Abstract: The invention concerns a solar collector (10) which has at least one radiation-transmitting prism (16) which is wedge shaped in cross section. The prism has major side surfaces (20, 21) converging at an acute angle to a relatively narrow, operatively upper end (24). The opposite, lower end (26) of the prism is wider. A refractor (18) is arranged over the prism to refract solar radiation incident thereon onto the major side surfaces of the prism, as the sun moves relative to the earth, at angles allowing such radiation to enter the prism and be internally reflected therein towards a target at or adjacent the relatively wide end of the prism. The configuration allows high levels of solar concentration to be achieved.

Abstract: The present invention provides a solar tracking apparatus for use with a power driving apparatus. The solar tracking apparatus includes: a memory unit for recording a first solar image; an image capturing unit for capturing a second solar image; and an processing unit for obtaining difference between the first solar image and the second solar image; wherein the processing unit activates the power driving apparatus in response to the difference. Furthermore, the present invention also provides a solar power generation system using the solar tracking apparatus. Besides the solar tracking apparatus, the solar power generation system also includes a solar panel; the power driving apparatus for adjusting the position of the solar panel, wherein the processing unit of the solar tracking apparatus activates the power driving apparatus based on the difference so that the solar panel is aligned with the sun to gather the solar energy of the sun.

Abstract: A solar-powered system and method for producing a utility, such as electricity, hot water, and/or potable water is disclosed. The system may be configured to produce the utilities alone or in combination. The system may comprise a fluid medium, a converter, one or more solar concentrators, a storage tank, a collection tank, a dehydration tank, and one or more safety features. The system may be closed-loop or open-loop.

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).

Abstract: A solar heat collecting dome includes a frame having an odd number of frame elements extending upward and inward from a floor structure to a disk at the top of the dome. A dome shaped helical structure including two flexible tubes is woven to extend along and around the frame elements, with the dome shaped helical structure extending across alternating inner and outer sides of the frame elements, and with adjacent portions of the dome shaped helical structure extending across alternating inner and outer sides of each frame element. At an outer end of the dome shaped helical structure, the two tubes form an inlet and an outlet. At the inner end, the two tubes are joined. The frame may also include a fluid path, with the fluid moving in opposite directions in each of the frame elements.

Abstract: Disclosed is an apparatus and method for improved efficiency in the collection of solar energy, in which an energy conversion device is provided that includes a first zone for converting received solar energy into thermal energy, the first zone having a Fresnel lens, and a heat absorption layer with heat collectors embedded therein. The energy conversion device also includes a second zone positioned at a lower level of first energy zone for converting received solar energy into electrical energy utilizing a photovoltaic cell.

Abstract: A device for concentrating optical radiation comprises a collection frame, and a radiation collector. The collection frame also has a collecting surface and a focal point 120. The collecting surface is adapted to collect optical radiation, and more particularly to collect solar radiation, from different directions, and guide the radiation to the focal point. The radiation collector is located at the focal point. It can collect the concentrated radiation for further utilization. The present invention is using simple, stationary and economical structures to increase area for collecting more sun light from all directions instead of increasing the radiation collector's area which largely saves the cost.

Abstract: A light collection device assembled with a light-processing unit comprises a fresnel lens unit, an anti-reflection layer and a light-processing unit. The fresnel lens unit has a light-incident surface and a light-emitting surface. The light-processing unit is positioned with the light-emitting surface for transmitting or converting a light emitted from the fresnel lens unit. The anti-reflection layer is mounted or formed on the light-incident surface of the fresnel lens unit.

Abstract: A system for concentrating solar energy is provided. The solar concentrating system uses a membrane formed of a flexible material to form either a reflective or refractive surface of a predefined shape. A quantity of fluid disposed on the membrane deforms the membrane into the predefined shape. In one embodiment the fluid is a liquid and the deformation of the membrane is determined by the mass of fluid and the effect of gravity. In another embodiment, the fluid is a gas and the deformation of the membrane is determined by the pressure of the gas contained in a cavity formed by the membrane on the bottom and a transparent layer forming the top surface of the cavity.

Abstract: The present invention discloses a liquid inserted lens and solar panel focus system. Liquid such as water is inserted into a transparent solid casing with the shape of a convex lens to form a convex lens. A solar panel is placed between the convex lens and the focus point of the convex lens, such that the sunlight can be focus on the solar cells to increase light intensity and produce more electric energy. This structure reduces the weight of the lens and its cost, and can be used in the focusing of solar panel system or other shape of lens for different application such as a photo-telescope, optical microscope or triangular prism to reduce the weight of the lens.

Abstract: The parabolic trough collector includes a single-axis parabolic mirror (1) and a receiver tube (2) arranged at the focal point (F) of the parabolic mirror (1). The receiver tube (2) includes an absorber tube (4) and an outer tubular glass jacket (3) around it. To compensate for focusing errors in the parabolic collector and thus to reduce associated geometric optical losses, the tubular jacket (3) is provided with structural elements (9a, 9b, 9c, 9d), which focus sunlight reflected from the mirror as well as sunlight that falls directly on the receiver tube from the sun on the absorber tube. The receiver tube is preferably arranged relative to the parabolic mirror, so that its center is displaced from the focal point (F) by a distance equal to half the spacing between the tubular jacket (3) and the absorber tube (4).

Abstract: A solar chimney includes a solar collector which heats air in the chimney, producing updrafts which can be harnessed to perform useful work. The solar collector may be located inside or outside the chimney. The device may include a reservoir for storing a heat transfer fluid, thus enabling the device to be used during both day and night. The solar chimney may be equipped with both internal and external solar collectors, operating in parallel. The solar chimney may also be equipped with multiple external solar collectors, connected in parallel to a reservoir. The solar chimney of the invention provides a convenient and practical way to convert solar energy into electrical power.

Abstract: A solar chimney includes a solar collector which heats air in the chimney, producing updrafts which can be harnessed to perform useful work. The solar collector may be located inside or outside the chimney. The device may include a reservoir for storing a heat transfer fluid, thus enabling the device to be used during both day and night. The solar chimney may be equipped with both internal and external solar collectors, operating in parallel. The solar chimney may also be equipped with multiple external solar collectors, connected in parallel to a reservoir. The solar chimney of the invention provides a convenient and practical way to convert solar energy into electrical power.

Abstract: A solar chimney includes a solar collector which heats air in the chimney, producing updrafts which can be harnessed to perform useful work. The solar collector may be located inside or outside the chimney. The device may include a reservoir for storing a heat transfer fluid, thus enabling the device to be used during both day and night. The solar chimney may be equipped with both internal and external solar collectors, operating in parallel. The solar chimney may also be equipped with multiple external solar collectors, connected in parallel to a reservoir. The solar chimney of the invention provides a convenient and practical way to convert solar energy into electrical power.

Abstract: A solar chimney includes a solar collector which heats air in the chimney, producing updrafts which can be harnessed to perform useful work. The solar collector may be located inside or outside the chimney. The device may include a reservoir for storing a heat transfer fluid, thus enabling the device to be used during both day and night. The solar chimney may be equipped with both internal and external solar collectors, operating in parallel. The solar chimney may also be equipped with multiple external solar collectors, connected in parallel to a reservoir. The solar chimney of the invention provides a convenient and practical way to convert solar energy into electrical power.

Abstract: A solar energy collection system for use in generating electric power from solar energy is provided. The system is comprised of a solar energy collector (16), a lens (14), and a support structure (12) for supporting the lens. The lens is comprised of one or more shaped surfaces (300) configured for modifying a path of incident light. In this regard, the lens provides an optical path which is used to expose the solar energy collector to a source of solar radiation (116). As such, the lens is interposed between the solar energy collector and an anticipated location of a source of solar radiation. The support structure includes an inflatable chamber defining an interior volume within which a gas is constrained. The inflatable chamber is comprised of a non-porous membrane (114). According to an embodiment of the invention, the lens is supported in position by the non-porous membrane. According to another embodiment of the invention, the lens is comprised of a portion of the non-porous membrane.

Abstract: The present invention relates to an apparatus for collecting and transmitting sunlight into a space comprising a solar ray collecting device, a solar light transmitting device and a solar light emitting device, wherein said solar ray collecting device is arranged to collect sunlight and direct said sunlight to said solar light transmitting device, said solar ray transmitting device is arranged to transmit said sunlight from said solar ray collecting device into said space and to said solar light emitting device, and said solar light emitting device is arranged to emit solar light in said space. Said solar ray collecting device comprises at least one convex lens and at least one concave lens, and at least said convex lens or said concave lens is arranged to be movable in dependence of the angle of incident solar light so as to focus the solar light onto said solar light transmitting means through said convex and concave lens.

Abstract: A light element with a translucent surface includes an energy converter, wherein the translucent surface is so formed as to direct only that portion of the radiation onto the energy converter that impinges on the translucent surface. The energy converter may be a solar cell, a fluid line or a light guide. The light element is particularly suited for illuminating interior spaces with diffuse light.

Abstract: A Fresnel lens including a substantially polygonal focusing portion adapted to focus solar radiation to a area having the same geometry as the focusing portion of the lens. Also a solar module including the Fresnel collecting lens and a substantially polygonal photovoltaic cell. The photovoltaic cell is mounted at distance from the Fresnel collecting lens so that the size of the area substantially matches the size of the photovoltaic cell. Also a solar panel having multiple modules within a glazed building envelope system. The solar panel also includes an actuating mechanism within the glazed window envelope system. The actuating mechanism is operatively connected to the plurality of solar modules and is adapted to move the solar modules to track the sun.

Abstract: This invention consists in a nonimaging device for concentration or collimation of radiation on a receiver or from an emitter (14), depending on the case. The device is made up of the lens (50), which surrounds the receiver and consists of the aspheric surface (21), and the lens (15), whose upper refractive surface (16) may be aspheric, while the lower surface is aspheric (17) in its central portion (between points 18 and 19) and has a structure with discontinuous slope (20) in its external portion, in which the faces (22) fundamentally refract the rays while the faces (23) reflect them by total internal reflection. The design method provides that the device properties of concentration/collimation are noticeably superior to those of the existing inventions. Possible applications of this lens include: radiation sensors, illumination systems with LEDs, wireless optical communications and photovoltaic solar energy.

Abstract: Method and system for converting solar energy into electrical energy utilizing serially coupled multijunction-type photovoltaic cells in conjunction with a form of spectral cooling. The latter cooling is carried out by removing ineffective solar energy components from impinging concentrated light, inter alia, through the utilization of dichroics or the conversion of ineffective solar energy components to effective energy components by means of luminescence, phosphorescence, or fluorescence. Ineffective solar energy components are described as those exhibiting wavelengths outside the bandgap energy defined wavelength and an associated wavelength defined band of useful photon energy.

Abstract: A tracking heliostat array comprises a plurality of optical elements. The tracking heliostat array further comprises a frame separated from the optical elements. Each of the optical elements has an orientation with respect to the frame. The tracking heliostat array further comprises a plurality of supports coupled to at least one of the optical elements. The tracking heliostat array further comprises a turnbuckle coupled to at least one of the supports and to the frame. Rotation of the turnbuckle causes the corresponding support to be displaced relative to the frame. The orientation of the optical element relative to the frame is adjustable. The tracking heliostat array further comprises a traveling actuator configured to rotate at least one of the turnbuckles. The tracking heliostat array further comprises a positioning mechanism supporting the traveling actuator. The positioning mechanism is configured to move the traveling actuator from a first selected turnbuckle to a second selected turnbuckle.

Abstract: A solar installation is described. It has a solar element and a diffractively and/or refractively operating optical apparatus by way of which the incident sunlight is passed directedly perpendicularly on to the solar element. The optical apparatus is caused to track the position of the sun by way of a tracking device. The optical apparatus uses a light-deflecting foil having portions of different natures with a structure having a different optical action. By virtue of the action of the tracking device the holographic foil is moved relative to the solar element so that different portions of the foil move into an operative position above the solar element in succession during the tracking procedure.

Abstract: A solar water heater is provided. The heater features heat control so that a maximum temperature is automatically controlled. The heater is insulated to maintain a water temperature of water stored therein for long periods of time. The heater includes an insulated lens which transmits most solar radiation incident on its top surface through the lens. An air trap is located below the lens. A heat control valve opens the air trap to surrounding air when a maximum temperature for air within the air trap is exceeded. A heat absorption plate is located below the air trap. The plate is in contact with a heat transfer liquid within a liquid space below the plate. A heat exchanger is positioned within the space and routes water in heat transfer contact with the liquid within the space, while keeping the water isolated from the liquid within the space.

Abstract: A solar concentrator system includes a collector lens for collecting and at least partially focusing incident solar rays, a solar cell and a lens array positioned generally between the collector lens and the solar cell, the lens array directing the partially focused rays emerging from the collector lens onto the solar cell.

Abstract: In a multi-lens hydrogen and/or electric/steam power plant there are mirrors 2, or equivalent, such as prisms, placed underneath lenses 1 directing ray bundles from several lenses 1 onto one focal point.

Abstract: A camouflaged structure and a method of camouflaging a structure against a background having a generally uniform composition of hue, saturation and brightness. In one embodiment, the camouflaged structures comprises a cell tower (100) camouflaged to decrease its visual impact when viewed by a viewer against a background sky (122) from an expected vantage point (102) using camouflaging techniques according to various aspects of the present invention. In a first aspect, the camouflage technique of the present invention comprises applying regions of color to one or more components of cell tower, wherein the colors are selected to match the composition (hue, saturation and brightness) of the background sky. In a seconds aspect, the camouflage technique of the present invention comprises providing one or more components of cell tower with reflectors that reflect light from an ambient sky (124) to a viewer.

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 method is disclosed for collimating light energy falling randomly from myriad directions on a fixed-positioned thin flat surface. The collimated rays are then concentrated by an assembly of prismatic slabs and optical or fiber optic means to achieve light concentrations of 700 or more times than that of normal sunlight. Applications are given for new products such as collimated beam non-blinding motor vehicle headlights; fixed-positioned solar collectors that collect and concentrate more than 80% of the direct and diffused radiation falling on their surfaces; generation of high pressure steam by means of solar energy; and efficient and economical photovoltaic and thermoelectric generators and fiber optic acceptors for concentrating and transmitting significant quantities of light energy.

Abstract: A solar collection system and method having means for receiving solar radiation through a main refractive interface and means for internally reflecting at least once, at least a portion of the received solar radiation. The refractive medium may be liquid, gel or solid. The device may be integrated with a photovoltaic device, photohydrolytic device, a heat engine, a light pipe or a photothermal receptor.

Abstract: An array of concentrators of electromagnetic radiation (i.e., visible light, radio waves, etc.) employing one or more concentrating devices. Each concentrating device includes: a concentrator system for concentrating the incident electromagnetic radiation impinging thereon; a collimator system disposed in the path of electromagnetic radiation from the concentrator system for producing a beam of electromagnetic radiation; and a redirecting system. Each concentrating device has one or more of its elements staggered such that the beams from the array of concentrating devices result in a stacked or bundled plurality of beams. This bundle of beams is then concentrated again, recollimated and redirected to join with other similarly concentrated beams. This arraying can be repeated again and again, producing stronger and stronger beams or electromagnetic radiation, if desired.

Abstract: A solar collector tracking system that has a solar collection device having multiple lens assemblies mounted on its front surface. An exoskeleton structure is secured to the rear surface of the solar collection device and it is pivotally secured about a horizontal axis to the front end of an azimuth platform assembly. A hydraulic elevation actuator is pivotally mounted in the azimuth platform assembly about a horizontal axis and the front end of its piston rod is pivotally connected to the rear surface of the solar collection device and this allows it to be pivoted approximately 90 degrees between a vertical operating position and a horizontal storage position. The azimuth platform assembly is journaled on the top end of a tower extending up from the ground. A tubular post is rigidly secured to the top end of the post. A drive head extends horizontally from the tubular post and it has a pivot pin that extends upwardly therefrom.

Abstract: A novel, high-efficiency, extremely light-weight, inflatable refractive solar concentrator for space power is described. It consists of a flexible Fresnel lens, flexible sides, and a back surface, together enclosing a volume of space which can be filled with low pressure gas to deploy the concentrator on orbit. The back surface supports the energy receiver/converter located in the focal region of the Fresnel lens. The back surface can also serve as the waste heat radiator. Prior to deployment, the deflated flexible lens and sides are folded against the back surface to form a flat, low-volume package for efficient launch into space. The inflatable concentrator can be configured to provide either a line focus or a point focus of sunlight. The new inflatable concentrator approach will provide significant advantages over the prior art in two different space power areas: photovoltaic concentrator arrays and high-temperature solar thermal conversion systems.

Abstract: A solar power heating system includes a plurality of concentrating solar collectors each comprising a frame having two side walls and a reflecting layer attached to the inside thereof. Each of the side walls has two engaging members so as to conveniently connect with others. An isolating block is received between the two side walls and a circulating tube is engaged in the isolating block with a section of the circulating tube being exposed from the top of the isolating block. An absorbing layer is attached to the top of the isolating block and the section of the circulating tube. A lens device is connected between the two side walls so that water flowing through the circulating tube is heated by the absorbing layer. A heat exchanging device is connected to concentrating solar collectors.

Abstract: A high efficiency, light weight solar concentrator array particularly suitable for use with space vehicles. Parallel rows of mirror assemblies are mounted on a base plate having high thermal conductivity. Each mirror assembly comprises back-to-back mirror strips having reflecting front faces. Photovoltaic cells are placed ion the base plate between rows of mirror assemblies. The reflecting faces reflect incident light to the photovoltaic cells to produce electric power. Preferably, the reflecting faces have a cylindrical parabolic configuration with a line of focus approximately along the interface between the photovoltaic cell and the edge of the opposite mirror strip adjacent to the cell. The mirror strips may typically be roll formed from metal strips, cast from fiber reinforced plastic material and coated with a reflecting layers, etc.

Abstract: A novel, high-efficiency, extremely light-weight, robust stretched Fresnel lens solar concentrator for space power is described. It consists of a flexible Fresnel lens attached to end supports, wherein said end supports stretch the lens to maintain its proper position and shape on orbit in space. One embodiment of the new concentrator includes means for lens deployment on orbit in space. In this embodiment, prior to deployment, the flexible lens and end supports are folded into a flat, low-volume package for efficient launch into space. Another embodiment of the new concentrator includes non-deployable means of stretching the lens to maintain its proper position and shape in space. Both embodiments of the new concentrator approach will provide significant advantages over the prior art in space photovoltaic concentrator arrays. Photovoltaic concentrator arrays using the new stretched lens will be much lighter and more economical than prior space concentrator arrays.

Abstract: A solar collector comprising an evacuation envelope; an absorber housed inside the evacuated envelope and comprising plates which define an evaporation gap, the evaporation gap providing communication between a reservoir of heat transfer fluid at a first, bottom end of the absorber and a condenser at a second, top end of the absorber. The plates define the evaporation gap so that capillary action between the plates can draw heat transfer fluid from the reservoir along at least a substantial portion of the evaporation gap to the condensor. The absorber transfers heat derived from the incident solar radiation to heat transfer fluid contained in the evaporation gap.

Abstract: A photovoltaic power source includes a shadowing timer comprising at least one shadowing member (i.e. vane element) secured proximal to an array of photovoltaic solar cells electrically connected in series. The shadowing members are arranged such that they shadow individual solar cells or rows of cells as the sun moves through diurnal and annual cycles. The shadows cast by two or more vanes can modulate the array output power on two independent time scales: time of day and time of year. Because the individual solar cells are connected in series, a small shadow significantly reduces the array output power, thus enabling fine-scale temporal control.

Abstract: A color-mixing lens for use in a concentrator system and methods of manufacture and operation thereof. The color-mixing lens includes: (1) a light-transmissive substrate that receives broad spectrum light from a source, (2) a first plurality of prisms, located on the substrate, that refract and chromatically disperse the light received therein toward a first plurality of locations on an active region of a target cell, and (3) a second plurality of prisms located on the substrate that refract and chromatically disperse the light received therein toward a second plurality of locations on the active region. Relative dimensions of the first and second pluralities of prisms are preselected to cause the chromatically-dispersed light to mix and thereby increase a power output of the target cell by reducing inter-junction currents therein.

Abstract: A modular solar energy collector having elongated V-shaped side walls formed by a pair of coplanar panels for each side wall. The upper panels, occupying most of the wall area are diffusely reflective, but the lower panels are specularly reflective. A Fresnel lens, having a snap fit relation to the side walls focuses some light on the lower specularly reflective panels which direct light to the solar cells at the base of the V-shaped walls. A heat sink provides support for the two panels with two opposed, upwardly extending wings terminating in opposed linear clips located near the lengthwise seam of the coplanar panels, each clip holding two coplanar panels in parallel alignment. The clips not only provide support for the panels, but also transfer heat to the remainder of the heat sink. The clips are shaped so that edges of the panels engage each clip by a snap fit, outside of the clip in one embodiment and inside of the clip in another embodiment.

Abstract: High radiation concentration photovoltaic cell system including at least one optical structure in the form of a three-dimensional body having a first surface adapted to receive thereon photovoltaic cells and a second surface to be, at least indirectly, exposed to light radiation. The body of the optical structure has formed between its first and second surfaces a two-dimensional array of contiguous light radiation concentrators each in the form of an individual prismatic body portion. Each prismatic body portion tapers in two dimensions toward said first surface along the entire length of the concentrator. Each concentrator defines on the first surface a photovoltaic cell-attaching area to be aligned with an active portion of a single photovoltaic cell to be attached thereto.

Abstract: To provide a tracking-type solar module capable of high-performance sunlight-tracking with a simple configuration while simultaneously performing highly effective cooling of a solar cell, a solar cell is movably installed within a transparent cooling tube and is connected to a motor with a crank. A position detecting sensor is also installed inside the transparent cooling tube. Sunlight is refracted by a cooling medium filled inside the transparent cooling tube and is converged on the inner surface of the transparent cooling tube. The position detecting sensor detects the position at which sunlight is converged and the sunlight is tracked by the motor moving the solar cell to that position. Simultaneously, the cooling medium inside the transparent cooling tube directly cools the solar cell.

Abstract: A solar energy conversion system, in which two separated arrays of refracting elements disperse incident sunlight and concentrate the sunlight onto solar energy converters, such that each converter receives a narrow portion of the broad solar spectrum and thereby operates at higher efficiency.

Abstract: For the purpose of providing a solar module which has a fixed type solar concentrator of high converging magnification, a solar cell 12 is installed on the bottom face of an extension 30 which is extended further from the apex of a V shape formed by a pair of prisms having a refractive index larger than that of air, and a mirror surface 18 is formed on the back side of an incident surface 20 on which sunlight 10 falls. The mirror surface 18 and the incident surface 20 are formed in such a manner that their distance widens toward the apex of the V shape. The sunlight 10 incident on the prisms 16 performs reflection on the mirror surface 18 and total internal reflection on the incident surface 20, respectively. After repeating such reflection, the sunlight 10 reaches the bottom of the extension 30, where it emerges as outgoing light 22 to the solar cell 12.

Abstract: There is provided a converging solar module of a simple structure which can accurately track the sun and efficiently generate electricity. A converging solar module comprises an electricity generating converging lens (10) made of resin having a flat shape, and a solar battery cell (12) placed in the vicinity of a focal area of the converging lens (10). The converging lens (10) and the solar cell (12) are rotatable as a unit. The electricity generating converging lens (10) is attached to a shaft (20) of a rotation driving motor (18). Using sunlight converged by a cylindrical position detecting converging lens (40), a position detecting sensor (42) locates the sun, and outputs information regarding the position of the sun as angle information to a controller (48).

Abstract: The present invention discloses a converging type solar cell element able to restrain recombination of carriers and inflow of carriers into an embankment section and improve photoelectric conversion efficiency. A p.sup.+ diffusion layer 16 is formed on the surface of a sunlight receiving section 10 which is formed on a silicon substrate 12 comprising a p-type silicon. An energy gradient arises between the p.sup.+ diffusion layer 16 and the silicon substrate 12. Therefore, free electrons, which are minority carriers among the carriers generated in the silicon substrate 12 resulting from irradiation of sunlight to the sunlight receiving section 10, can be prevented from migrating to the surface side of the silicon substrate 12. Further, recombination of free electrons which may arise due to lattice defects of the surface can also be prevented. Still further, the p.sup.+ diffusion layer 16 may also be formed on a back surface side of the embankment section 14 which surrounds the sunlight receiving section 10.

Abstract: For a converging solar cell element capable of preventing excessive concentration of converged sunlight to one point without lowering the degree of light convergence, a p+ layer 14 and an n+ layer 12 are formed on the rear surface of a silicon substrate; a positive pole 16 and a negative pole 18 are formed in response to the respective layers; and, on the front surface side, a light receiving surface 24 is formed with a bank portion 28 which enhances intensity in the surrounding area. In the central portion of the light receiving surface 24, a projected portion 26 is formed, which scatters converged sunlight and prevents the concentration of converged sunlight to one point.

Abstract: A multiple lens solar heating unit consisting of a piping component, a housing component with a transparent housing cap, holes within the housing component for entry and exit of the piping component, multiple lens mounting braces affixed parallel wise to inner walling of the housing component, a plurality of external lens holders mounted to the braces by mounting pins and rotatably pivotable in an XY plane, an equivalent plurality of internal lens holders mounted one each to each external lens holder by mounting pins and rotatably pivotable in an XZ plane and an equivalent plurality of magnifying lens mounted one each within each internal lens holder.

Abstract: A solar cooker which has at least one biconvex lens which can concentrate solar rays onto an item to be cooked. In addition, the solar cooker utilizes a series of pulleys to rotate the lens from an angle of 45.degree. on each side of the sun's zenith in order to effectively collect the sun's rays at different times of the day.

Abstract: A solar heat collecting apparatus includes a first, inner glass dome, and a second, larger outer glass dome disposed outwardly from the inner dome. Both of the inner and outer domes have respective inner and outer surfaces and an open end, and an infrared reflective coating is adhered to the inner surface of the outer dome. A solder glass seal joins the open ends of the inner and outer domes together, thereby forming a void between said inner and outer domes. Means are provided for rechargeably forming a vacuum in the void, and an absorber plate is disposed beneath and covered by the inner and outer domes. Solar radiation entering the solar heat collecting apparatus according to the present invention is absorbed by the absorber plate, and transferred to a remote storage system by conventional heat transfer means, such as an array of conduits placed in thermal contact with the absorber plate and containing a suitable fluid.