiting wavelengths outside the bandgap energy defined wavelength and an associated wavelength defined band of useful photon energy.

Abstract: A solar blackbody waveguide that captures and uses sunlight to heat a thermal working or heat transfer fluid. Solar cell arrays capture the sunlight. The arrays are movably mounted on solar towers to track the daily movement of the sun and to maintain the proper angle with the horizon throughout the year. The arrays direct the light into a series of light pipes to deliver the light into a solar coil located within an underground insulated pipeline. Energy from the light rays is absorbed by the solar coil and transferred to the thermal working fluid or heat transfer fluid flowing between the solar coil and the insulated pipeline. The energy laden thermal working or heat transfer fluid is removed from the downstream end of the insulated pipeline so that it can be used with existing technologies, such as with a combined cycle gas turbine, boiler, or steam generator.

Abstract: The present disclosure relates to an absorber element for solar high-temperature heat generation. The absorber element includes a light focusing unit, an outer tube composed of a translucent material and an absorber which is arranged in the absorber element. The absorber is surrounded by at least one reflector channel having an opening gap. A focal line of the light focusing unit lies on a center axis of the outer tube and the absorber does not lie on the center axis of the outer tube. The opening gap of the at least one reflector channel, through which the solar rays fall on the absorber, lies on the center axis of the outer tube, and hence on the focal line.

Abstract: There is disclosed herein a concentrating solar energy receiver comprising a primary parabolic reflector having a center and a high reflectivity surface on a concave side of the reflector and having a focal axis extending from the concave side of the reflector and passing through a focal point of the primary parabolic reflector; and a conversion module having a reception surface wherein the reception surface is spaced from the focal point by a predetermined distance and disposed to receive a predetermined cross section of radiant solar energy reflected from the concave side of the primary parabolic reflector for conversion to electrical energy in the conversion module. In one aspect, the conversion module includes a reception surface comprising a planar array of at least one photovoltaic solar cell. In another aspect, the conversion module includes a reception surface coupled to a thermal cycle engine. The mechanical output of the thermal cycle engine drives an electric generator.

Abstract: A high concentration central receiver system and method provides improved reflectors and a unique heat removal system. The central receiver has a plurality of interconnected reflectors coupled to a tower structure at a predetermined height above ground for reflecting solar radiation. A plurality of concentrators are disposed between the reflectors and the ground such that the concentrators receive reflective solar radiation from the reflectors. The central receiver system further includes a heat removal system for removing heat from the reflectors and an area immediately adjacent the concentrators. Each reflector includes a mirror, a facet, and an adhesive compound. The adhesive compound is disposed between the mirror and the facet such that the mirror is fixed to the facet under a compressive stress.

Abstract: A solar energy concentrator is formed in the shape of a spiral horn, so that solar energy incident over a wide range of incident angles on the mouth of the horn is concentrated by multiple reflections from inner walls of the horn to emerge from an exit aperture at the centre of the horn. Solar energy emerging from the collector may be distributed by light pipes to illuminate a building or may be transmitted to a solar energy conversion chamber having a small entry aperture. The entry aperture acts as black body absorbing all solar energy incident upon it and the solar energy may be converted within the chamber either by photovoltaic cells and/or by heat absorbing media.

Abstract: The invention relates to an absorber element for solar high-temperature heat generation, having a light focusing element, an outer tube composed of a translucent material and an absorber which is arranged in it. The absorber is surrounded by at least one reflector channel having an opening gap. The focal line of the light focusing unit runs on the centre axis of the outer tube and the absorber does not lie on the centre axis of the outer tube. The opening gap of the reflector channel, through which the solar rays fall on the absorber, lies on the centre axis of the outer tube, and hence on the focal line.

Abstract: A method and high concentration central receiver system provide improved reflectors and a unique heat removal system. The central receiver has a plurality of interconnected reflectors coupled to a tower structure at a predetermined height above ground for reflecting solar radiation. A plurality of concentrators are disposed between the reflectors and the ground such that the concentrators receive reflective solar radiation from the reflectors. The central receiver system further includes a heat removal system for removing heat from the reflectors and an area immediately adjacent the concentrators. Each reflector includes a mirror, a facet, and an adhesive compound. The adhesive compound is disposed between the mirror and the facet such that the mirror is fixed to the facet under compressive stresses.