Abstract: In one respect, disclosed is a device or system for solar irradiance measurement comprising at least two irradiance sensors deployed outdoors at substantially different angles, such that, by analysis of readings from said irradiance sensors, direct irradiance, diffuse irradiance, and/or global irradiance are determined. In another respect, the disclosed device or system may additionally determine ground-reflected irradiance.

Abstract: A solar tracking sensor includes lens and four fibers respectively representing four directions installed in a lens barrel to serve as a fine-positioning daylighting module, and four groups of fibers installed on the side of the lens barrel to serve as a coarse-positioning daylighting module. A circuit board and four photocells are installed at the bottom of a cassette. Each photocell is connected to fine positioning fibers located in the same direction as the photocell, and is connected to coarse positioning fibers located in a direction diagonal to the direction of the photocell. By using a daylighting method of combining fine-positioning daylighting and coarse-positioning daylighting, the number of the photocells is reduced, the design of the circuit board is simplified, and costs are reduced; moreover, because the coarse-positioning daylighting module can collect sunlight in a wide-angle range, the tracking angle range of the sensor is enlarged.

Abstract: The present invention relates to a solar energy harvesting device, said device including several single-axis solar trackers (S1-S5), each comprising an elongated structure (4) on which a plurality of photovoltaic panels (2) are installed, and a tubular rotating shaft (1) fixed to a lower side of the structure (4). A plurality of support feet (20) rotatably support the coaxially aligned tubular rotating shafts (1) of the several single-axis solar trackers (S1-S5) on the ground. A motor rotates the tubular rotating shafts (1) according to the relative movements of the Sun. Positive and negative wires (3a, 3b) conducting electrical energy generated by the photovoltaic panels (2) connected in series of the different single-axis solar trackers (S1-S5) are housed inside one or more of the tubular rotating shafts (1).

Abstract: A method comprising the steps of flowing a flow of relatively cold fluid along at least one photovoltaic solar panel being heated by solar energy towards and into a fluid treatment device, at least heating the flow of fluid in a fluid treatment device to divide the flow of fluid into a flow of a first fluid part and a flow of a second fluid part, flowing the flows of the first fluid part and the second fluid part from the fluid treatment device along the flow of relatively cold fluid. Before entering the fluid treatment device the flow of relatively cold fluid is preheated by the relatively warm photovoltaic solar panel and the relatively warm flow of the first fluid part and the relatively warm flow of the second fluid part.

Abstract: A CSP system including a reflector and a receiver for concentrating the solar radiation incident on the reflector onto the receiver, comprising a shadow blind and a shadow receiver as well as a colour and/or brightness digitizing sensor arranged to detect the shadow of the shadow blind on the shadow receiver in order to determine a deviation of the actual shadow position from a target shadow position, a tracking means configured to adapt the position of the reflector and the receiver according to the deviation.

Abstract: A solar positioning system configured to position a body, such as, but not limited to, a solar module, perpendicular to incoming solar energy to maintain an optimal angle of incidence with efficacy is disclosed. The solar positioning system may include a support subsystem having a first mechanism for controlling rotational adjustments about a first axis and a second mechanism for controlling rotational adjustments about a second axis, thereby controlling pan and tilt adjustment. Positioning of the support subsystem may be controlled by a plurality of infrared sensors similarly oriented. A differential amplifier and a comparator may be coupled between the sensor subsystem and an integrated circuit to ignore brief flashes of light. The solar positioning system may also be used with a solar positioning control system to control the position of two or more solar modules, such as hundreds of solar modules in a solar farm.

Abstract: The solar power generating device according to the present invention comprises: solar cell modules disposed in a plurality of rows and columns; and an inclination control member for controlling the inclination angle of all the solar cell modules at a time, wherein the inclination control member comprises: a support part for supporting the solar cell modules; a control part, disposed on the support part, for controlling the inclination angle of the solar cell modules; and a driving part for driving the control part. In the solar power generating device according to an embodiment, the solar cell modules connected to the support unit can be vertically moved at one time by the inclination control member. In other words, the inclination control member can vertically control the plurality of solar cell modules, which are connected to the inclination control member, at a time according to the altitude of the sun so as to optimize the incident light.

Abstract: A self-powered light seeking apparatus and method for directing a target-plane towards a light source. The apparatus includes a photovoltaic powering arrangement configured to convert light energy into a driving current to power an actuator. The actuator is coupled to a support platform and is wired to the photovoltaic powering arrangement such that the polarity of the driving current causes the actuator to drive the target-plane towards alignment with the light source. A solar energy collection system including a photoelectric assembly for generating electricity from light incident upon an active area; a light concentrator comprising a substantially planar reflective surface subtending an angle to the active area such that light arriving along a line perpendicular to the active area and striking the reflective surface is reflected onto the active area; and a cooling unit configured to maintain the photoelectric assembly at an efficient operating temperature.

Abstract: A drive assembly for a heliostat is described, wherein the drive assembly may be configured to dynamically adjust the position of an attached reflector in concentrated solar power applications. The drive assembly may be further configured to provide for biasing of the reflector to reduce backlash due to external loads. The biasing force may be provided by at least one of a spring, counterweight, or offset of the center of gravity of the reflector or other attachment, or some combination thereof.

Abstract: A solar energy collection system comprises a frame for mounting the system on a suitable substrate and a plurality of solar panels disposed adjacent to one another on the frame. A first set of the solar panels are movable relative to a second set of the solar panels, for tracking movement of the sun during the day. Solar panels of the first set are arranged in alternating fashion with solar panels of the second set. In some embodiments of the invention, the panels in the second set of solar panels are stationary. The second set of solar panels, in some embodiments, are disposed substantially flat, relative to the frame and the substrate on which the frame is mounted. In some embodiments, differing from those in which the second set of solar panels are stationary, the second set of solar panels may be arranged to be movable relative to the first set of solar panels.

Abstract: The disclosure generally relates to concentrating daylight collectors and in particular to a light concentrator alignment system that can detect and correct for misalignment of the solar concentrator. The present disclosure generally relates to concentrating daylight collectors that can be used for illuminating interior spaces of a building with sunlight, and in particular to a light concentrator alignment system that can detect and correct for misalignment of the solar concentrator.

Abstract: A solar energy system for collecting and converting solar energy to electricity using photovoltaic devices. The system further includes reflective panels to concentrate incident solar energy onto an array of solar panels, as well as an automated sun tracking system to rotate the solar and reflective panels to follow the sun.

Abstract: The disclosure relates to a guide system for holding and moving sunlight-absorbing devices, in particular, solar panels or concentrated photovoltaic modules, about an azimuth axis and an elevation axis, comprising a housing, at least one azimuth drive, at least one azimuth gear unit, the azimuth drive being configured for driving the azimuth gear unit for a rotational movement about the azimuth axis, at least one elevation drive, at least one elevation gear unit, the elevation drive being configured for driving the elevation gear unit for a rotational movement about the elevation axis, and wherein the elevation gear unit is connected to a first end of a torsion tube, and the torsion tube is turnably mounted inside the housing along the elevation axis, wherein the torsion tube is supported by at least two bearings, preferably one at each end of the torsion tube, and wherein the second end of the torsion tube is configured to receive and connect to a support arm for carrying/supporting one or more of the sunlig

Abstract: A system and method of capturing solar energy, and related method of manufacturing, are disclosed. In at least one embodiment, the system includes a first lens array having a plurality of lenses, and a first waveguide component adjacent to the lens array, where the waveguide component receives light, and where the waveguide component includes an array of prism/mirrored facets arranged along at least one surface of the waveguide component. The system further includes at least one photovoltaic cell positioned so as to receive at least a portion of the light that is directed out of the waveguide. A least some of the light passing into the waveguide component is restricted from leaving the waveguide component upon being reflected by at least one of the prism/mirrored facets, hereby the at least some light restricted from leaving the waveguide component is directed by the waveguide toward the at least one photovoltaic cell.

Abstract: A sun tracking solar energy collection system includes a sun tracker having a base with a rotatable member driven by a base motor. A support extends from the base and is rotatably driven in conjunction with the rotatable member by the base motor. An arm in communication with the support is pivotable relative to the base and the support and is driven by an arm motor associated with the arm. A light sensitive element in conjunction with the arm receives a light from a light source for determining an amount of received light. A solar energy collector is movably positioned to correspond to a relative position of the base and the arm to correspond to the position of the light source for collecting solar energy. A controller controls a position of the sun tracker and the solar energy collector to correspond to a position of the light source.

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: A solar tracking sensor and methods of tracking the sun. In one embodiment, the solar tracking sensor includes a housing, an inclinometer to output a signal indicative of the angle of the housing relative to the gravitational pull of the Earth, and first and second photosensors located on a first plane located within the housing. An opening on one side of the housing allows solar radiation to pass through the housing and reach the first and second photosensors. A difference calculating module is coupled to the first photosensor and the second photosensor. The difference calculating module determines a photosensor difference value using signals from the photosensors and outputs a photosensor difference value. The photosensor difference value can be used by a controller. The controller is coupled to the inclinometer determines whether the opening is aligned with the Sun based on the photosensor difference value and information or signal from the inclinometer.

Abstract: A tracking system configured to orient light concentrators to face a light source. The system includes a movable support structure for providing global alignment of the light concentrators with the light source. The system also includes a light concentrator (LC) module that is coupled to the support structure and has an array of light concentrators that are in fixed positions with respect to each other. The system also includes a secondary alignment mechanism having a module joint that movably couples the LC module to the support structure and an actuator assembly. The actuator assembly is configured to selectively move the LC module about two axes relative to a pivot point of the module joint thereby orienting the array of light concentrators.

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: A solar power generating apparatus and a solar tracking method for the same. When a plurality of solar collector plates are arranged, the solar collector plates may be adjusted at certain rotation angles to maintain a high level of solar absorption efficiently with respect to shade, and errors caused by the installed positions (particularly, the installed directions) of the solar collector plates having solar cells can be compensated for, to accordingly calculate and determine adjustment angles in order to accurately rotate the solar cells or solar collector plates to a desired direction and to increase solar absorption efficiency.

Abstract: Methods and systems for use with solar devices. The present invention may be used with solar panels, solar dishes, or any other devices for which an optimal exposure to the sun is desired. The present invention first adjusts an azimuth of the solar device until an optimal solar exposure, from an azimuth point of view, is achieved. Then, an altitude of the solar collector is adjusted until an optimal solar exposure, from an altitude point of view, is achieved. The invention also uses a load compensation mean to alleviate the amount of lifting or braking torque needed from the motor to tilt the solar collector.

Abstract: A solar-thermal concentrator for a expeditionary power generator system including a portable power plant that utilizes a hybridized solar/fuel Stirling engine to supply electric power in an expeditionary setting. The concentrator includes a collapsible dish assembly that is pivotably and tiltably mounted on a portable base assembly, where the dish assembly includes a lightweight frame including a central mounting structure and multiple truss-like radial arms that are rigidly connected to and extend radially from the central mounting structure, and a reflector panel assembly including multiple flat, fan-shaped reflector panels that are secured to the frame and disposed in a semi-circular pattern. Each reflector panel includes multiple reflectors that collectively form a substantially flat Fresnelized reflective surface that redirects incident sunlight into a focal region. The power plant is maintained in the focal region by a support structure that extends perpendicular to the flat reflective surface.

Abstract: The present invention proposes a one-axis solar tracker system and apparatus which is simple to install, lower cost and with the provision of an electric-magnetic locking device to resist from medium to strongest wind condition like hurricane or typhoon. Solar farms is more and more popular to use one-axis tracker due to lower cost, higher wind resistance and easier for large scale solar farm installation, especially at lower latitude tropic zones. This disclosure proposes a one-axis tracker with multiple posts support using a single or dual linear actuators driving mechanism for rotation. It is also equipped with a wind lock device to lock the solar tracker in horizontal neutral position during strong wind condition such as hurricane or typhoon. The stepwise wind lock device can further be applied to locking the solar tracker following each step of linear actuator activation enabling the disclosed solar tracker to operate in windy conditions.

Abstract: A shadow band assembly includes a platform and an arcuate shadow arm extending upward from the platform and terminating in a free end above the platform. A sun sensor mounting location is located below the free end of the shadow arm. The arm is preferably further supported by a vertical strut. According to other embodiments, the arm is hollow and contains a fluid conduit and/or an electrical cable. A sun sensor may be mounted on top of the free end of the arm and a fluid nozzle may be mounted under the free end. A shadow band pyranometer includes the shadow band assembly, a sun sensor mounted at the mounting location and a motor drive coupled to the platform for azimuth tracking. Additional sensors with zenith tracking may also be provided.

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: A system and method of collecting solar energy from sunlight, employing a thermal generation apparatus having a solar collector module including a receiver in optical communication with an array of mirrors. The method comprises reflecting energy impinging upon the reflector assembly with a plurality of reflective elements. The plurality of reflective elements is configured to direct energy reflected therefrom onto the receiver. The solar collector module is configured to rotate about an axis; and an angular position of the plurality of reflective elements is changed in relation to relative movement of the sun with respect to earth.

Abstract: A shadow band assembly includes a platform and an arcuate shadow arm extending upward from the platform and terminating in a free end above the platform. A sun sensor mounting location is located below the free end of the shadow arm. The arm is preferably further supported by a vertical strut. According to other embodiments, the arm is hollow and contains a fluid conduit and/or an electrical cable. A sun sensor may be mounted on top of the free end of the arm and a fluid nozzle may be mounted under the free end. A shadow band pyranometer includes the shadow band assembly, a sun sensor mounted at the mounting location and a motor drive coupled to the platform for azimuth tracking. Additional sensors with zenith tracking may also be provided.

Abstract: A tracker including an outer post having elongated bore and a lower end mounted on a sub-structure, an inner pole rotatably received in the elongated bore, a lower bearing in the bore adjacent a lower end of the outer post and attached thereto to be constrained from lateral movement and mounted on the sub-structure such that a lower end of the inner pole rests on and is supported by the lower bearing, an upper bearing near an upper end of the outer post, a circumferential drive supported on the outer post for rotating the inner pole relative to the outer post, such that substantially a full weight of a load on the inner pole is directly transmitted to the sub-structure and lateral force and torque leverage are placed on a full length of the outer post by way of the upper and lower bearing.

Abstract: A solar power water heating apparatus includes a supporting device for supporting movably a mounting seat provided with a condensing unit on a mounting side thereof for concentrating sunlight onto a heat-conductive tube body in the mounting seat. The tube body absorbs thermal energy from the sunlight concentrated thereonto and transmits the thermal energy to water therein, thereby heating the water. The supporting device includes a disk member mounted rotatably on a hollow base body and driven by a drive unit in the base body to rotate relative to the base body in a central axis of the disk member, and a telescopic rod member and two upright supporting rods interconnecting the mounting seat and the disk member. A control module controls the drive unit and the telescopic rod member based on a solar radiating direction to move the mounting side of the mounting seat to face sunlight.

Abstract: An apparatus for positioning an object, for example, a solar energy capture device, can include a frame, the object, a joint, and at least two linear actuators. The joint connects the object to the frame and allows the object to rotate relative to the frame. The first and second linear actuators are coupled to the object. When the first and second actuators are actuated in combination, the object rotates about a pitch axis. When the first and second actuators are actuated differentially, the object rotates about a roll axis.

Abstract: A solar-tower system includes a raised solar receiver disposed on a tower and a mirror array including multiple flat mirrors for reflecting sunlight onto the raised receiver. The mirror array is disposed on a carousel-type platform that is rotatable around a vertical axis, and the raised receiver is maintained at a substantially fixed position relative to the mirror array for all rotational positions of the platform. A solar azimuth tracking controller controls the platform's rotational position to track the sun's azimuth angle such that sunlight shines on the mirror array from a fixed apparent azimuth angle at all times during daylight hours. Each flat mirror pivots around a corresponding unique axis, and a solar elevation tracking controller individually controls each mirror's pivot position to track the sun's elevation angle such that sunlight is accurately reflected onto the raised solar receiver at all times during daylight hours.

Abstract: A method for harvesting solar power by concentrating sunlight onto a raised solar receiver disposed on a tower. The method involves rotating a mirror array made up of multiple flat mirrors as a unit around a vertical axis such that sunlight shines on the mirror array from a fixed apparent azimuth angle at all times during daylight hours, and controlling each mirror's pivot position to track the sun's elevation angle such that sunlight is accurately reflected onto the raised solar receiver at all times during daylight hours. In one embodiment the mirror array is disposed on a roundabout-type platform whose rotational position is controlled to track the sun's azimuth angle and the raised receiver is maintained at a substantially fixed position relative to the mirror array for all rotational positions of the platform.

Abstract: There is provided an apparatus for tracking and condensing sunlight of a sliding type which tracks a direction of sunlight according to variations of an altitude or orbit of the sun pivots a solar module plate to maximize condensing efficiency, and strengthens a fixing structure on an inclined ground or inclined building surface by suing a frame structure on the bottom without using a concrete base harmful to natural environment.

Abstract: A machine for tracking the sun's movement and concentrating sunlight consists of a main frame which pivots in the north and south direction on a base having conduit for a heat medium (a liquid usually of the Glycol family the main frame supports the mirror frame that pivots 360 degrees East to West allowing the mirror to focus the sunlight onto the conduit heating the liquid medium producing a very high and concentrated amount of heat during the entire daylight period and can be used for a small business or residential heating. An optional prism can be attached to the mirror frame to focus sun rays onto the conduit for added heat.

Abstract: The invention relates to a two-axle solar tracker, consisting of a moving supporting system for solar panels, which maximizes the energy production of said panels and which is formed by a vertical axle and a horizontal axle in relation to which the system rotates in order to track the sun's path. The aforementioned axles are components of a structure supported at the center and supported peripherally on wheels positioned on a running track or surface. The structure rotates about a fixed central point supporting the vertical axle of the tracker. At least one board is positioned on the horizontal axle of the structure in order to receive the solar modules or panels and said board(s) can rotate about the horizontal axle so that the solar panels are maintained perpendicular to the sun's rays.

Abstract: An improved diurnal sun tracking system and methodology for use with a photovoltaic solar collector system mountable on flat roof industrial buildings or multi-unit apartment buildings is provided. The improved tracking system and method rotates or pivots the solar collector system to track the sun during the spring and fall Equinoxes in a first tracking mode, as well as from winter to summer solstices, when the angular rate of the sun's movement does not exactly follow the angular rate at the Equinoxes, in a second tracking mode.

Abstract: A terrestrial concentrator solar tracking photovoltaic array that may include an elongated frame configured to mount concentrator solar cell modules in a longitudinally-extending and spaced-apart arrangement. The frame is able to rotate each of the concentrator solar cell modules along a first axis to simultaneously track the elevation of the sun during the course of a day. The frame is also able to rotate each concentrator solar cell array module along second axes that are substantially perpendicular to the first axis to track the azimuthal position of the sun during the course of the day.

Abstract: In a two-axle drive system (10) for holding and moving large sunlight-absorbing, concentrating or reflecting surfaces about an azimuth axis (14) and an elevation axis (15), in the case of which a first gear unit which is driven by a first drive (43) is provided for a rotational movement about the azimuth axis (14), and a second gear unit which is driven by a second drive (45) is provided for a rotational movement about the elevation axis (15), the first gear unit being located in a first housing section (23), and the second gear unit being located in a second housing section (24), the first and second housing sections (23, 24) are immobile relative to each other. High stiffness is obtained as a result.

Abstract: A sun tracking system includes a reduction device of a servo motor, multiple shafts, multiple couplers, and at least two rows of cylinders and each row having at least two cylinders, a solar panel, multiple pivotal connection units and multiple sliding units. The reduction device of a servo motor drives the cylinders of the first and second rows of cylinders which drive other cylinders. The cylinders of the first row of cylinders are pivotably connected to the solar panel and the cylinders of the second row of cylinders are movably connected to the solar panel. By the cylinders of the same row moving upward or downward while the cylinders of the other row moving downward or upward, the panel is controlled to aim the sun.

Abstract: A sun-tracking solar energy collector apparatus includes an east-west driving shaft body and a south-north driving shaft body which are coupled in the shape of a cross. A first driving member of an east-west shaft sleeve of the east-west driving shaft body is actuated to turn the south-north driving shaft body in an east-west direction. A second driving member of the south-north driving shaft body is driven by the first driving member to turn an east-west driving shaft of the east-west driving shaft body in a south-north direction and to drive an annular member which is connected with the ends of the east-west driving shaft, such that a holding rack assembly connected with the annular member is actuated in east-west and south-north directions. Solar energy collector modules of the holding rack assembly can track to collect solar energy. Due to the base body in cooperation with the effect of tracking sun, the area occupied by the base body is larger.

Abstract: An economical system for harnessing the sun's energy, storing this energy and/or converting this energy into a usable energy product on a sustainable cycle is provided. The system includes an enclosed volume chamber having a mirrored inner surface and an opening for receiving a condensed high-temperature solar energy beam and trapping thermal energy. A fluid source is injected into the chamber for converting this energy into a high pressure source which can be fed to an energy converting device. The enclosed volume chamber can include a thermal absorbing member to store thermal energy for use during sunless hours. A sustainable system including a plurality of interconnected chambers can be provided to form an additive system of thermal energy for use during the day and during sunless hours. The thermal energy can be converted to provide a clean energy source at zero carbon emission for use in numerous and diverse applications.

Abstract: A light tracking sensor and a sunlight tracking system including the same, the light tracking sensor comprises two or more light tunnel devices. One end of the respective light tunnel devices form a common single-point micro-hole acting as an input port for directional light, the other ends of the light tunnel devices act as output ports for directional light and is provided with light-sensing units respectively. A sunlight tracking system is constituted of said light tracking sensor, a differential processing unit, an A/D converting unit, a microprocessor unit, a driving unit and an executive unit driven by the output end of the driving unit. Since one ends of the light tunnel devices form a common single-point micro-hole and the surface around the micro-hole is a curved surface, the sunlight tracking system, compared with the prior art, has a simpler structure, and a higher integration.

Abstract: Solar apparatus for concurrent heating and power-generation duty having a base load bearing structure and a load bearing structure supported on the base load bearing structure secured to the plant solar concentrator so as to allow rotation of the concentrator with an established maximum rotation angle, with both a first alternate rotation movement in a circular direction and a horizontal plane along the base load bearing structure, and a second alternate movement along a curved path around a vertical plane orthogonal to the horizontal plane. The solar concentrator is actuatable with said first and second movement during the day by respective first and second actuators, controlled by a microprocessor, depending on the corresponding orientations of the concentrator, detected by first and second sensors, in a manner to orientate the concentrator for receiving maximum solar radiation during the day.

Abstract: In one aspect of the present invention, a solar energy collection system that includes multiple longitudinally adjacent collectors is described. The collectors are coupled end to end to form a collector row. The collector row extends along a longitudinal axis and is arranged to rotate about a pivot axis to track the sun in at least one dimension. Each collector includes a reflector, one or more solar receivers and a support structure. The support structure includes a tube assembly that underlies the reflector. The tube assemblies of the collector row are arranged end to end along the longitudinal axis. There is a space between the tube assemblies of adjacent collectors in the collector row, where the reflectors of the adjacent collectors extend beyond the underlying tube assemblies to form a substantially continuous reflective surface over the space. A coupling device is positioned in the space between the tube assemblies.

Abstract: A tracking system is provided for a roof-mounted solar array. The system includes a sensor mechanism for sensing an orientation of the sun relative to the solar array, and a controller connected to the sensor mechanism that generates a signal that represents an optimal tilt angle of the solar array relative to the orientation of the sun. An actuator connected to the controller receives the signal from the controller and adjusts the tilt angle of the solar array in response to the received signal.

Abstract: A tracking system configured to orient light concentrators to face a light source. The system includes a movable support structure for providing global alignment of the light concentrators with the light source. The system also includes a light concentrator (LC) module that is coupled to the support structure and has an array of light concentrators that are in fixed positions with respect to each other. The system also includes a secondary alignment mechanism having a module joint that movably couples the LC module to the support structure and an actuator assembly. The actuator assembly is configured to selectively move the LC module about two axes relative to a pivot point of the module joint thereby orienting the array of light concentrators.

Abstract: A man-made island [10], adaptable for land-based or sea-based operation holds solar energy collection facilities and is rotatable to optimize the angular orientation thereof relative to the position of the sun. More particularly, the man-made island [10] uses a platform [12] that includes a large outer ring [14] that floats on a fluid, and a flexible cover [16] attached to the ring [14] to define an airtight volume [30] below the cover [16]. A plurality of rows [19] of solar radiation collector modules are located above the cover [16], and carry steam generating heat pipes [21]. The rows [19] of modules are supported above the cover [16] by an upper support structure, either a space frame [27], a plurality of cables [46] or a honeycomb [75]. A compressor [32] creates an over-pressure within the enclosed volume [30] to assist in supporting the cover [16] and the other components mounted thereabove.

Abstract: A heliostat for the collection of solar energy while resting on a surface is disclosed, comprising a rigid disk having an exposed surface, a back surface, and a circular peripheral edge connecting the exposed surface to the back surface. The peripheral edge includes a plurality of wheels each having a rotational axis substantially tangent to the circular peripheral edge of the disk. Each wheel is driven by an electric motor electrically connected to a power source. A hollow, substantially transparent spherical enclosure contains the rigid disk. Each wheel of the disk frictionally engages an inner surface of the enclosure such that rotation of the any of the wheels changes the orientation of the disk within the enclosure. A control circuit is electrically disposed between the power source and each motor. The control circuit includes a direction setting means for causing the motors to orient the exposed surface substantially facing a commanded direction.

Abstract: A power solar panel is maintained in an optimum position relative to the sun during daylight as the sun traverses a solar track elevated above the horizon and extending from a sunrise location to a sunset location during each day of consecutive days of the year by utilizing solar energy to power a sun tracker which carries the power solar panel. The sun tracker includes pairs of solar modules wherein the solar modules are arrayed in an A-shaped cross-sectional configuration for being aimed directly at the sun in response to exposure to the sun, and the pairs of solar modules power motors which tilt the solar panel about a horizontal direction and rotate the power solar panel about a vertical direction to maintain optimum alignment with the sun during the course of a day.

Abstract: Systems and methods for a heliostat directing incident sun light to a receiver based on an estimate or predicted receiver location and an imaged sun location