Abstract: An apparatus (10) and method for the co-production of high temperature thermal energy and electrical energy from solar irradiance includes a photovoltaic cell (30) laminated to a metal extrusion device (40) and a transparent channel (20) in front of the photovoltaic cell (30). The transparent channel (20) contains a heat transfer fluid that is seeded with metallic, semiconducting, and/or non-metallic nanoparticles and absorbs wavelengths of solar energy that are not utilized or underutilized by the photovoltaic cell (30).

Abstract: A pumpless solar energy-based air heater includes a body housing a chamber surrounded by a heat conducting medium; an intake pipe to draw cool air into the chamber; and one or more exit pipes to push warm air out from the chamber, the one or more exit pipes having one or more structures within the interior of the one or more exit pipes to create a low friction factor for the air flowing upwards in the exit pipe while creating a high friction factor for the air attempting to move downward, thereby ensuring air flow in an upward direction; a pressure difference is created between an entry point of the intake pipe and an end point of the one or more exit pipes, thereby eliminating the need for a pump or a fan.

Abstract: A pipeline system in a linearly concentrating solar power station comprises at least one pipeline which is connected at one end to a converger and at a second end to a distributor. The converger and the distributor are arranged at a different geodetic height. When the converger lies on top pressurized gas can be fed into the converger and the distributor is connected to a drainage container. When the distributor lies on top pressurized gas can be fed into the distributor and the converger is connected to a drainage container. The drainage container is lower than the converter and the distributor.

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 modular liquid heating assembly includes a plurality of liquid delivery modules in series. The liquid delivery modules each include a module body having an inlet fitting, an outlet fitting, and a plurality of vessel coupling ports. The vessel coupling ports each include inflow and outflow orifices. The inlet and outlet fittings and the plurality of vessel coupling ports are in serial communication with each other through respective inflow and outflow orifices of the plurality of vessel coupling ports. At least one of the liquid delivery modules are configured for coupling with an inflow liquid line coupled with a liquid reservoir. Similarly at least one of the liquid delivery modules are configured for coupling with an outflow liquid line coupled with the liquid reservoir.

Abstract: A solar collector having two axis control and cogeneration capabilities is provided. The solar collector may have a primary collecting mirror, a second reflecting mirror, and a solar collector positioned adjacent to the primary mirror. The collector may realize both direct solar to electricity production via photovoltaic cells or the like, as well as heat collection generated by the collected solar energy. The collected heat may be transferred to a fluid which may be transferred for productive uses such as electricity production, heating, cooling, and the like.

Abstract: A solar collector includes a substrate having a top surface and a bottom surface opposite to the upper surface, a sidewall, a transparent cover, and a heat-absorbing layer. The sidewall is arranged on the periphery of the top surface of the substrate. The transparent cover is disposed on the sidewall opposite to the substrate to form a sealed chamber. The heat-absorbing layer is disposed on the upper surface of the substrate and includes a carbon nanotube film having a plurality of carbon nanotubes. The carbon nanotubes in the carbon nanotube film are joined end-to-end.

Abstract: The invention relates to a solar collector (1) comprising a collector element plane comprising a set of parallel metallic collector elements (2) for collecting solar energy. The collector element plane, on its side to be arranged to face the sun, comprises a set of parallel, elongated ridges (R, r) formed by the metallic collector elements (2), and elongated depressions (v) between the ridges (R, r), and that at least some of the ridges (R, r) comprise therein a channel (3) for a heat transfer medium. The invention also relates to a collector element. The invention further relates to a building roof, a building, and a solar energy recovery system comprising said solar collector (1).

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: The present invention relates to a heat exchanger configured to capture energy by radiation, comprising at least one flag-shaped basic exchanger (10), including: a) an input collector (5) and an output collector (6); b) a plurality of exchange tubes (1) connected to the input collector (5) and to the output collector (6), respectively, and stacked so as to halt the incident radiation, each tube (1) being provided in the form of a hairpin with one curved part at the head of the pin (4) and two arms (2, 3) adjoining essentially vertically and on the largest part of the length thereof, the end of the tubes (1) at the pin head (4) being free and the tubes (1) being self-supported at the ends thereof connected to said collectors (5, 6).

Abstract: A heat pipe comprises an evaporator section 5 having a radiation absorbing plate 6 a portion of an elongate tube 7, and a condenser section 10 at a distal end of the elongate tube 7 remote from the evaporator section 5. A flow control valve 20 is provided between the evaporator section 5 and the condenser section 10 to selectively interrupt communication between said sections when the temperature within the condenser section 10 exceeds a predetermined maximum. A temperature sensitive member, (coil of memory metal 34?, or discs 34?) acts between a support plate 26 and a seat 36 located on a valve pintle 30 to urge the valve head 22 towards the valve seat 24 when the temperature of the temperature sensitive member 34 exceeds a predetermined limit. A return spring 38 is provided to bias the valve head 22 away from the valve seat 24.

Abstract: A solar power tower solar receiver absorber including: an enclosure; at least one panel configured to be illuminated by solar flux; a core made of at least one material with heat conductivity at least partially encompassed by the enclosure; and a plurality of tubes passing through the core and extending substantially in a parallel direction with respect to the panel configured to be illuminated. The tube is configured for circulation of a fluid to be heated, for example a gas for operating a gas turbine.

Abstract: Methods and systems for solar water heating are provided herein. A modular pipe system for a solar water heater is provided in one embodiment. The system includes a plurality of first manifolds which are interchangeably connectable to any other first manifold. The system also includes a plurality of second manifolds which are interchangeably connectable to any other second manifold. The system further includes a plurality of pipe panels which are interchangeably connectable to any other panel, any first manifold, and any second manifold. Connecting the first manifolds and the second manifolds end to end expands the system along a first axis, and connecting a plurality of panels expands the system along a second axis perpendicular to the first axis.

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

Abstract: This invention relates to solar engineering. The solar collector, which comprises a closed enclosure and an absorber 5 with channels for a liquid heat carrier, is designed in the form of a cylindrical portion having radius R1 and an axis coinciding with the axis of the central cylindrical portion 1 of the enclosure. The absorber 5 consists of thin-walled, interconnected modules. The modules are provided with bulges on the rear side thereof, in which channels with slots are made for arranging pipes forming heat-carrier flowing channels. In addition, the absorber can be designed in the form of a storage tank. The shape of the collector is optimized in such a way that the axes of the two lateral cylindrical portions 2 thereof are remote at distance L and the central cylindrical portion 1 is as remote as possible from a plane 3 tangential to the lateral cylindrical portions 2 at a distance H having the defined ratio of geometric parameters.

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

Abstract: A boiler for a solar receiver includes a first boiler panel having a plurality of tubes fluidly connecting an inlet header of the first boiler panel to an outlet header of the first boiler panel. The tubes of the first boiler panel form a first solar receiver surface. A second boiler panel has a plurality of tubes fluidly connecting an inlet header of the second boiler panel to an outlet header of the second boiler panel. The tubes of the second boiler panel form a second solar receiver surface. The first and second boiler panels are adjacent to one another with a portion of the first boiler panel and an end of the first solar receiver surface overlapping an end of the second boiler panel to reduce solar radiation passing between the first and second solar receiver surfaces.

Abstract: A solar collector includes a substrate having a top surface and a bottom surface opposite to the upper surface, a sidewall, a transparent cover, and a heat-absorbing layer. The sidewall is arranged on the top surface of the substrate. The transparent cover is disposed on the sidewall opposite to the substrate to form a sealed chamber with the substrate together. The heat-absorbing layer is disposed on the upper surface of the substrate and includes a carbon nanotube film having a plurality of carbon nanotubes. The carbon nanotubes in the carbon nanotube film are entangled with each other.

Abstract: A solar collector includes a substrate having a top surface and a bottom surface opposite to the upper surface, a sidewall, a transparent cover, and a heat-absorbing layer. The sidewall is arranged on the top surface of the substrate. The transparent cover is disposed on the sidewall opposite to the substrate to form a sealed chamber with the substrate together. The heat-absorbing layer is disposed on the upper surface of the substrate and includes a carbon nanotube structure.

Abstract: A solar collector comprises a solar absorbing tube 3 containing elongate tube 11 that extends out of one end of the solar absorbing tube 3 and into an end fitting 15 wherein an annular outer passageway 13 of the elongate tube 11 communicates with a cold fluid inlet conduit 16 within the end fitting 15 and the inner passageway 14 of the elongate tube 11 communicates with a hot water outlet conduit 17 within the end fitting 15. Each end fitting 15 is provided with a receiving portion 22 extending orthogonally to the tubular passage 18 for receiving an end of the concentric elongated tube 11. The end fittings 15 are interconnected to provide fluid flow paths without the need for a manifold. Any number of solar collector tubes can be interconnected in this way. The invention also applies solar collectors of the heat pipe type.

Abstract: Methods and systems for solar water heating are provided herein. A modular pipe system for a solar water heater is provided in one embodiment. The system includes a plurality of first manifolds which are interchangeably connectable to any other first manifold. The system also includes a plurality of second manifolds which are interchangeably connectable to any other second manifold. The system further includes a plurality of pipe panels which are interchangeably connectable to any other panel, any first manifold, and any second manifold. Connecting the first manifolds and the second manifolds end to end expands the system along a first axis, and connecting a plurality of panels expands the system along a second axis perpendicular to the first axis.

Abstract: This invention relates to a solar panel, and in particular to a solar panel designed to absorb heat from solar radiation. The invention provides a solar panel adapted to fit between two sheets of glass in a glazing panel, the solar panel being adapted to absorb heat from a proportion of the incident light, and to permit another proportion of the incident light to be transmitted through the solar panel and the glazing panel. The invention also provides a glazing panel fitted with a solar panel.

Abstract: A solar collector includes a substrate having a top surface and a bottom surface opposite to the upper surface, a sidewall, a transparent cover, and a heat-absorbing layer. The sidewall is arranged on the periphery of the top surface of the substrate. Thea transparent cover is disposed on the sidewall opposite to the substrate to form a sealed chamber with the substrate together. The heat-absorbing layer is disposed on the upper surface of the substrate and includes a carbon nanotube film having a plurality of carbon nanotubes. The carbon nanotubes in the carbon nanotube film are aligned along a same direction or along different directions.

Abstract: The present disclosure relates to an energy supplying device intended to be used for energy collecting, energy transfer and energy release, but also for cooling and storing of energy, said energy supplying device (1) consists of at least three elongated profiles (3), which comprise a number of walls (2?, 2?) delimiting in the same elongated cavities (2), produced by extruding in a direction of extrusion (4) by aid of a tool, said cavities (2) provide space for a medium (5) such as gas or liquid to circulate or to be stored in said cavities (2) or a hose or a tube (9) located in these.

Abstract: A modular panel for a solar boiler includes an inlet header, an outlet header, and a plurality of tubes fluidly connecting the inlet header to the outlet header. The tubes are substantially coplanar with one another forming a solar receiver surface and an opposed internal surface. The panel is modular in terms of height, width, number of tubes, and size of tubes, for improved handling of high heat flux and resultant thermally induced stresses.

Abstract: A solar collector includes a first header, a second header and one or more riser tubes that connect the first header and second header. The solar collector is mounted to a surface, e.g., a roof, such that the headers are substantially parallel to a horizontal axis. The first header is curved so as to define a low point that facilitates drainage of liquid from the solar collector.

Abstract: A boiler for a solar receiver includes a plurality of boiler panels arranged side by side with each other so that the panels form a boiler wall section. Piping fluidly connects the plurality of boiler panels together to route a working fluid through the boiler wall section from an inlet of the boiler wall section to an outlet of the boiler wall section. The piping and boiler panels are configured and adapted to route the working fluid through each of the boiler panels in a common direction.

Abstract: A solar water heater includes a number of elongate water heating units which can be interconnected in series. The solar water heater can be installed vertically or inclined to have maximum solar exposure. Each water heating unit can utilize inner and outer glass tubes, which may or may not be a twin glass tube, to collect and conserve solar thermal energy inside. An inner metal water container extends through an opening in the inner and outer glass tubes. Heat transfer elements can be inserted between the inner tube and the metal water container. The solar water heater can work on natural convection and city water pressure.

Abstract: This invention provides a solar fluid heating assembly that generally increases efficiency by reflecting the sun's energy onto heat generating surfaces that face away from the sun. It also provides an aesthetic structure that is readily installed in a variety of outdoor settings and can be used as a boundary fence in certain applications. In an illustrative embodiment, the solar heater comprises one or more conduits and a reflective mechanism, such that in use, heat energy falls onto a front surface of the conduit, thereby heating water or another fluid within the conduit, and heat energy is reflected by the reflective mechanism onto another surface of the conduit, thereby further heating the fluid within the conduit.

Abstract: A boiler for a solar receiver includes a first boiler panel having a plurality of tubes fluidly connecting an inlet header of the first boiler panel to an outlet header of the first boiler panel. The tubes of the first boiler panel form a first solar receiver surface. A second boiler panel has a plurality of tubes fluidly connecting an inlet header of the second boiler panel to an outlet header of the second boiler panel. The tubes of the second boiler panel form a second solar receiver surface. The first and second boiler panels are adjacent to one another with a portion of the first boiler panel and an end of the first solar receiver surface overlapping an end of the second boiler panel to reduce solar radiation passing between the first and second solar receiver surfaces.

Abstract: A continuous moving bed solar steam generation and storage system is provided to generate steam for production processes after loss or reduction of received solar energy. The system includes a receiver 10 that receives a flowing stream of particulate material 30 that absorbs solar radiant energy 15 as it passes through beams of the energy 15 received from collectors 14. The heated stream of material 30 passes into a first chamber 40 to heat a tube bundle 42 therein. Heat from the particulate material 30 is transferred to the bundle 42, evaporating the water to generate, reheat (RH) and/or superheat (SH) steam 46. The cooled material 30 passes to a second chamber 60. The material 30 is drained from the second chamber 60 and carried to a cyclone 80 in the receiver 10. The material 30 drains from the cyclone 80 to complete the flow cycle.

Abstract: A solar collector includes a solar absorbing tube containing an elongate tube that extends out of one end of the solar absorbing tube and into an end fitting. An annular outer passageway of the elongate tube communicates with a cold fluid inlet conduit within the end fitting. An inner passageway of the elongate tube communicates with a hot water outlet conduit within the end fitting. Each end fitting 15 is provided with a receiving portion extending orthogonally to the tubular passage for receiving an end of the concentric elongated tube. The end fittings are interconnected to provide fluid flow paths without the need for a manifold. Any number of solar collector tubes can be interconnected in this way.

Abstract: A solar collector, includes a glass sheet provided with a fired metal frit; a metal frame or another glass sheet provided with a fired metal frit and a metal frame; a brazed seal between the metal frit or frits and the metal frame; an absorber and pipes in which a heat-transfer fluid circulates, the pipes being in contact with the absorber, and the absorber and the pipes being placed between the glass sheet and the metal frame or between the two glass sheets. The invention provides a solar collector which is compact and simple and improves solar radiation transmission.

Abstract: A liquid-heating system has a solar energy collector exposed to solar radiation, a geothermal heat exchanger buried in the ground at a depth between 0.5 m and 5 m, a heater through which a liquid to be heated passes, and a heat pump having a sink side connected to the heater and a source side connected to the geothermal heat exchanger or to the solar energy collector. A first controller or valve setup connected to the heat collector can in one position connect the solar energy collector to the water heater such that heat collected by the solar energy collector is applied to the water heater. In another position it can connect the solar energy collector to the geothermal heat exchanger such that heat collected by the solar energy collector is applied to the ground surrounding the geothermal heat exchanger.

Abstract: A vacuum solar thermal panel including a vacuum envelope defining a sealed volume and able to withstand atmospheric pressure when evacuated, at least one heat absorber being disposed inside the vacuum envelope, a pipe entering and exiting the envelope and being in contact with the heat absorber, the vacuum envelope including a first plate made of glass, a peripheral frame, a metallic peripheral belt being joined to the first plate by way of a vacuum tight bulk glass-metal seal, including glass material and obtained by fusion and subsequent solidification. The metallic peripheral belt includes at least one elastically deformable portion that prevents the bulk glass-metal seal from getting damaged and is no more vacuum tight when subject to the evacuation process of the envelope and the thermal treatments of the panel and the potential reciprocal displacements of the glass plate and the joined metallic peripheral belt.

Abstract: A solar receiver is provided. The solar receiver may include a receiver housing with front and rear ends. The solar receiver may also include a window configured to allow radiation to pass therethrough. The window may be mounted at the front end and project within the housing. The solar receiver may also include a receiver chamber defined between the housing and the window. The receiver chamber may include a working fluid inlet for ingress of working fluid to be heated therewithin, and a working fluid outlet for egress therethrough of the heated working fluid. The solar receiver may also include a solar radiation absorber configured for absorbing the radiation and heating the working fluid thereby. The absorber may be located within the receiver chamber and may surround at least a portion of the window. The solar radiation absorber may be formed with projections.

Abstract: Thermal solar energy collector, in which a solar radiation absorption panel, inside which the heat-conducting fluid flows, is situated inside a parallelepipedal box, with an opening having a transparent cover at the front, which may be doubled so as to leave an atmospheric space in the middle. The rear wall of the box has a system of seals and reservoirs which are inset in the wall so that they accommodate the expansion and contraction of vertical tubes of the panel and horizontal connections by means of gentle changes in curvature of the tube bends and slight rotations of the reservoirs, with the addition of a system for filling the box with an inert gas, the pressure of which may be chosen from a range of between a thousandth of an atmosphere and one atmosphere, there being provided for this purpose an external gas circuit, with low- and high-pressure tanks, an intermediate compressor.

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, a plurality of absorber tube functions, in the limit, effectively to simulate a flat plate absorber.

Abstract: This invention relates to solar engineering. The solar collector, which comprises a closed enclosure and an absorber 5 with channels for a liquid heat carrier, is designed in the form of a cylindrical portion having radius R1 and an axis coinciding with the axis of the central cylindrical portion 1 of the enclosure. The absorber 5 consists of thin-walled, interconnected modules. The modules are provided with bulges on the rear side thereof, in which channels with slots are made for arranging pipes forming heat-carrier flowing channels. In addition, the absorber can be designed in the form of a storage tank. The shape of the collector is optimized in such a way that the axes of the two lateral cylindrical portions 2 thereof are remote at distance L and the central cylindrical portion 1 is as remote as possible from a plane 3 tangential to the lateral cylindrical portions 2 at a distance H having the defined ratio of geometric parameters.

Abstract: The shower heated by solar energy comprises a platform (2), to a base (2a) of which is connected a piping (3) containing a water supply. A tubular body (4) is connected superiorly to the platform (2), bearing a shower head (5) at a top thereof. The platform (2) internally exhibits a plurality of conduits (7) for retaining water, which plurality of conduits (7) is exposed to solar rays.

Abstract: A high-efficiency solar radiation collection and conversion system is described. An array of evacuated collector tubes each includes two or more inner heat pipes that capture the solar energy and conduct it as heat through a condenser portion into a manifold that operates as part of a closed-loop circulation system. In another part of the loop, a heat exchanger transfers the heat into a hot-water holding tank or otherwise applies the heat energy in the circulating fluid.

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: In a flat panel solar collector adapted to be evacuable and vacuum-tight, at least one absorber is provided. At least one conduit is provided which is at least partially thermally associated with the at least one absorber. A holding structure is provided comprising a perimetric frame. At least one first transparent wall is provided, the first transparent wall and the holding structure having a overlapping area. At least one side of the first transparent wall comprises at least partially at said overlapping area a metal coating forming at least one metallized area on the transparent wall. A first soft metal ribbon is provided sealing the junction between the first transparent wall and the holding structure and which is soldered to the holding structure and to the metallized area of the first transparent wall.

Abstract: The invention relates to a flat solar collector comprising individual vacuum chambers. The invention is formed by two heads and a series of parallel tubes having high transmittance in the solar spectrum, which is disposed between said heads. The opposite side of the heads is provided with vacuum chambers which closure the connections of the conducting tubes. One of the vacuum chambers is characterized in that it is fitted with a vacuum valve at one end thereof. In addition, conducting tubes are disposed inside the aforementioned tubes having high transmittance in the solar spectrum and said conducting tubes are in turn connected to collector plates, all under vacuum conditions which minimize convection energy losses. When the conducting tubes are configured in series, the collector can raise the temperature of the working fluid to above 200° C. All of the above is performed in a novel, simple and economical manner.

Abstract: A solar thermal energy collector manifold is provided. The manifold is connected to solar collector tubes for collecting solar energy. A fluid is used to transfer the heat collected from the collector tubes. The manifold includes an inlet path for receiving the fluid, a fluid flow path for transferring the fluid to the solar collector tubes, and an outlet path for outputting the heated fluid. To facilitate the flow paths, the manifold includes a plate with depressions.

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: An optically efficient and thermally stable solar heating apparatus and method provide efficient heating by using a solar collector having a transparent tube containing a porous absorbent material or structure that permits liquid or aerosol to percolate through the transparent tube. Thermal protection against overheating is provided when the system is drained by a transparent top with a bottom surface that, when in contact with another liquid medium filling the collector, permits incident light to enter and be collected, but when the liquid medium that normally contacts the bottom surface of the top is absent when the system is drained, incident light is reflected. The collector, top and transparent tubes may be extruded and made from the same recyclable plastic material, making the assembly lightweight for installation and ease of structural integration, while facilitating recyclability of the entire collector.

Abstract: The invention provides receivers which can be used to heat a working fluid to high temperature. In preferred embodiments, concentrated solar radiation is received and converted to heat at varying depths in the receiver such that multiple layers of surface are used to heat the working fluid. In addition, the depth-loading configuration helps to trap received heat to reduce radiant thermal loss.

Abstract: A solar collector includes a substrate having a top surface and a bottom surface opposite to the upper surface, a sidewall, a transparent cover, and a heat-absorbing layer. The sidewall is arranged on the top surface of the substrate. A transparent cover is disposed on the sidewall opposite to the substrate to form a sealed chamber with the substrate together. The heat-absorbing layer is disposed on the upper surface of the substrate and includes a carbon nanotube composite material.

Abstract: A solar collector includes a substrate having a top surface and a bottom surface opposite to the upper surface, a sidewall, a transparent cover, and a heat-absorbing layer. The sidewall is arranged on the top surface of the substrate. The transparent cover is disposed on the sidewall opposite to the substrate to form a sealed chamber with the substrate together. The heat-absorbing layer is disposed on the upper surface of the substrate and includes a carbon nanotube film having a plurality of carbon nanotubes. The carbon nanotubes in the carbon nanotube film are entangled with each other.