Abstract: A Fresnel lens-type solar heater including an outer enclosure having at least an upper portion for admitting solar energy to be directed to a Fresnel lens mounted above a heat sink mounted within a solar energy collector which is pivotally mounted to be movable in an east-west manner within a support cradle that is pivotally mounted to be movable in a north-south manner such that the lens is correctly oriented toward the sun during each day of a year and wherein fluid directed through the outer enclosure is heated by energy from the heat sink before being exhausted from the heater to an area to be heated.

Abstract: Surfaces containing conversion elements may be positioned and shaped to concentrate or manipulate convergence of sunlight, for example, to produce a steady reflected beam within a wide range of concentration levels and to direct reflected beams for multiple reflections from solar power conversion mediums. The mediums can be positioned to avoid blocking reflected or other light so that unconverted energy may be directed to other surfaces and has several chances to be absorbed or converted. All of the devices may fit within the total converting surface area, e.g., within a concentrator's surface area. The method of solar power conversion may employ active and passive methods simultaneously and/or sequentially.

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: 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: 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: Provided is a solar light concentrating system which realizes suppression of power generation costs by applying a receiver 2 that is capable of suppressing a manufacturing cost to a low level, facilitating recovery work when a failure occurs, and quickly recovering a heating medium circulating inside in case of an emergency. The receiver 2 is formed by three-dimensionally combining multiple modules 20. At least a part of the modules is a trapezoid-shaped module 20B. The trapezoid-shaped module includes an upper header 21B, a lower header 22B being shorter than the upper header, and multiple heat receiving tubes 23 which connect the two headers. The heat receiving tubes are formed by successively altering their cross-sectional shapes in away that makes each heat receiving tube shaped like a wedge that becomes narrower from its top toward its bottom in a front view, and like a wedge that becomes wider from its top toward its bottom in a side view.

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: Developed is a solar cooker with triangle reflective sides. Above and below are two movable solar reflecting panels that can be adjusted to focus light onto a frying pan using a glass lid, an insulating pad, and a surrounding plastic bag to trap solar light for cooking. The triangle reflective sides are used also to adjust and support the two movable solar reflecting panels via movable pegs. In the corners adjacent to the triangle sides, back reflective plate and reflective floor plate is an invented reflective-tilted-equilateral-triangle-plate with each of the three angles at 60 degrees in all three horizontal and vertical dimensions, to capture and reflect light towards the solar cooking area dishware. At night the entire solar cooker can be folded down to form a storage space. The entire solar cooker is foldable for shipping.

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 cooking device is provided which includes a cooking surface, a remote heat collector, and a heat transfer passage. In an example, the heat transfer passage is located adjacent at least a portion of the remote heat collector and extends to a point adjacent at least a portion of the cooking surface.

Abstract: Direct solar thermal steam generator with an ultra-compact linear Fresnel reflector field that has “travel and turn” capability by means of independent linear and rotational motion of reflectors. Method of positioning and orienting the reflectors of the traveling field such that the reflected energy of the field is maximized at all times Crescent like rotational support rail of the reflector with its gravitational center in the center of the crescent. The curvature of the reflector is customized for each row of the field Ultra-light, collector-absorber structure, with cable suspended arch-like tubular absorber, wide aperture, and secondary reflector with optimized light entrapment Flow distribution and control method of the large horizontal solar thermal steam generation field.

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: Disclosed herein are examples and variations of solar energy collector systems comprising an elevated linear receiver extending generally in an east-west direction, a polar reflector field located on the polar side of the receiver, and an equatorial reflector field located on the equatorial side of the receiver. Each reflector field comprises reflectors positioned in parallel rows which extend generally in the east-west direction. The reflectors in each field are arranged and positioned to reflect incident solar radiation to the receiver during diurnal east-west processing of the sun and pivotally driven to maintain reflection of the incident solar radiation to the receiver during cyclic diurnal north-south processing of the sun. Inter-row spacings of the reflectors on opposite sides of the receiver may be asymmetrical.

Abstract: A structure (26) for supporting an array (22) of solar panels (24) in a solar energy collection system (20) includes a support assembly (42) formed from a rigid subassembly (44). The subassembly (44) includes an elongated truss (68), a base (46) coupled to the truss (68) for attachment to a footing (48), and posts (50) extending from a top edge of the truss (68). The structure (26) further includes torsion tubes (34), each of which is pivotally retained by one of the posts (50) to form parallel rows (32) of torsion tubes (34). A number of rigid subassemblies (44) can be interconnected to further increase the number of rows (32) of the system (20). The solar panels (24) are attached to the torsion tubes (34) to form the array (22), and a drive mechanism (38) pivots the torsion tubes (34) via a single elongated actuator and multiple torque arms (90).

Abstract: A solar concentrator includes high concentrating reflective or refractive optics concentrating collected solar light along a first axis and includes spectrum splitting reflective or refractive optics splitting collected solar light along a second axis for illuminating photovoltaic solar panels with spectrum split light having a plurality of frequency components respectively illuminating horizontally aligned subarrays of cells of associated bandgaps forming a panel matrix of cells for high concentration spectrum splitting solar power collection for efficient solar power conversion.

Abstract: A reflector for focusing sunlight upon a single location. The reflector is preferably positioned in orbit about a celestial body to focus sunlight on objects such as space debris to heat up and vaporize such debris. The reflector includes a plurality of units in an array, with each of the units including a plurality of subunits. Each of the units rotates about a first axis and each of the subunits is tiltable about a second axis which is perpendicular to the second axis. A reflecting surface is mounted on each of the subunits such that the reflecting surface rotates with its respective unit and tilts with its respective subunit. Such rotation and tilting permits sunlight to be directed theoretically anywhere on one side of a plane. Each of the units and each of the subunits is independently controllable, and this permits each of the units directs sunlight to a single location onto a single object, which then heats up rapidly to a relatively great temperature until it vaporizes under the intense heat.

Abstract: In an electronic blood pressure measurement device which is arranged to extract pulse waves from the measured cuff pressure, a pulse wave pattern is generated from the pulse wave amplitude and pulse wave interval data and this pulse wave pattern is compared with reference patterns to classify the pattern in order to accurately obtain biological information other than the blood pressure. Blood pressure amplitudes PA(i) are computed from the measured cuff pressures C(i) and a pulse wave pattern is generated (35) on the basis of this pulse wave amplitude data and this pulse wave pattern is classified into a plurality of reference patterns (37) according to reference patterns or reference values (36). Here, the reference patterns or reference values are set as hemodynamic references based on dynamic characteristics of the blood vessel or cardiac output characteristics.

Abstract: Disclosed is a solar electric power system that utilizes multiple reflectors to concentrate sun light onto a panel of photovoltaic (PV) cells. The power system, consisting of multiple reflectors, mounted PV cells, and a heat dissipation component, is mounted on a tracker that keeps the system directed to the sun. A noteworthy feature of this system is its designed-in capability of being retrofitted with advanced reflectors, PV components, and heat dissipation components during the system's multi-year operating life. The common axes design feature of the system allows for low cost materials and manufacturing concepts. The system can operate on either a single or a dual axis tracker with active or passive cooling.

Abstract: The solar concentrator includes a carriage movable along an inclined, ground anchored ramp. A first weight at the end of a pulley carried first cable, biases the carriage upwardly of the ramp slope. A number of mirrors are pivotally carried by the carraige, and reflect sunrays toward a heat sink absorber. A second weight biases the mirrors to pivot in one direction, while a third weight biases the mirrors in an opposite direction. The operator can put into operation the second or third weight as he chooses. Gravity induced up or down carriage displacement allows sun tracking adjustments on an incremental, day to day basis. Gravity induced mirrors pivotal motion allow sun tracking adjustments on a continuous basis during each daylight period. Hence, all year long, solar rays reflected by the mirrors remain convergent toward the absorber.