Abstract: An energy conversion system includes a water-containing vessel with a transparent sidewall. Energized carbon rods are fed into the vessel such that the carbon rods are immersed in the water. The carbon rods are juxtaposed sufficiently that electrical arcing occurs between them, causing decomposition of some water molecules into constituent hydrogen and oxygen gas. Photon emissions resulting from the arcing are collected by photovoltaic cells placed around the sidewall of the vessel. The hydrogen gas is cooled by passing it through a water reservoir which also provides a source for water in the vessel. The cooled hydrogen gas may be used to fuel an internal combustion engine. Byproduct heat from the arcing reaction may be utilized in a Stirling engine or radiated from the system. As the carbon rods become depleted during arcing, additional rods are fed through conductive sleeves into the vessel by linear actuators.

Abstract: The solar concentrator includes a base with a support frame that is rotatably connected thereto. A torsion box is tiltably mounted to the support frame to provide a wide range of movement of the torsion box and the finish surface thereon, which is preferably of a single plane parabolic shape that carries a layer of highly reflective chrome material. A receiver is mounted above the surface of the chrome layer at the focus of the parabola by a bracket to optimize reflection of radiation thereto. Plumbing transports liquid, such as water, through the receiver for heating thereof for various purposes, such as water desalinization. Thus, the solar concentrator is an optimized low cost and easy to manufacture solar concentrator.

Abstract: A concentrating solar energy device for use in buildings is configured to share structural elements with a building for cost savings. The device incorporates a shallow cylindrical trough mirror comprising mirrored sheets that are conformed to curved rafters, a receiver that is moveable within the cumulative area of focus of the cylindrical trough mirror, a secondary mirror integrated with the receiver that augments solar energy collection, and parallel linear tracking assemblies that move the receiver and that mount to a building's side walls.

Abstract: A reciprocating solar engine includes a) a seesawing platform having a central fulcrum support upon which to reciprocally rotate the platform; b) a first container located on the platform on one side and a second container located on the other side of the platform; c) a solar reflector located adjacent each container; d) a connecting tube connecting the first and second containers; e) an evaporative fluid contained within at least one of the containers; f) a roof above the platform with a window located above each of the containers; g) shutter devices at each of the windows; and b) shutter device controls to activate the shutter devices to present alternating exposure of sunlight and shading at each of the containers to effect reciprocal movement.

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

Abstract: A trough collector (1) for solar power plants comprises a pressure cell (25) containing an absorber pipe (42) for a heat-carrying fluid and also a secondary concentrator which is likewise arranged in the pressure cell (25). The pressure cell (25) thus can be reduced in height, which eliminates the need for reinforcements in the form of a framework structure for the pressure cell (25), which are otherwise required.

Abstract: The invention relates to a trough collector (1) for a solar power plant, comprising a mount (34) carrying a supporting structure (30), means disposed on the supporting structure (30) for providing heat originating from incident solar radiation, and a pivot device (40) that is fixed to the supporting structure (30) and is used to pivot the supporting structure (30) with respect to the mount (34), wherein the centroidal axis (36) of the supporting structure (30) equipped with the means for providing the heat is located outside the pivot axis of the supporting structure (30), and wherein the pivot device (40) is configured such that the centroidal axis (39) of the fully equipped supporting structure (30) is located in the region of a fixed pivot axis (35). In this way, a cost-effective, and zero-backlash pivot drive for the trough collector is obtained.

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 solar heated water server is a batch type solar water heater that is integrally mounted on a wheeled chassis. The server enables a person to fill the solar heater with water through an externally pressurized hose that is then disconnected. The server can then be moved by hand into a position which best captures sunlight. Said chassis is constructed to allow adjustment for solar angle as well as azmuth. The solar water heater is constructed with curved internal reflectors that allow for the capture of a wide angle of diffuse radiation and also reflect direct sunlight onto the absorber tank over a wide azmuth angle. When the water is hot, the server is then wheeled to the point of use and reconnected by a hose to a source of pressurized cold water. The hot water can then be forced out by and mixed with cold water.

Abstract: An improved solar collector pipe that directly conveys fluid to be heated and collects and transfers solar energy efficiently and directly to the internal fluid, thereby maximizing both the amount of energy transmitted to the internal fluid and the peak temperature attainable by that fluid. The solar collector pipe includes a transparent portion for admitting solar energy into the solar collector pipe. Internal to the solar collector pipe is an absorbing portion for absorbing solar energy. A conduit portion is also included and comprises a reflecting surface thereon for reflecting solar energy received through the transparent portion onto the absorbing portion. In embodiments of the invention, the transparent portion, the conduit portion, and the absorbing portion together define at least one fluid passageway for conveying the fluid. In other embodiments of the invention, an internal conduit defines a fluid passageway for conveying the fluid.

Abstract: A solar receiver (10; 110) for a solar thermal power plant comprises an elongated supply chamber (16; 118) for a heat carrier medium flowing in the supply chamber (16; 118) at a small loss of pressure, an elongated absorber (13; 113), the inlet areas (21; 119) thereof extending in a longitudinal direction and limiting the supply chamber (16; 118), and a drain chamber (18; 125) extending in a longitudinal direction and being contained in the supply chamber (16; 118) for the heated heat carrier medium and being limited by at least one outlet area (22; 124) extending in a longitudinal direction, the inlet area (21; 119) and the outlet area (22; 124) being offset against each other in a transverse direction. This is why the heat carrier medium flows in a transverse direction to the absorber (13; 113) so that the flow causing a loss of pressure is limited on a relatively short path and the heat carrier medium being heated flows towards the increasing intensity of incident radiation.

Abstract: A concentrating solar array consisting of a roll of reflective film which is stretched between tension wires strung between a pair of wire stays. There is a roll of film and a take up roll such that the film can be unrolled from the storage roll and pulled toward the take-up roll to replace degraded film. A pair of extension arms holds a solar cell at a fixed position relative to the solar concentrator film surface to receive concentrated sunlight. The roll of reflective film ensures the life requirements of the solar concentrator can be met in space, by replacing exposed concentrator film as it degrades.

Abstract: The present invention relates to an improved solar energy concentrating system having a novel focal collection zone. In general, the system comprises a moveable solar energy collector supported above a cylindrically arcuate solar energy concentrating reflector. Instead of positioning the collector to rotate about the center of curvature of the reflector and to extend down halfway between the center of curvature and the reflector, in the present invention, the solar energy collector extends further down according to a particular algorithm.

Abstract: The present invention relates to an improved solar energy concentrating system incorporating replaceable solar energy concentrating reflectors. Prior systems typically required a structurally stable solar energy concentrating panel. The present invention uses a combination of structurally stable backing panels and flexible solar energy concentrating reflectors to significantly reduce the ease and cost of replacing reflectors.

Abstract: A device for absorbing heat energy, in particular a solar panel, includes a housing in the form of a frame-shaped rack. The housing has a cover which allows the radiant energy to enter. Several collector tubes are disposed below the cover and between a distributor tube and a gathering tube. The collector tubes are provided with wing-shaped collector elements. The collector tubes are rotatably mounted such that the collector elements can follow the position of the radiation source, such as the sun. The collector elements are thereby disposed at a mutual spacing such that a shading from the adjacent collector element is prevented, even at the lowermost position of the sun. The collector elements are further provided with a heat absorbing coating on both sides, and reflectors are provided below the collector elements as seen in the direction of the incoming heat radiation.

Abstract: The present invention is a cross-section arrangement for solar concentrators which is comprised of a concave reflective boundary, and of at least two receiver-converters extending outward within the concavity wherein the second receiver-converter is well removed from the first and the multiple receiver-converters may communicate with each other.