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: Disclosed are a solar cell having a fan structure that provides a more pleasant life, convenience, and stability by forming, in a fan structure, a flexible color solar cell applied with a carbon dioxide absorption material, and configuring the formed flexible color solar cell through convergence of information technology, and an electronic application apparatus using the same. The electronic application apparatus using a solar cell as a power source includes: an application device body portion including a both side supporter fixed to ground, a transmitter including an antenna capable of transmitting power and data, and a data screen to thereby provide a predetermined service; and the solar cell provided in an upper end of the application device body portion, to color using a predetermined wavelength of light, and to perform solar power generation using a remaining wavelength of light.

Abstract: A light intensity detection system for a wind turbine including a single light sensor adapted to measure the intensity of light, a housing for protecting the single light sensor from environmental influences, and a driving mechanism configured to allow the single light sensor to receive light from a first direction at a first time and from a second direction at a second time.

Abstract: An end member for a gas spring assembly can include a first end, a second end opposite the first end and a plurality of reflector surfaces formed along the first end. A first reflector surface can extend from the first end toward the second end. A second reflector surface can extend from adjacent the first reflector surface toward the second end. One or more of the plurality of reflector surfaces can include a plurality of facets or reflector zones. A gas spring assembly including at least one of such end members and a suspension system including one or more of such gas spring assemblies are also disclosed.

Abstract: Images representative of cloud shadows with respect to a field of heliostats can be used to adjust operation of a solar energy system. For example, images of a field of heliostats and shadows produced by the clouds can be obtained. Additionally or alternatively, images of the sky and clouds can be obtained. The images can be analyzed to determine a shading parameter. Based on the shading parameter, an operating parameter of the solar energy system can be changed or maintained. For example, the operating parameter may include aiming directions for one or more of the heliostats. Cloud characteristics in addition to the location of the cloud shadow can be used in determining the shading parameter. Such characteristics can be used in determining if and/or how to change the operating parameter of the solar energy system.

Abstract: A sun tracking device comprises a light sensing module, a processing module, a control module, and a driving module. The light sensing module includes eight light sensors, a pole fixing portion, and a pole. The eight light sensors each have a light sensing surface. The pole fixing portion has a fixing surface. The eight light sensing surfaces and the fixing surface cooperatively form a 3×3 grid, and the fixing surface is in the middle of the grid. The pole extends from the fixing surface. The processing module is configured for determining the direction of the sun, and calculating a rotating direction and angle of the light sensing module. The control module is configured for sending out a rotating instruction. The driving module is configured for driving the light sensing module to rotate so that the sunlight perpendicularly shines onto the light sensing surface.

Abstract: A device (1) for concentrating solar radiation in an absorber (2), an anchoring frame (8) and an inflatable concentrator pad (3), which has a light-transmissive entry window (4) for coupling in the solar radiation and a reflector film (5) subdividing the concentrator pad (3) into at least two cavities (6, 7), wherein the reflector film (5) is designed to concentrate the solar radiation in the absorber (2) which is arranged in the cavity (6) of the concentrator pad (3), and with an anchoring frame (8), arranged outside of the concentrator pad (3), for anchoring the concentrator pad (3), wherein the absorber (2) is attached to the anchoring frame (8) by means of an absorber mount (15) and the concentrator pad (3) has at least one attachment opening (26) for the absorber mount (15) to pass through.

Abstract: A sun tracking mechanism is provided for solar power generation, including a power unit, a linear actuator and at least two universal joints. The sun tracking mechanism outputs an angle of high precision by two axial directions provided from the universal joints, the power unit and the linear actuator. A solar power module disposed on the sun tracking mechanism generates electricity in the best light incident angle. In addition, the linear actuator provides an auxiliary supporting force to improve the wind-resistant capability.

Abstract: A solar collector positioning apparatus including a base structure and an intermediate frame connected to the base structure by at least two base support legs. The base support legs have a hinged connection to the base structure and a hinged connection to the intermediate frame, thereby constraining the movement of the intermediate frame to a plane substantially orthogonal to a plane occupied by the base structure. A solar collector support frame is connected to the intermediate frame by at least two intermediate support legs. The intermediate support legs have a hinged connection to the solar collector support frame and a hinged connection to the intermediate frame, thereby constraining the movement of the solar collector support frame to a plane substantially orthogonal to a plane occupied by the intermediate frame.

Abstract: Described herein are solar energy collector systems, components for solar energy collector systems, and methods for installing solar energy collector systems. The components for solar energy collector systems include but are not limited to solar radiation absorbers, receivers, drives, drive systems, reflectors, and various support structures. The solar energy collection systems, solar radiation absorbers, receivers, drives, drive systems, reflectors, support structures, and/or methods may be used, for example, in LFR solar arrays. Drives and drive systems are described herein that may provide improved rotational positioning, movement, and/or rotational positional sensing. For example, drives and drive systems are provided which allow operation through a variable frequency drive. The components and methods described herein may be used together in any combination in a solar collector system, or they may be used separately in different solar collector systems.

Abstract: The invention relates to a bearing arrangement (1), in particular for bearing the carrying shaft (30) of a parabolic trough collector (26), having a disc- or ring-shaped component (3), at least one support roller (5), which radially fixes the component (3) and on which the component (3) rolls on the circumferential side during rotation about a rotation axis (2), and a support structure (6), on which the support roller (5) is mounted by a radial sliding bearing (8). According to the invention, the lateral surface (12) of the support roller (5) which receives the component (3) has a convex curve in the axial direction. The invention further relates to parabolic trough collector (26) mounted on a plurality of such bearing arrangements (1).

Abstract: A housing has a bottom, side panels, end panels, and a top, forming a chamber. The side and end panels have interior sections and slidable exterior sections. A solar energy collector, tubing or solar panels, is within the chamber. A cover plate is fabricated of a transparent material and is secured to the exterior section adjacent to the top. Lenses are coupled to the exterior section, and focus sunlight on the solar energy collector. Lift drivers vary the elevation of the lenses with respect to the solar energy collector. A gimbal assembly with a tilt driver operatively couples the housing to the roof to vary the angular tilt of the housing. A light sensor, a temperature sensor, and an associated controller adjust the elevation of the lenses and the tilt of the housing.

Abstract: A lightweight reflector with a load bearing structure based on a tensile spoke-wheel. The spoke structure is especially compatible with dish parabolic mirrors, but has utility as a carrier structure for any round functional surface, including flat or slightly-curved mirrors used in central tower solar systems, parabolic dishes for radio telescopes and antennas, and for non-concentrating thin film solar panels. There are no radial members loaded in compression. All the spokes pull the rim inwards, and the rim is compressed in the circumferential direction. The imbalance in spoke tension results from the application of load provides the rigidity of the rim in respect to the hub, both for in-plane and out-of-plane forces. Ribs stiffen the spokes to resist wind and gravity, but are not structurally supported by either the hub or the rim. Lightweight reflector tiles match the wheel structure and create the reflective surface.

Abstract: A solar thermal lamp used for heating water inside a tank. The thermal lamp includes a transparent glass bulb with a threaded male coupling for attaching to a female coupling in the tank. The lamp also includes a heat tube with an enlarged water heating condenser. The condenser is received inside the tank. The heat tube can include a copper coil, copper fins, a glass coil, a copper lamp, a glass lamp, and the like for receiving solar energy and conducting the heat to the heating condenser for heating the water inside the tank. Also, the invention can be in the form of a solar thermal globe. The solar globe is self-contained and includes a water tank. Another embodiment of the globe tracks with the daily movement of the sun and change with seasons.

Abstract: A linear solar energy collector system includes reflective lines arranged in parallel in a south-north direction, heliostats mounted on the reflective lines, respectively, each comprised of mirror segments to reflect solar radiation, a light receiving line set above the reflective lines in a east-west direction, a receiver mounted on the light receiving line, to receive light reflected from the heliostats and collect heat from the light, and an angular adjuster to adjust angles of the mirror segments individually to irradiate a same light receiving area on the receiver with the reflected light from east-west neighboring reflective lines and thereby adjust a concentration ratio.

Abstract: A movable solar array and method for capturing solar energy which includes a V-shaped longitudinal support forming a corner of an elongated truss located at each angle of a polygonal axial cross-section where an open web is fixedly attached between each V-shaped longitudinal support extending the length of the elongated truss. An end member is fixedly attached at each end of the support truss and includes a shaft extending longitudinally outwardly from the end member adapted to engage a drive to longitudinally rotate the elongated truss. Solar panels are attached along one face of the elongated truss, and at least one rotatable drive is capable of driving the shafts at the end of the elongated truss to move the solar panels in relation to a change of direction of incoming solar energy.

Abstract: A mechanical interface between the drive and support structure of a heliostat assembly for use in concentrated solar power applications. The heliostat drive is mounted to the support structure by inserting a drive post into a structure post, the structure post having grooves for interfacing with bolts or other fasteners attached to the drive post. The structure post has a plurality of grooves to allow for multiple heliostat orientation options. The heliostat assembly further includes a capsule containing a drive motor controller and cable-mounting features, wherein the capsule is inserted into the drive post and has a cable-positioning feature to provide egress of power and communication connectors from the drive through at least one groove.

Abstract: The present invention relates to a solar cooking apparatus, comprising: a first solar reflector; a second solar reflector; a solar collection element; and a solar collection element holder, wherein the first solar reflector and the second solar reflector are concave and parabolic, and are in a substantially symmetrical arrangement to a solar collection element axis, each reflector focuses solar radiation at the solar collection element from a reflective surface, which rapidly heat when the the solar collection element. The solar cooking apparatus is adjustable and, in some embodiments, portable.

Abstract: A drive mechanism for a solar concentrator assembly. In one embodiment, a drive mechanism for a linear solar concentrator assembly which includes an elongate reflector support frame which is rotatable about an axis which is parallel to the length of the frame and is defined by a support for the frame includes: a first elongate arm fixable at one end to the frame for rotation about the axis with the frame; a second elongate arm rotatable at one end about the axis independently of the first arm; a first reversible linear drive device coupled between the second arm and the first arm which is operable to rotate the first arm about the axis relative to the second arm; and a second reversible linear drive device coupled between the support and the second arm which is operable to rotate the second arm about the axis.

Abstract: A sun tracking system for tracking the sun in at least two axes, including a base, a rotating system mounted on the base, a spatial structure assembly having a lower portion at a first peripheral end thereof, and an upper portion at a second peripheral end thereof, the lower portion being more proximal to the base than the upper portion, and an anchoring location at the lower portion, and a torque box assembly at the anchoring location for resisting a torque applied to the spatial structure assembly.

Abstract: The present invention relates to a solar energy collector (18) including an outer casing (20) having at least one aperture (22) disposed therein and an absorber (24) disposed within the outer casing (20). The aperture (22) is arranged to receive a beam (16) of solar radiation therethrough so that the beam (16) is incident on the absorber (24). The absorber (24) is arranged in use to absorb the energy of the beam of solar radiation and to thereby convert solar radiation to heat energy to heat a fluid communicated through the absorber (24). The absorber (24) is arranged to be moved by a moving means to promote even heating of the absorber (24).

Abstract: In various aspects, a solar collector apparatus includes a lens pivotally mounted about an axis thereof and adapted to gather sunlight into a focal point, and a tracking device adapted to track a position of the sun, the tracking device cooperates with the lens to pivot the lens about the axis in correspondence to the position of the sun. Related methods of use of the solar collector apparatus are disclosed herein. This Abstract is presented to meet requirements of 37 C.F.R. §1.72(b) only. This Abstract is not intended to identify key elements of the apparatus and methods disclosed herein or to delineate the scope thereof.

Abstract: Systems and methods for directly monitoring energy flux of a solar receiver in a solar energy-based power generation system include measuring infrared radiation emanating from the solar receiver. Such measurement can be achieved using one or more infrared thermography detectors, such as an IR camera. Resulting thermal data obtained by the imaging can be used to determine energy flux distribution on the receiver. A user or a system controller can use the determined flux distribution to adjust heliostat aiming to achieve a desired operation condition. For example, heliostats can be adjusted to achieve a uniform energy flux distribution across the external surface of the receiver and/or to maximize heat transfer to a fluid flowing through the receiver within system operating limits.

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: A heliostat capable of collecting light with high efficiency and having reduced manufacturing and installation costs; and a method of controlling the heliostat. The heliostat includes a reflecting mirror configured to reflect sunlight; and a support mechanism configured to tiltably support the reflecting mirror. The support mechanism has a single supporting column and first and second cylinders. The reflecting mirror is supported at its back surface by a supporting column upper end of the supporting column, a first cylinder upper end of the first cylinder and a second cylinder upper end of the second cylinder in a tiltable manner, which are arranged to form a triangle on the back surface of the reflecting mirror. A gimbal bearing connects the supporting column upper end and the reflecting mirror, the gimbal bearing being configured to be tiltable in two axial directions intersecting with each other.

Abstract: A solar collection system is described that includes an elongate central truss angled upward from ground horizontal and mounted on a plurality of ground support legs, a collector subsystem mounted at one end of the central truss, a cross truss perpendicular to the central truss and mounted at an end of the central truss opposite the collector subsystem, and a reflector subsystem mounted on the cross truss. The collector subsystem includes a truncated trapezoid-shaped housing with a front side facing the reflector subsystem, the front side including a glassed-in opening fronting a V-shaped core heat mechanism enclosed within the housing interior that captures reflected photon energy from the reflector subsystem which heats a fluent medium within the V-shaped core heat mechanism for output to an external source for thermal power operations.

Abstract: An assembly is disclosed for adjusting the position of a solar array or device to enable it to maintain a desired solar energy reception throughout each day's operation of the assembly. Solar panels are mounted on a first axle and a second axle, and the axles are mutually orthogonal. The assembly also includes a first motor for rotating the array and the panels relative to the first axle in a direction providing azimuth angle position adjustment and a second motor for rotating the array and the panels and the second axle in a direction providing elevation angle position adjustment. The motors are electrically connected to and powered by their respective solar panels.

Abstract: A solar trough frame for holding solar mirrors includes a plurality of chords. The frame includes a plurality of extruded profiles, including chords, chord sleeves, struts, strut end pieces and mirror support pieces, each chord sleeve having at least one chord sleeve fin, each chord sleeve positioned about one of the chords. The frame includes a plurality of struts, at least one of the struts having a strut end piece having at least one strut fin that connects with a chord sleeve fin to connect the plurality of chords. The frame includes a platform supported by the chords and struts on which the solar mirrors are disposed. A chord sleeve for connecting a chord of a solar frame which supports solar mirrors to a strut end piece extending from a strut of the solar frame. A strut end piece for connecting the strut of a solar frame which supports solar mirrors to a chord sleeve of the solar frame. A method for linking a strut of a solar frame which supports solar mirrors to a chord of the solar frame.

Abstract: A system and method for providing real time control of a heliostat array or CPV/PV module that reduces actuation cost, the disclosure reduces the fixed cost of calibrating and repositioning an individual surface. This simultaneously removes the core engineering assumption that drives the development of large trackers, and enables a system and method to cost effectively track a small surface. In addition to lower initial capital cost, a small heliostat or solar tracker can be pre-assembled, mass-produced, and shipped more easily. Smaller mechanisms can also be installed with simple hand tools and do not require installers to rent expensive cranes or installation equipment.

Abstract: Systems and methods for solar steam generation are described. The systems and methods include moving at least one frame mounted optical focusing lens to track the sun in two axes and disposing a water boiler at a focus of each optical focusing lens. Raw water is pumped through an inlet at a bottom of each boiler and solar energy is concentrated, using each optical focusing lens, on each boiler, heating the raw water in each boiler and evaporating steam from the raw water. The steam exits each boiler, via a steam outlet pipe. Remaining salts and solids in each boiler are ground by rotation of salt grinding-cleaning gears. These ground salts and solids are drained and/or pumped out of each boiler from an exit in the bottom of each boiler.

Abstract: A solar tracking system and method that use a shielding tube that admits solar radiation and has an absorptive inner surface for absorbing the solar radiation that is incident on it. The system has a photodetector for generating a signal related to an intensity of solar radiation at a distal end of the shielding tube and a scan unit for periodically executing a certain scan pattern in an elevation angle El and in an azimuth angle Az of the shielding tube. A processing unit in communication with the photodetector determines an on-sun orientation of the shielding tube based on a convolution of the signal obtained while executing the scan pattern with a trained convolution kernel. The on-sun orientation thus found can be used to update the orientation of one or more solar surfaces, e.g., reflective or photovoltaic surfaces.

Abstract: A solar air heating module is provided including an air entrance situated proximate to a bottom of the module and an air exit situated proximate to the top of the module; a back film, having a plurality of conical solar collectors extending perpendicularly therefrom; a front film in contact with the collectors to prevent air from escaping between the entrance and the exit; wherein air, when entering the entrance, passes by the collectors to mix with heated air before reaching the exit. Alternatively the collectors may be aligned wherein each collector is secured to adjacent collectors by plates or a strap to allow the module to be folded or rolled up for storage.

Abstract: An solar energy harvester and method for controlling the solar energy harvester, in which an insolation collector is formed of one or more elements each having two opposite major sides, a first side and a second side, and being configured to collect energy from insolation incident on any of the first and second sides. A cradle enables installation of the insolation collector on a roof with the first side generally towards the sun independently of the form of the roof. One or more heliostats reflect insolation to the second side of the insolation collector. A controller controls the one or more heliostats to maintain reflected insolation incident on the collector and to decrease the reflected insolation incident on the collector when necessary to inhibit the insolation collector receiving insolation exceeding given threshold through its first and second sides.

Abstract: Disclosed is a method of making solar collector assemblies for photovoltaic conversion. The method comprises providing a mold for receiving encapsulant, the mold having serially arranged, alternating peaks and valleys. A respective PV solar cell is placed into each of a series of the valleys such that the light-receiving surfaces of the PV solar cells face upwards. Uncured encapsulant is delivered into the mold and onto the light-receiving surfaces, and from the light-receiving surfaces to a level at least as high as the peaks so as to form, above the light-receiving surfaces, optical concentrators for concentrating light received by the optical concentrators and directing the light to the light-receiving surfaces. The encapsulant is then cured.

Abstract: A low profile heliostat with elongated louvered mirror segments is provided. Its envelope of revolution has the shape of a flat disc to enable heliostat fields with very high ground coverage ratio. The heliostat's disc-shaped footprint rotates around a substantially vertical axis (akin to a carousel). The short dimension of the mirror segments is drastically shorter than the disc's diameter. Embodiments are described in which the motion relies on two concentric rings, which are individually rotated around a vertical axis. The lower ring acts as a platform providing mainly azimuth tracking, carrying the upper ring. The differential rotation between the upper ring and the lower ring is translated into a rotation of the mirror segments around a second, perpendicular, axis and used for elevation tracking. Disc-shaped heliostat with D-shaped cut-offs are described, to facilitate the required maintenance access even in highly dense heliostat fields.

Abstract: A solar collector apparatus includes a parabolic mirror configured to direct solar energy through a double convex lens and towards a linear set of secondary mirrors, each of the secondary mirrors positioned to direct the solar energy towards a solar collection target. The subsequent diversion achieved by the solar collector apparatus allows collection of solar energy several times denser than natural sunlight, and can be captured using a substantially compact system.

Abstract: Methods and apparatus are described for a two axis tracking mechanism for a concentrated photovoltaic system. Two or more paddle structures containing multiple CPV modules are installed onto each tilt axle on the common roll axle as part of the two-axis tracking mechanism's solar array. The two or more paddle structures couple across the common roll axle on that tilt axle. The common roll axle and each paddle assembly are manufactured in simple modular sections that assemble easily in the field while maintaining the alignment of the tracker assembly.

Abstract: A novel portable solar energy system includes a solar concentrator, a thermal storage device, an azimuth adjustment system, an elevation system, and a heat exchanger, all mounted on a rotatable support frame. In a particular embodiment, the thermal storage device remains at a fixed vertical height and fixed tilt orientation when adjustments are made to the azimuth adjustment system and/or the elevation adjustment system.

Abstract: A tilt-able-central-planar-reflector, a tilt-able-auxiliary-left-planar-reflector, and a tilt-able-auxiliary-right-planar-reflector are hingely attached to a solar-absorbing-thermal-mass. The sun's light is made horizontal to reflect to the interior wall of a reflecting-curved-overhang, capturing the sun's sunrise light and sun's sunset light, and to reflect to the interior wall of a reflecting-parabolic-half-shell capturing the sun's noon light, so as to redirect the sun's light to a solar-absorbing-thermal-mass. The net result provides heat 24 hours a day, 7 days a week for utilization.

Abstract: A positioning system is attached to radiation collection device such as a solar oven. The positioning system is attached to an outside of a building structure, allowing the collection device to be positioned in a plurality of locations. At least one of the plurality of locations is away from the building structure to allow the radiation collection device to collect solar radiation.

Abstract: The invention relates to the field of solar energy usage and, particularly, to solar systems, which operate on the base of concentration of direct solar radiation. The invention proposes a radiation absorbing metal pipe intended for heating gaseous medium or gaseous-liquid mixture. The proposed radiation absorbing metal pipe is constructed from perforated plates. These plates are provided with inclined or two-stage upright rims. The plates are stacked and sealingly joined with formation of a tubular unit. Such tubular units with absorbing coatings of their external surfaces can be applied in following solar thermal systems: parabolic trough collectors; solar thermal collectors with usage of linear Fresnel reflectors; for a system with an array of tracking mirrors and a central receiver mounted on a tower or on the ground.

Abstract: A solar energy collector system includes a base, and a parabolic trough collector carried by the base for reflecting sunlight to a longitudinal focal line. The parabolic trough collector includes a center section horizontally positioned with respect to ground, and opposing end sections adjacent the center section. Each end section is angled towards the ground. A conduit is positioned along the longitudinal focal line to receive the reflected sunlight. The conduit circulates a heat transfer liquid therethrough to be heated by the reflected sunlight.

Abstract: A support system for holding solar mirrors of a solar trough system includes a frame for supporting the mirrors. The system includes a rib attached to the frame. The system includes at least a first roller engaged with the rib along which the rib moves as the frame moves. A method for moving a frame supporting solar mirrors of a solar trough system includes the steps of moving the frame on a roller guided by a rib engaged with the roller and attached to the frame bottom to a first position. There is the step of moving the frame on the roller guided by the rib engaged with the roller and attached to the frame bottom to a second position. A roller for engaging with a rib attached to a frame that holds mirrors of a solar trough system. A rib for a frame that holds solar mirrors of a solar trough system which engages with a roller. A support system for mirrors of a solar trough system.

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 tracker drive system is provided for rotatably driving one or more objects, for example solar panels or other equipment. The system comprises a torque element mounted for rotation about a generally horizontal axis, wherein the torque element can support one or more objects for rotation therewith about the generally horizontal axis; a lever arm connected with the torque element, the lever arm being movable to rotate the torque element; a movable drive member that is drivable by a drive mechanism; and a dynamic coupler coupling the drive member with the lever arm such that the lever arm is drivable by the drive member to rotate the torque element.

Abstract: A solar collection device includes a solar energy collector assembly being received and supported by a base. The solar energy collector assembly includes: a plurality of lenses secured within an elongated holder. Positioned concentric to the axis of the holder is a cylindrical glass shroud through which a tube passes. A first end of the tube, which is preferably formed of a high thermally transmissive metal, receives a supply of water, which is heated within the evacuated glass shroud by sunlight passing through the lenses and being focused onto the tube. The solar collector assembly is rotatably mounted to the base and may be caused to rotate at a slow speed by a drive means, or may be rocked at a slow speed. The elongated holder may be cylindrical, or may have a polygonal cross-sectional shape, with lenses staggered along each side of the holder to increase collection capability.

Abstract: Tracker support system (1) for solar sensor comprising:—a fixed structure (2) for anchoring to the ground exhibiting several anchoring points (21) defining an anchoring plane and separated from one another by distances termed ground prints, including a larger ground print distance (DE) established between at least two anchoring points (21); and—a movable structure (3) comprising:—a first armature (4) mounted rotatably on the fixed structure (2) according to a vertical axis of rotation (AV); and—a second armature (5) defining a support plane for the solar sensors and mounted rotatably on the first armature (4) according to a horizontal axis of rotation (AH) extending to a distance termed the zenith height from the anchoring plane; said tracker support system (1) being noteworthy in that the ratio of the largest ground print distance (DE) to the zenith height is included in a span ranging from 0.5 to 1.5, and preferably in a span ranging from 0.8 to 1.2.

Abstract: Systems, methods, and apparatus by which solar energy may be collected to provide electricity or a combination of heat and electricity are disclosed herein. Examples of solar energy receivers are disclosed that may be used to collect concentrated solar radiation.

Abstract: A steam or vapour condensing system (10) for use with radiant solar energy collecting apparatus (17) of the type having solar energy concentrators (20) and in which steam or vapour is generated for supply to a load such as to a steam turbine, the system (10) using the solar energy concentrators (20) to directly or indirectly radiate heat energy of exhaust steam or vapour from the load. The collecting apparatus (17) may float on a body of liquid (19) and heat energy of the exhaust steam or vapour is transferred to the body of liquid for example by being passed through a duct (23) in the body of liquid (19) and heat energy transferred to the body of liquid (19) is radiated by the concentrators (20).

Abstract: A solar tracking system is disclosed. The tracking system includes a tube rotatable around its end-to-end axis. A first support is coupled to the tube at a first location of the tube, and is coupled with a first base. A second support is coupled to the tube at a second location of the tube, and is coupled with a second base. A translation mechanism is coupled with the tube and provided to change the position of the first support relative to the second support.