Abstract: The present invention is a solar concentrator composed of a generally V-shaped trough of reflective Fresnel steps. The Fresnel reflective steps concentrate the sunlight entering the mouth of the V-shaped trough and parallel to its central axis into a central focal area. By disposing a solar energy receiving element at the central focal area of sunlight concentration a preferred embodiment as a concentrating solar energy collector is realized. Various types of solar energy receiving structures are shown that serve to convert the concentrated sunlight into other forms of useful energy to realize the preferred embodiment as a concentrating solar energy collector.

Abstract: A tubular heat-absorbing element partly enclosed in an insulating layer or jacket, has absorbing surface that is accessible to solar radiation. The thermal insulation is designed to provide entry to solar radiation by way of a cavity. The absorbing surface can be substantially planar.

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 linear Fresnel light concentrating device with high multiplying power, including a reflector field and a receiving unit, where the reflector field includes a plurality of arrays of one-dimensional linear convergence reflector strips; the linear receiving unit is arranged parallel to the reflector strips, and is provided with a secondary optical light concentrating unit inside, the height value of the receiving unit exceeds half of the width value of the reflector field, so as to obtain a relatively high primary convergence light concentrating multiplying power and secondary convergence light concentrating multiplying power, thereby realizing a high total convergence light concentrating multiplying power. High multiplying power light concentration in low cost can be achieved, while the severe problem of low light concentration efficiency caused by extinction, tolerance rate and shading rate and the problem of inconvenience in repair and maintenance of the device are solved.

Abstract: A receiver system for a Fresnel solar plant is provided. The system includes an absorber tube defining a longitudinal direction and a mirror array that runs parallel to the longitudinal direction. The mirror array has a mirror-symmetrical curve profile having at least one top apex for concentrating light beams onto the absorber tube. The mirror array has ventilation holes in the region of the apex.

Abstract: A device for concentrating solar radiation (4) with longitudinal mirrors (7) and a longitudinal receiver (1), has mirrors with a circular cross-section with a radius of curvature that is twice the transverse distance from the center (35) of each mirror to the central point (3) of the receiver. The width of the receiver is 1% of the transverse distance from the central point to the center (89) of the furthest mirror (32). The width of each mirror is determined according to the drift of the rays reflected when the mirror focuses the sun, prescribing an equal width for all mirrors, which is: equal to the width of the active face (2) of the receiver when mounted according to the meridian; and triple the width of the active face (2) of the receiver when mounted according to the parallel of latitude. The mirrors are installed in a contiguous manner and the receiver is installed at a height on columns (8).

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 system for transferring torque between modules in a concentrating solar collector array. A trough collector system includes at least two modules, each module including a reflector having a reflective surface shaped to concentrate incoming radiation onto a linear tube, and a structural lattice attached to the reflector. The modules are constrained to rotate about a common axis. A torque transfer connection directly connects the three-dimensional structural lattices of the two modules at a location removed from the axis of rotation. Torque is thus transmitted between the modules by a force couple acting on the module. Also described are a method of transferring torque between adjacent trough collector modules, and a three-dimensional structural lattice configured for use in the system and method. Mechanisms for accommodating thermal expansion and contraction of the array are described. A drive system is described that imparts torque to a module near an edge of the module.

Abstract: A solar energy harvester comprises: an elongated stationary solar irradiance converter assembly; a concentrator comprised of a substantially flat array of flat reflective heliostatic slats disposed at tilt angles to concentrate the sun onto the converter assembly, said slats each rotating in elevation about a north-south axis; sun sensor detecting the efficacy of concentration as the sun traverses; and control circuitry and drive motor positioning the collector in elevation according to the sun sensor so that the slat array tracks and faces the sun whenever the solar incident energy is greater than a selectable threshold level.

Abstract: Solar energy generates steam in a “once-through” configuration without recirculation, with closely managed steam quality, to produce wet steam from high-contaminant feed water without scaling or fouling. Feed water is pressurized, preheated, and evaporated in a series of pipes exposed to concentrated solar energy to produce a water-steam mixture for direct distribution to an industrial process such as enhanced oil recovery or desalination. Water flow rates are managed based on measurements of solar energy and steam production to manage variations in the solar energy. Steam generator piping system uses continuous receiver pipe that is illuminated by segmented parabolic mirrors enabled to track the sun. Provisions for steam generator piping recurring maintenance are provided. Thermal energy from hot condensate and/or from low quality steam is recaptured and warms inlet water.

Abstract: A solar energy collector system (32) has a fixed array (34) of reflectors (40) extending in parallel rows, and a common focal receiver (36) located above the fixed array (34) and extending parallel to the rows of reflectors (40). Incident solar radiation from all of the reflectors is reflected upon the receiver (36) which includes a heat absorbing medium adapted to absorb heat from the reflected radiation. There is an elevated support structure (38) for the fixed array (34) of reflectors and the receiver (36). The support structure (38) orients each row of reflectors at a respective fixed angle relative to the support structure. The support structure (38) is pivotally mounted to an upright elevation assembly (77) to allow controlled rotation of the fixed array (34) and receiver (36) simultaneously about a pivotal axis (39) extending parallel to the rows of reflectors (40) so as to track the movement of the sun.

Abstract: Systems, methods, and apparatus by which solar energy may be collected to provide heat, electricity, or a combination of heat and electricity are disclosed herein.

Abstract: An improved solar reflector with a frame structure suitable for spanning longer distances that utilizes light-weight side beams, ridgecaps and tensioned cables to form a truss-system.

Abstract: A system for controlling the rotational position of a solar collector trough includes a hydraulic cylinder having an output end and a linkage assembly. The linkage assembly includes at least one linkage member and a pair of pivot arms attached to the at least one linkage member. The pair of pivot arms is defined by a first pivot arm and a second pivot arm, each arm being pivotally attached to the at least one linkage member and the trough. The first and second pivot arms form respective parallel horizontal first and second pivot axes enabling the trough to be entirely movable over an angular range of motion extending over 180 degrees based totally on the linear movement of the output end of the hydraulic cylinder and in which an actuator control circuit controls the relative displacement of the cylinder output end.

Abstract: A solar reflective assembly includes a plurality of reflective segments radially configured to collectively at least partially define a dish-shaped reflector having a center axis, each reflective segment having a generally conical shape and being discontinuous relative to the conical shape of an adjacent reflective segment, and an elongated receiver having a length generally extending in a direction of the center axis. Each reflective segment reflects and focuses sunlight on the receiver along the length of the receiver.

Abstract: An absorber for a solar receiver with a casing of lengthways axis including at a first lengthways end, a collector to supply a heat transfer fluid; and at a second lengthways end, a collector for evacuating the heat transfer fluid. The casing includes a first wall having a face intended to be subjected to a luminous flux, a second wall facing the first wall, and side walls connecting said the first and second walls. The casing is formed by at least one rib extending lengthways, and attached to the first and to the second wall. The at least one rib includes windows, and deflectors associated with the windows. The deflectors cause a portion of the heat transfer fluid to flow through the windows, causing reblending of the heat transfer fluid.

Abstract: An apparatus is provided for the collection and conversion of light energy. The apparatus includes, a sandwich core structure, a collector element and a concentrator including one or more reflector elements and positioned at an exterior surface of the sandwich core structure.

Abstract: The inventive solar trough field system (A) comprises multiple parabolic reflectors (1), support circles (3) of which the center coincides with the focus of the parabolic reflector (1 ) and which are used in order to support the reflector (1), core mechanisms (2) which are located on the center of the circles (3), guy wires (4) which connect the circle (3) and the core mechanism (2) to each other, side support units (5,5J) which bear the support circles (3) from their outer surfaces, lightweight filling materials (6) which support the reflectors (1) from their lower parts, thermal receiver tubes (11) which pass through the center axis of the circles (3). The parabolic reflectors (1) are rotated around the center axis of the circles (3), which is the focus thereof, and directed towards the sun. Thus, the parallel beams coming from the sun are concentrated in the thermal receiver tubes (11) which are located in the focus of the reflectors (1).

Abstract: A linear trough concentrates sunlight through a long target window in a greenhouse's roof or north wall. Heat is stored in a geothermal heat bank below the greenhouse's center, where a thermal skirt around the greenhouse reduces heat loss.

Abstract: A system for transferring torque between modules in a concentrating solar collector array. A trough collector system includes at least two modules, each module including a reflector having a reflective surface shaped to concentrate incoming radiation onto a linear tube, and a structural lattice attached to the reflector. The modules are constrained to rotate about a common axis. A torque transfer connection directly connects the three-dimensional structural lattices of the two modules at a location removed from the axis of rotation. Torque is thus transmitted between the modules by a force couple acting on the module. Also described are a method of transferring torque between adjacent trough collector modules, and a three-dimensional structural lattice configured for use in the system and method. Mechanisms for accommodating thermal expansion and contraction of the array are described. A drive system is described that imparts torque to a module near an edge of the module.

Abstract: A solar energy collector system (32) has a fixed array (34) of reflectors (40) extending in parallel rows, and a common focal receiver (36) located above the fixed array (34) and extending parallel to the rows of reflectors (40). Incident solar radiation from all of the reflectors is reflected upon the receiver (36) which includes a heat absorbing medium adapted to absorb heat from the reflected radiation. There is an elevated support structure (38) for the fixed array (34) of reflectors and the receiver (36). The support structure (38) orients each row of reflectors at a respective fixed angle relative to the support structure. The support structure (38) is pivotally mounted to an upright elevation assembly (77) to allow controlled rotation of the fixed array (34) and receiver (36) simultaneously about a pivotal axis (39) extending parallel to the rows of reflectors (40) so as to track the movement of the sun.

Abstract: Advanced stationary solar concentrating wedges are described. Using the latest collection optics, sunlight is directed into the wedge to produce a short hot focus. The wedge acceptance angle allows for a two-sided collector. A simple and sturdy non-tracking frame ensures that collected light will follow the intended path to the absorber. The scalable wedge will be useful in making steam for motive power and purified water for human consumption.

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

Abstract: A system for transferring torque between modules in a concentrating solar collector array. A trough collector system includes at least two modules, each module including a reflector having a reflective surface shaped to concentrate incoming radiation onto a linear tube, and a structural lattice attached to the reflector. The modules are constrained to rotate about a common axis. A torque transfer connection directly connects the three-dimensional structural lattices of the two modules at a location removed from the axis of rotation. Torque is thus transmitted between the modules by a force couple acting on the module. Also described are a method of transferring torque between adjacent trough collector modules, and a three-dimensional structural lattice configured for use in the system and method. Mechanisms for accommodating thermal expansion and contraction of the array are described. A drive system is described that imparts torque to a module near an edge of the module.

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 system and method of arranging a solar cell and reflector to replace a typical solar cell oriented normal to the incoming sunlight inside a module (i.e. parallel to a module's transparent cover plate or opening). The present invention in a preferred embodiment uses a solar cell oriented at a 45 degree angle to the incoming sunlight, and a reflective surface oriented perpendicular to the cell and at a 45 degree angle to the incoming sunlight. The solar cell and the mirror are the same length/size and form a V shape where the angle between the sloped sides is 90 degrees. Any light falling normally on the arrangement will hit the solar cell either directly or after reflection. In another embodiment, two adjacent reflectors can be used making angles of around 60 degrees and around 30 degrees with respect to the cover or opening. An alternate embodiment can include a second reflector added to the base of the cell and reflector pairings also at an approximate 45 degree angle with the cover or opening.

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 present invention is a Solar Concentrator composed of a generally V shaped trough of reflective Fresnel steps. Said Fresnel reflective steps concentrate the sunlight entering the mouth of the V shaped trough and parallel to its' central axis into a central focal area. By disposing a solar energy receiving element at the central focal area of sunlight concentration a preferred embodiment as a concentrating solar energy collector is realized. Various types of solar energy receiving structures are shown that serve to convert the concentrated sunlight into other forms of useful energy to realize the preferred embodiment as a concentrating solar energy collector.

Abstract: A curved surface structure for reflecting solar light, heat or electromagnetic radiation is made by scoring two opposing pairs of curved bend lines along one pair of opposing edges of a sheet of bendable material, dividing it into a center section joined by curved bend lines to curved ribs, joined by curved bend lines to respective curved edges; bending the curved ribs down and curved edges up along the bend lines to nominally right angles to form a curved surface supported by two curved ribs and two curved edges. Two straight ribs and respective straight edges may be scored and formed on the other pair of opposing edges of the sheet. A backside sheet may be applied to the four edges. A widthwise corrugated, elongate right angle reinforcement member may be employed for strengthening the formed bend lines.

Abstract: A system and method for energy-efficient and environmentally-friendly recovery of bitumen aims at recovering unconventional oil in an environmentally friendly and sustainable way that has the potential of eliminating the need of natural gas currently employed for steam production and power generation. The system and method aims at providing low temperature steam for the stimulation of the formation by means of solar radiation. In addition, the system and method provides a novel solution for hydrogen production that does not employ reforming of natural gas. Furthermore, the use of thermoelectric devices in combination with low temperature steam can be employed to power an electrolysis plant to generate the hydrogen necessary to produce synthetic oil.

Abstract: A multiplicity of Fresnel lenses are attached to tubular branches of a tree-like support structure. Fiber optic bundles are connected to the Fresnel lenses and routed inside the tubular branches and collected as a larger fiber optic bundle inside a main trunk structure to which each of the branches is connected. The larger fiber optic bundle may be connected to a remotely located power generating plant or other processing facility via a fiber optic transmission network. A domed solar energy collector includes an outer dome and one or more inner domes concentrically nested therewith, one or more Fresnel lenses being positioned on the hemispherical surface of each of the outer and inner domes. Each of the inner domes is sized and positioned such that its hemispherical surface lies on the focal point of the next larger dome to thereby multiply the solar energy focused through each of the domes to a collection area within the innermost dome.

Abstract: Methods and apparatuses are provided for generating electrical power for a cellular tower using solar troughs. Unlike typical long, straight solar troughs, the solar troughs are formed into circular or similar shapes such that they surround the cellular tower radially and are attached to it at different heights. A pipe is located within each solar trough at the focal point of the reflective surface of the trough. A heat-transfer liquid within the pipe is heated by reflected sunlight and flows to an energy-conversion device that converts energy from the heat-transfer liquid into electrical energy to power the cellular tower.

Abstract: This invention is a trough solar collector that uses inexpensive aluminized plastic films as the reflecting surface. The films are held in proper shape by stretching them between rigid ribs that are spaced apart along the length of the collector. The structure of the trough is held rigid by a unique sun-tracking system that not only guides a whole of array of troughs on a field to point them toward the sun, but also maintains the whole length of each trough in rigid configuration. It is not necessary to extend rigid metal beams along the trough to maintain the rigidity of the trough. Small-diameter cables are wrapped around rotatable pipes that extend along the east and west sides of the field. The cables extend over the field of the troughs and are attached to connecting points above the troughs in such a way that when the rotatable pipes rotate, the cables move, the troughs move with them, and the cables provide the rigidity of the troughs.

Abstract: A method of wastewater treatment comprises: providing waste water to a vessel within a solar collector; and superheating the waste water under pressure within the vessel using solar energy of the solar collector, thereby to provide oxidation conditions from said solar energy to oxidize organic matter. The water may then be passed to a flash chamber to vaporize and leave behind a brine with dissolved salts.

Abstract: In an energy wave solar reflector assembly (12) for an energy concentrator (10), the assembly has a support structure (21) with support arms (22) extending from a central zone (24), and an array of concentric annular reflective elements (28) spacedly arranged on the support arms or on elongate mounting strips fixed to each or selected supported arms. The reflective elements having a reflective surface shaped to reflect incident energy waves, and a holding arrangement having holding devices (40, 74) arranged to hold the reflective elements in an orientation to direct the reflected energy waves thereof in a direction towards a focal zone (16) of the reflective elements.

Abstract: Increased utilization of solar power is highly desirable as solar power is a readily available renewable resource with power potential far exceeding total global needs; and as solar power does not contribute to pollutants associated with fossil fuel power, such as unburned hydrocarbons, NOx and carbon dioxide. The present invention provides low-cost inflatable heliostatic solar power collectors, which can be stand-alone units suitable for flexible utilization in small, medium, or utility scale applications. The inflatable heliostatic power collectors use a reflective surface or membrane “sandwiched” between two inflated chambers, and attached solar power receivers which may be of photovoltaic and/or solar thermal types. Modest concentration ratios enable benefits in both reduced cost and increased conversion efficiency, relative to simple prior-art flat plate solar collectors.

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: A concentrator for solar radiation and which comprises a housing having an aperture arranged to admit incident solar radiation and linearly extending receivers located within the housing. A plurality of linearly extending line focusing, tensile-loaded reflector elements is associated with each receiver and arranged to reflect toward the receiver incident solar radiation that enters the housing, and a drive mechanism is located within the housing and arranged to impart sun tracking pivotal drive to the reflector elements. A housing configuration is disclosed that, with aperture-defining windows, provides for maximal admission of solar radiation.

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 collector has operably connected reflective panels that can be positioned to substantially form a parabolic trough that concentrates solar radiation onto a tube running along the focal line of the trough. A folding mechanism can be manually or automatically operated to selectively fold and unfold the panels into open and closed positions and into any number of intermediate positions, including the position characterized by formation of a parabolic trough. A rotating mechanism can be manually or automatically operated to selectively rotate the solar collector about an axis parallel to the focus line of the parabolic trough.

Abstract: A solar air conditioning device (100) includes a solar collector assembly (30), an inlet assembly (10) at an entrance of the solar collector assembly, and an outlet assembly (50) at an exit of the solar collector assembly. The solar collector assembly includes a heat-absorbing set (31) and a transparent panel (38) being assembled to a top of the heat-absorbing set. The heat-absorbing set comprises a plurality of heat-absorbing units (32) engaged with each other. Each of the heat-absorbing units includes two adjacent supporting members (33) and a heat-absorbing plate (35) sandwiched between and buckled with the two supporting members. The heat-absorbing set defines an air channel (314) with the transparent panel and a heat-absorbing channel (315) below the air channel. The inlet and outlet assemblies are in fluidic communication with the heat-absorbing channel.

Abstract: A rotational trough reflector solar-electricity generation device includes a trough reflector that rotates around a substantially vertical axis and includes a solid optical element having a linear parabolic convex surface that serves as a base for automatically positioning a mirror to focus sunlight onto a focal line, and a flat aperture surface that serves to support a strip-type photovoltaic (PV) receiver on the focal line. A tracking system rotates the trough reflector such that the trough reflector is aligned generally parallel to the incident sunlight (e.g., in a generally east-west direction at sunrise, turning to generally north-south at noon, and turning generally west-east at sunset). A disc-shaped support structure is used to distribute the reflector's weight over a larger area and to minimize the tracking system motor size. Multiple trough reflectors are mounted on the disc-shaped support to maximize power generation.

Abstract: A radiant energy collector comprising a reflective surface having a concave cross-sectional shape, wherein the reflective surface focuses radiant energy onto a receiving surface that is disposed along the focal axis of the reflective surface, wherein the focused radiant energy provides substantially uniform illumination along the entire axial length of the receiving surface.

Abstract: A solar collector includes a plurality of elongated parabolic reflectors mounted within a glass-topped enclosure for pivotal movement such that each reflector is incrementally pivoted throughout the course of a day to remain substantially perpendicular to the sun. The incremental pivotal movement is caused by a motor energized from a solar switch having solar cells that also pivot throughout the day so that in one position of the switch, no electricity is being generated and transferred to the motor, but in a second position, the switch receives solar radiation and energizes the motor to again incrementally pivot each reflector along with the solar switch.

Abstract: A collector includes a convergent lens (2) having a focal distance f and an image focal plane (PFI). The convergent lens (2) defines one of the walls of a casing (1) defined by two pairs of side walls (4a, 4c), a bottom wall (3) and a front wall defined by the lens (2), the side and bottom walls on the inside of the casing being reflective, and the depth p of the casing being lower than the focal distance f of the lens so that after multiple reflections, the ray beam (R1, R2) thus reflected is concentrated on a final image focus (I?) located inside the casing, the collector including a mobile receptor (6a) held inside the concentrated beam or in a position at least intersecting the beam by elements controlling the movement of the collector (6a) with that of the beam.

Abstract: The subject matter of the invention of hyperbolic solar trough field system (B, II) comprises hyperbolic reflectors (20, 20m) in which the beams that come from the sun parallel, but of which the angle of incident changes at a fixed rate of 15 degrees per hour throughout the day are concentrated on the focal axis in the bottom part thereof, thermal receiver tubes (21) which extend throughout said focal axis and are at a fixed position, and side supports (23, 23?) which are at a ground-fixed position on the both sides of the reflectors. The reflectors (20, 20m) are connected to the ground from at least one rotary joint (22) point such that said reflectors can rotate around the central axis of the thermal receiver tubes (21). The bottom part of hyperbolic reflectors (20, 20m) has been produced as circular sectioned such that it surrounds the thermal receiver tubes (21) somewhat, on the continuation; a hyperbola form has been given to its arms extending towards two sides.

Abstract: A radiant energy flux transformation system including a primary linear focus concentrating collector formed by a plurality of cylindrical slat-like reflectors and a secondary elongated collector is described. The reflectors of primary collector generally have concave or planar transversal profiles and are positioned in a stepped arrangement with longitudinal axes being parallel to each other and to the secondary collector. The reflectors are tilted away from the direction to the source of radiant energy at a range of angles being less than 45° to reflect and direct the incident energy flux to a common focal region located below the primary collector where the concentrated flux is intercepted and further transformed by the secondary collector. In addition to efficient concentrating radiant energy such as sunlight, the system can provide uniformity or a desired energy distribution in the concentrated flux.

Abstract: A solar collector system (10, 30, 82, 82?, 171) includes a photovoltaic means (24, 174) for conversion of solar energy into electrical energy and a pathway/conduit (22, 94, 94?, 94?) for thermal transfer fluid which is in thermal communication with the photovoltaic means (24, 174). A shaped solar concentrator surface (12, 58, 58?, 173) may have at least one focus and the pathway/conduit (22, 94, 94?, 94?) may be disposed at the focus. The shaped solar concentrator surface (12, 58, 58?, 173) may be comprised of roof cladding material (58?) which is integrally formed to support the conduit (94) at the focus. Alternatively, the concentrator surface (173) may be disposed in a trough of corrugated roof cladding, with a transparent or translucent cover (98) over the top. The covers may be domed covers having an axis of curvature which substantially aligns with the roof gradient. A roofing structure comprises intersecting first (48) and second (50) roofing planes.

Abstract: The current invention is a Method and Mechanism to Increase Efficiencies of Energy or Particle Beam Collectors. Light may go through a transparent, open, 1-way, low emission, or transparent top that may focus light below from a thin film that is designed to be a Fresnel focusing surface that angles most of the light to a collector(s). With a 1-way mirror, or low emission film or glass top surface, light may go into the light collector unit, but most to all doesn't leave the unit. Light that gets in the light collector/concentrator units and doesn't get totally focused on the collector(s) from the top, may hit the bottom or sides, which each may be a compact linear Fresnel reflector, Fresnel reflector, photovoltaic or other energy collection, or total reflective surface, and be focused to the collector(s) from the surface, or reflected to eventually be incident on the collector(s).