Abstract: A double line focusing solar energy collection apparatus of the present invention includes a heat collector, a secondary concentrator, and a bracket. The heat collector includes a primary concentrator and a heat collection tube, in which the primary concentrator has a focus line. The secondary concentrator has a focus line. The bracket supports the primary concentrator, the heat collection tube, and the secondary concentrator. The heat collection tube is located between the primary and secondary concentrators and located on the focus lines of the secondary and primary concentrators. The primary concentrator is a paraboloid reflector or Fresnel reflector. The secondary concentrator is a paraboloid reflector or Fresnel reflector. By adding the secondary concentrator, it achieves low light loss and high heat collection efficiency, and erosion of the heat collection tube by sand, rain, and snow can be effectively prevented, thereby extending the lifetime of the heat collection tube effectively.

Abstract: A water sanitizing system is disclosed and includes an inner chamber and an outer chamber disposed at least partially around the inner chamber. A lens concentrates solar energy applied to a liquid within the inner chamber. A vacuum source in communication separately with the inner chamber and the outer chamber. The vacuum source controls a pressure within the inner chamber separately from the outer chamber for controlling conversion of liquid within the inner chamber to a gas. The outer chamber, also under vacuum, is an insulative layer to prevent heat loss.

Abstract: A solar collector device is provided. The solar collector device includes an evacuated tube and a mini-channel tube mounted within the evacuated tube, the mini-channel tube comprising a first plurality of ports for inflow of a heat-transfer fluid and a second plurality of ports for outflow of the heat-transfer fluid to a heat exchange system. The mini-channel tube may have a hydraulic diameter in a range of approximately 3 millimeters to approximately 200 micrometers. The mini-channel tube may have a hydraulic diameter in a range of approximately 200 micrometers to approximately 10 micrometers.

Abstract: A solar energy collector includes a first member having a cavity and a longitudinal axis. The first member has a longitudinal window forming a part thereof and a body forming another part thereof. The longitudinal window is made of a material adapted to be transparent to solar radiation. The body has an exterior absorptive surface and an interior reflective surface. A second member is located within the cavity of the first member and is generally parallel to longitudinal axis of the first member. The second member is adapted to carry an energy absorbing fluid. An insulative material fills the cavity between the first member and the second member. A solar energy collection system includes the form going solar energy collector and a solar energy transmitting device for directing solar energy through the window of the collector.

Abstract: A solar energy collector comprises a solid body having a substantially planar solar energy absorbing collecting surface. The solid body has a first thickness at a center portion tapering to a second thickness at each of a pair opposing edge portions defining a width of the body. A bore extends completely through the body along its length and is aligned along an axis at the center portion. A window transparent at most solar radiation in the visible spectrum and near UV to infrared-red solar energy wavelengths is disposed at a distance from the collecting surface, the window sealed around a periphery of the collecting surface to define a sealed air gap or nitrogen gas filled gap between the collecting surface and the bottom surface of the window. The solar energy collector is a major component of a solar water heating system.

Abstract: A solar air conditioning system and method of superheating working fluid is provided. The solar air conditioning system superheats the working fluid using radiant energy from the sun, and then delivers the working fluid as a superheated and higher-pressured gas to a condenser within the solar air conditioning system. The solar air conditioning system includes a solar collector within which the working fluid is superheated.

Abstract: The present invention relates to a tile for a roof or the like comprising a tile body with at least one vacuumed closed space to provide the tile with a thermal insulation barrier for the maintenance of a more stable temperature within an internal roof area. The tile body is manufactured from recycled glass and preferably is formed as foam glass containing a plurality of vacuum containing bubbles. The tile also comprises at least one energy recovery means such as heat absorbing aluminum wafers to provide for heat transfer through conductivity into a hot water supply or voltaic cells to provide for electricity generation. Light is focused onto the energy recovery device by a profiled translucent cover. These and other variations provide for a roof tile which is environmentally friendly, easy to install with improved thermal, energy efficient and sound-proofing qualities.

Abstract: The present invention relates to a solar energy collector (18) including an outer casing (20) having at least one aperture (22) disposed therein and an absorber (24) disposed within the outer casing (20). The aperture (22) is arranged to receive a beam (16) of solar radiation therethrough so that the beam (16) is incident on the absorber (24). The absorber (24) is arranged in use to absorb the energy of the beam of solar radiation and to thereby convert solar radiation to heat energy to heat a fluid communicated through the absorber (24). The absorber (24) is arranged to be moved by a moving means to promote even heating of the absorber (24).

Abstract: A double-sided vacuum thermal solar panel comprising a vacuum-tight envelope capable of withstanding atmospheric pressure when evacuated, the envelope comprising a first and a second glass plate transparent to solar radiation and facing each other, a perimeter frame defining the lateral surface of the envelope, the solar panel comprising at least one first heat absorber, a second heat absorber, a pipe which enters and exits the envelope by passing in between the first and second heat absorber, and a box-like element which surrounds the outer surface of the pipe.

Abstract: A solar power conversion receiver is described. In one aspect, the solar power conversion receiver includes a circular glass envelope and an absorber tube encapsulated within the circular glass envelope. An annulus, positioned between the circular glass envelope and the outer perimeter of the absorber tube, is bifurcated by first and second fins operatively coupled to the circular glass envelope and the absorber tube. These fins create first and second annulus compartments that are substantially sealed off, or independent, from one another. The first and second fins are ductile and responsive to expansion and contraction of components in the solar power conversion receiver due to temperature effects. In one aspect, gas in the lower annulus compartment stratifies with cooler gas interfacing with the encapsulating glass envelope, and hotter gas interfacing with the hotter absorber tube, resulting reduced natural convection heat loss as compared to conventional glass encapsulated receivers.

Abstract: A light energy conversion (LEC) system includes a fluid circuit having a working fluid flowing therethrough and a plurality of light concentrating (LC) modules for converting light energy into electrical energy and for transforming the light energy into thermal energy. The LC modules including a first LC module coupled in series with a second LC module along the fluid circuit. The working fluid absorbs thermal energy while flowing through the first and second LC modules. At least the first LC module includes a light concentrating optical element that is configured to direct light energy toward a focal region and a receiver held at the focal region. The receiver includes a housing having a chamber that holds an energy conversion member. The energy conversion member transforms light energy received from the optical element into electrical and thermal energy.

Abstract: The solar panel includes a housing for a heat collecting element, delimited by walls, one of which includes slits for the passage of solar rays. At least one reflective area is arranged to face the heat collecting element. At least one reflective strip is arranged outside the housing to face a respective slit so as to focus the solar rays received towards this slit. Elongated reflective elements are arranged side by side, and include coplanar flat bases, forming together the wall of the housing having slits and the flat base of at least one elongated reflective element forming a reflective area of this wall of the housing, and including one concave surface arranged to face the reflective strips such that the solar rays reflected by each concave surface are focused towards the corresponding reflective strip.

Abstract: [Problem] To present a solar heat collecting pipe capable of enhancing the heat collecting efficiency by suppressing the dissipation of energy transmitted to the heat medium passing through the inside of an inner pipe. [Solving Means] In the solar heat collecting pipe 1 including the inner pipe 11 for receiving sunlight collected by the light collecting mechanism 2, and transmitting energy to the heat medium 14 passing through the inside, and the outer pipe 12 covering the outer circumference of the inner pipe 11, a solar heat absorbing film 11a is applied in a portion exposed to sunlight of the inner pipe 11 of the solar heat collecting pipe 1 (the portion exposed to the reflected light of the sunlight at least on the surface of the inner pipe 11, and a heat reflecting film 11b is applied in a portion not exposed to sunlight from the light collecting mechanism 2.

Abstract: A heat exchanger comprises a vacuum tube with an outer wall. An inner tube can be filled with a heat-conducting fluid. The outer wall of the inner tube is situated concentric to a wall of the vacuum tube. At least one heat-conducting film is provided that joins said wall of the vacuum tube to the fluid-conducting tube system. A means which collects and concentrates solar energy is provided on the wall on the side of the vacuum tube facing away from the heat-conducting element. In addition, each heat-conducting element, while being pretensioned, presses against the wall of the vacuum tube and against the fluid-conducting tube system.

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: The solar panel includes a housing for a heat collecting element, delimited by walls, one of which includes slits for the passage of solar rays. At least one reflective area is arranged to face the heat collecting element. At least one reflective strip is arranged outside the housing to face a respective slit so as to focus the solar rays received towards this slit. Elongated reflective elements are arranged side by side, and include coplanar flat bases, forming together the wall of the housing having slits and the flat base of at least one elongated reflective element forming a reflective area of this wall of the housing, and including one concave surface arranged to face the reflective strips such that the solar rays reflected by each concave surface are focused towards the corresponding reflective strip.

Abstract: A system for heating liquid using solar radiation, includes a plurality of solar panels (1, 2, 3, 4, 5), at least one reservoir for heated liquid and pipes for circulating liquid between the respective solar panel and the at least one liquid reservoir, the liquid circulating by gravity circulation. The present system is characterized in that a non-return valve (17) for controlling the flow of heated liquid from the respective solar panel is placed in a portion of the circulation pipe between the upper end of the solar panel and the at least one liquid reservoir, the non-return valve (17) being adapted to open and close at a predetermined pressure in the liquid flow from the solar panel.

Abstract: This invention relates to a fluid heating system, wherein the fluid is capable of being heated by means of solar energy, the fluid heating system including: an outer housing; an inner housing contained within the outer housing and including an absorbent material core located within the inner housing to define a flow passage between it and the walls of the inner housing; the absorbent material core being suitable for absorbing solar energy transmitted through the outer and inner housings; and wherein the outer housing; inner housing; and the absorbent material core are arranged such that solar energy is transferred through the fluid in the flow passage before being absorbed by the absorbent material core.

Abstract: Parametric cylindrical solar collector with an optimized secondary reconcentrator and its design process, where the geometry of the primary reflector is an evolution of the Helmet collector concept towards a discontinuous curve that allows increasing the C/Cmax concentration to over 0.52 as well as reducing the wind loads. The structure is optimized to withstand the different loads to which the collector is exposed. The collector's center of gravity is brought closer to the axis of rotation of the collector. The geometry of the secondary reconcentrator is optimized and the collection efficiency of the collector is of 100%. The secondary reconcentrator is obtained partially mirroring the glass tube that keeps the vacuum in the absorber tube.

Abstract: An absorber pipe for solar collectors is provided. The absorber pipe includes a metal pipe for and a cladding pipe surrounding the metal pipe to form an annular space that can be evacuated. The absorber pipe can include a wall extending between the cladding pipe and the metal pipe for sealing the annular space and a retaining device for a getter material or a container filled with getter material or inert gas. The retaining device has a receiving section for receiving the getter material or the container. The retaining device is fastened to the wall. The absorber pipe can alternately include a getter material disposed in the annular space for binding free hydrogen present in the annular space and a reflector disposed in the annular space for reflecting radiation. The reflector has a housing with a support section for fastening and protecting the getter material from the radiation.

Abstract: A solar collector is provided that concentrates solar energy for heating a medium such as air. The solar collector includes a housing with a first end wall, a second end wall and a cavity therebetween. A receiver tube is extended through the first end wall on a first end and extending longitudinally within the cavity. A receiver core member made from a metal foam material is disposed within the receiver tube. At least one mirror is arranged within the cavity opposite the receiver tube, the at least one mirror being arranged to reflect light onto the receiver tube. In one embodiment, an automated cleaning system is arranged to clean the collector cover. In another embodiment, the mirror is made from a dielectric mirror.

Abstract: Various embodiments for an improved solar collector are disclosed. For example, a heat absorber can be positioned inside an evacuated chamber formed by a frame and a transparent cover. Heat absorbed by the heat absorber within the evacuated chamber can be delivered to a heat transfer fluid inside a chamber of a heat exchanger. The heat exchanger chamber can also reside in the evacuated chamber. In a preferred embodiment, the heat absorber comprises a planar heat pipe. Also in a preferred embodiment, a reflector can be positioned to reflect energy radiated by the heat absorber back to the heat absorber.

Abstract: A double-sided vacuum thermal solar panel comprising a vacuum-tight envelope (30) capable of withstanding atmospheric pressure when evacuated, said envelope (30) comprising a first and a second glass sheet (1, 2) transparent to solar radiation and facing each other, a perimetral frame (3) defining the lateral surface of said envelope (30), said solar panel comprising at least one first heat absorber (11), a second heat absorber (12), a pipe (13) which enters and leaves said envelope (30) by passing between said first and second heat absorber (11, 12), and a box element (10) which surrounds the outer surface of the pipe (13).

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: A system for heating water and cooling a house has a power cell including a first tube to contain the water so that the water cools the power cell, a power unit that produces the electricity from light, a mirror that reflects the light onto the power unit, and a lens that helps focus the light onto the power unit; a water heater including a second, generally transparent tube to contain the water that is warmed by the light, a third tube inside the second tube to contain the water that is further warmed by the light, and a reflective material on the second tube that helps reflect the light onto the third tube; and a thermal barrier including a base made of material that provides thermal isolation and shade for cooling.

Abstract: A solar heat collection element includes: a central tube (102) formed from glass-ceramic material; and an outer tube (104) formed from glass material disposed coaxially with respect to the central tube (102) to form a volume therebetween (106).

Abstract: A solar panel that utilizes the sun's rays to heat a liquid to be used for providing heat or hot water includes front and rear parallel clear plastic panels. The front panel is intended to face the sun and is substantially transparent so that the sun's rays can pass there through The rear panel has a reflective coating thereon wherein rays from the sun are reflected back toward the space between the panels. Located within the space are a plurality of conduits formed by a plurality of internal walls that extend between the panels and the left and right side edges. Within the conduits is a darkened oily liquid that is heated by the incoming rays of the sun and the rays reflected by the rear panel. In a preferred embodiment, the front and rear panels and the internal walls are extruded as a single unit.

Abstract: A solar collecting apparatus for collecting solar energy in a heat transfer fluid includes an upper header member, a lower header member, and a plurality of collector tubes, each collector tube connected at an upper end thereof to the upper header member and connected at a lower end thereof to the lower header member. The collector tubes are arranged such that axes of the collector tubes form an array wherein no three adjacent axes are on the same plane, typically in a cylindrical or like array.

Abstract: A solar panel, through which a fluid is circulated, includes a transparent central panel, with a number of channels extending through the panel from one end to another. A manifold is attached to each end of the transparent central panel so that distributing chambers within the manifolds direct the fluid to move between adjacent channels within the central panel. The solar panel additionally includes a transparent support structure above the central panel and a lower support structure below the panel. Dark, opaque material below the central panel absorbs heat and warms the fluid.

Abstract: A solar collector with external reflector. A solar collector includes a glass housing having a heat pipe disposed within the housing and a light reflector disposed external to the housing.

Abstract: The parabolic trough collector has a receiver formed by several single absorber tubes (13). The single absorber tubes (13) are supported by absorber tube supports (14) and surrounded by a glass tube (15). Because of different expansion behavior of the absorber tube (13) and the glass tube (15) during collector operation flexible unions (17) are foreseen between absorber tube (13) and glass tube (15). In order to use the radiation coming to the non active-area where the absorber tube supports (14) and the flexible unions (17) are installed a mirror collar (20) is installed on this area. The mirror collar (20) is able to reflect the solar radiation, which is coming from different directions, to the active absorber part of the single absorber tubes (13) also when the sun incident angle is changing.

Abstract: The absorber pipe (1), especially for a parabolic collector for a solar heat collecting apparatus, is described. The absorber pipe (1) includes central metal pipe (3), a glass sleeve tube (2) surrounding the nine so that an annular space (4) is formed between them and an expansion compensating device connecting the central metal nine and a glass-metal transitional element (5) on a free end of the sleeve tube (2). The expansion compensation device (10) connects the metal pipe and sleeve tube, so that they can slide relative to each other, and includes folding bellows (11) for that purpose. Furthermore it also includes a connecting element (15), which has either a cylindrical or a conical section (17,18,18?) and which connects an interior end of the folding bellows with the metal pipe.

Abstract: A solar heat collecting apparatus comprises a casing body, a lid for the casing body, a plurality of pillars, and a shield member. The lid for the casing body allows sunlight to pass through the lid and forms a vacuum space in collaboration with the casing body. A plurality of the pillars support the lid. The heat collecting panel is disposed so as to be apart from a side wall of the casing body in the vacuum space, and penetrated by a plurality of the pillars. The shield member blocks at least a part of clearance gaps from the heat collecting panel to the side wall and a plurality of the pillars.

Abstract: The present disclosure relates to an absorber element for solar high-temperature heat generation. The absorber element includes a light focusing unit, an outer tube composed of a translucent material and an absorber which is arranged in the absorber element. The absorber is surrounded by at least one reflector channel having an opening gap. A focal line of the light focusing unit lies on a center axis of the outer tube and the absorber does not lie on the center axis of the outer tube. The opening gap of the at least one reflector channel, through which the solar rays fall on the absorber, lies on the center axis of the outer tube, and hence on the focal line.

Abstract: A getter support assembly for supporting getters in a focusing collector type solar collector system comprising a tube radiation absorber (TRA) and a glass enclosure tube, defining therebetween an annular space, and a solar radiation focusing reflector. The getter support assembly comprises a bridge formed with an elongated trough having a getter support portion. The bridge further comprising feet fixedly attached to the TRA supporting the trough so that the trough is spaced apart from the TRA. The trough further comprises a radiation reflecting surface facing the TRA for blocking radiation emitted from the TRA and missed solar radiation reflected from the reflector.

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: A getter support assembly for supporting getters in a focusing collector type solar collector system comprising a tube radiation absorber (TRA) and a glass enclosure tube, defining therebetween an annular space, and a solar radiation focusing reflector. The getter support assembly comprises a bridge formed with an elongated trough having a getter support portion. The bridge further comprising feet fixedly attached to the TRA supporting the trough so that the trough is spaced apart from the TRA. The trough further comprises a radiation reflecting surface facing the TRA for blocking radiation emitted from the TRA and missed solar radiation reflected from the reflector.

Abstract: A solar system comprising a reflector and a heat collecting element (HCE) received at the focus of the reflector. The HCE comprises a coated tube received within a coaxial evacuated enveloping glass tube. The enveloping glass tube is secured at respective ends thereof to the coated tube by a coaxially deformable connector element having a distal end thereof sealingly secured to the coated tube and a proximal end thereof sealingly attached to a respective end of the enveloping glass tube by a glass to metal connection (GMC). A radiation shield assembly is provided over the connector element and over the GMC and is secured to the connector element by support legs engaging the connector element adjacent the proximal end.

Abstract: Cultivated field water is desalinated by a series of independent units that float on the water surface, taking up the saline water with a wick, evaporating the water from the wick in desalinating relation by concentrating incident solar radiation with a combination of a lenses and cooperating mirrors onto the upper end portion of the wick while the wick lower end portion is immersed in the field water, capturing the desalinated vapor resulting by condensing within the unit and returning the condensed, desalinated water to the field, and periodically renewing the wick by rinsing the salt from it at a cleaning station beyond the field.

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. The transparent portion, the conduit portion, and the absorbing portion together define at least one fluid passageway for conveying the fluid.

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. The transparent portion, the conduit portion, and the absorbing portion together define at least one fluid passageway for conveying the fluid.

Abstract: A heat gathering device 1 is provided with a reflection plate assembly 2 and a heat gathering tube 3 with a glass tube 4 surrounding the reflection plate assembly 2 and the heat gathering tube 3. The reflection plate assembly 2 is designed to provide a structure which is capable of maintaining the accuracy of a compound paraboloid in a heat gathering device having a compound paraboloid. The reflection plate assembly 2 is an assembly for gathering light having a compound paraboloid, which is formed by combining two paraboloids 21a and 21b. The reflection plate assembly 2 includes a reflection plate 21 and a plurality of brackets 22. The reflection plate 21 is formed by specularizing and forming a compound paraboloid surface through a bending process on a side where light is gathered. The brackets 22 are installed on the reflection plate 21 on an opposite side of the side where light is gathered.

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 solar concentrator for producing usable power as heat and/or electricity uses a self-steering heliostat 1502 to concentrate solar radiation 1509 onto an absorbing surface such as, or including, a solar cell array 1511 capable of absorbing power from the radiation, meanwhile removing heat (such as from long-wave infra-red radiation or resistive losses) from the surface with fluid heat transfer means 1503, 1504, then making effective use of that low-grade heat. Thus the solar cell array is kept relatively cool and a larger proportion of the solar energy incident on the reflector unit is used. The invention uses electricity 1506 from the solar cells to move a transporting fluid through a heat exchanger 1504. Excess electricity may be available for local storage or use 1510, or feeding 1512 to the power distribution grid. Applications include warming swimming pools 1501, heating hot-water supplies using excess electricity, or warming, lighting and ventilating open spaces.

Abstract: A nonimaging solar collector. A method and article of manufacture of a solar collector includes an outer housing transparent to light, a reflector element positioned asymmetrically within the outer housing, an absorber disposed within the outer housing, and a heat conduction fin coupled to the absorber and having a wedge shape which tapers to a smaller thickness as a function of increasing radial separation from the absorber. The heat conductor fin can be positioned at a variety of angular positions.

Abstract: A collector core (104) for a solar water-heating-system (100) includes a plurality of heat-absorbing pipes (108) each of which surrounds a cooler-water return-pipe (116). The heating-pipes (108) may connect directly to an insulated hot-water storage-tank (104) from which cooler water descends through the return-pipes (116) into the heating-pipes (108). Upon reaching the end of the return-pipes (116), the cooler water flows outward into the space between the surrounding heating-pipes (108) and the inner return-pipes (116). Upon warming, water between the two pipes (108, 116) rises upward back to the hot-water storage-tank (104) thus completing the thermosyphon flow cycle. Preferably, the inner return-pipe (116) is made of polyvinyl chloride ("PVC"), polybutelene ("PB"), or other compressible material which permits collector core (106) operation both in freezing and non-freezing environments.

Abstract: An apparatus (10) for utilizing solar energy includes an outer shell body (11), an inner body (40) inside it, and a hollow body (30) provided in between which are formed in a shape of a uniform polyhedron, in particular a dodecahedron. The shell body (11) and the hollow body (30) are provided with at least one opening (12, 13, 15) for the entrance of solar rays. The shell body (11) is therein disposed above a reflector pan (20) and has a partial polyhedron form, in particular in dodecahedral form. The solar energy concentrated in the shell body (11) is converted and conducted further to a consumer. With this cost-effectively produced apparatus (10) an improved efficiency relative to know apparatus is attained.

Abstract: A nonimaging solar collector. A method and article of manufacture of a solar collector includes an outer housing transparent to light, a reflector element position asymmetrically within the outer housing, an absorber disposed within the outer housing, and a heat conduction fin coupled to the absorber and having a wedge shape which tapers to a smaller thickness as a function of increasing radial separation from the absorber. The heat conductor fin can be positioned at a variety of angular positions.

Abstract: A nonimaging solar collector. A method and article of manufacture of a solar collector includes an outer housing transparent to light, a reflector element positioned asymmetrically within the outer housing, an absorber disposed within the outer housing, and a heat conduction fin coupled to the absorber and having a wedge shape which tapers to a smaller thickness as a function of increasing radial separation from the absorber. The heat conductor fin can be positioned at a variety of angular positions.

Abstract: In order to provide a trough-shaped collector for radiation, in particular for solar radiation, comprising a trough-shaped mirror extending in longitudinal direction and reflecting the radiation into a focus region, and an absorber line extending in longitudinal direction through the focus region of the trough-shaped mirror and having a guide tube for the heat transport medium and an absorber pipe surrounding the guide tube such that an annular chamber is formed between guide tube and absorber line, with which the problems existing as a result of the uneven irradiation of the absorber line are also reduced or eliminated, it is suggested that an annular passage medium flow in the annular chamber and that the annular passage medium couple the guide tube thermally to the absorber pipe.