Abstract: The invention relates to a solar collector. The collector has a heat regulating medium which defines a cavity therein. An aperture communicates with the cavity so as to allow solar energy incident on the aperture to enter the cavity. An energy collection device is disposed in the cavity and in thermal contact with the heat regulating medium to collect solar energy entering the cavity.

Abstract: The present invention discloses a compact solar concentrator module and array preferably with cooling and heat extraction system for converting solar energy to other energy forms preferably electric and thermal energies. The solar concentrator module comprises a vacant structure with a substantially reflective parabolic inside surface, as well as a focal device disposed within the vacant structure for receiving a solar energy converter or a solar cell preferably photovoltaic cell. the focal device being positioned proximate to the focal point of the reflective parabolic inside surface, and a transparent cover coupled to the vacant structure opposing to the reflective parabolic inside surface for transmitting sunlight therein.

Abstract: Solar trough apparatuses are disclosed, where a heat transfer fluid conduit remains fixed in a focal of a solar trough as the solar trough tracks the sun. The support structures can be ring or arcuate structures, where rotation is about their central axis and the trough is support in them so that the focal zone is coincident with the axis of rotation and the conduit is situated in the focal zone eliminating the need for articulated or flexible conduit.

Abstract: A solar collector is provided with a reflective panel assembly that is supported by a frame and pivots about a first horizontal axis. The panel assembly is configured for reflecting sunlight to a common focal point, and includes a central panel and a pair of outer panels each pivotally coupled to the central panel and configured for folding over the central panel. A collector assembly is mounted relative to the frame and pivotal about a second horizontal axis. The collector assembly is configured for collecting solar energy and includes a receiver that is positioned at the focal point. The receiver is configured for extracting energy from the reflected sunlight. The solar collector may also include a four-bar linkage assembly for supporting the panel assembly and the collector assembly during movement from a collapsed position and a partially extended position.

Abstract: A solar receiver is provided, comprising a receiver housing extending along a longitudinal axis, having front and rear ends; a window configured to allow radiation to pass therethrough, the window being mounted at the front end and projecting within the housing; a receiver chamber defined between the housing and the window, the receiver chamber having 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; and a solar radiation absorber configured for absorbing the radiation and heating the working fluid thereby, the absorber being located within the receiver chamber and surrounding at least a portion of the window, the solar radiation absorber being formed with channels and made of a foam material, such as a ceramic or metallic foam material, having a characteristic average pore diameter.

Abstract: The present invention relates to a device for collecting and utilizing energy generated by the sun, comprising a layered construction provided with a substrate layer and a cover layer comprising a curable mortar, wherein there is arranged on the substrate layer a tube system through which a fluid can be transported in order to regulate the temperature in the tube system, this tube system being at least partially embedded in the mortar, and wherein the mortar of the cover layer comprises insulating granules, cement, water and additives. The invention further relates to a method for manufacturing a layered construction for a device for collecting and utilizing energy generated by the sun.

Abstract: An air heating system is for use with a mechanism for flowing air. The system includes a plenum and a solar absorber. The solar absorber defines a first boundary of the plenum. The solar absorber is permeable to air. The mechanism for flowing air is for pulling air into the plenum through the permeable solar absorber. The plenum has an axial direction, wherein along a cross section of said plenum normal to the axial direction the permeable absorber has an average shape that is substantially convex when the permeable absorber is viewed from outside of the plenum.

Abstract: A solar collector panel which can also be utilized to display information and/or images and/or messages and having an external frame, with a transparent upper panel securely positioned within the frame. A lower panel is positioned within the frame and spaced in relation to the upper panel so as to provide a closed chamber between the upper panel and the lower panel, an upper surface of the lower panel having applied thereon heat conversion means for converting solar radiation to heat energy, the heat conversion means providing thereon information, an image or message which is visible above the upper surface of the upper panel. A back panel is positioned within the frame, so as to define a closed volume of air space between the lower panel and the back panel through which air may flow. Intake and exhaust pipes introduce air into the frame, and transfer heated air from the frame.

Abstract: A solar component for solar thermal installations has an absorber element and at least one tube for a fluid thermal medium, coupled thermally directly or indirectly to the absorber element. At least one solid insulation of foam glass or plastic, in particular a cured plastic foam made of polyurethane or polyisocyanurate, is provided. The solid insulation, when mounted as intended, fixes the at least one tube relative to the absorber element.

Abstract: A solar energy collector panel intended for invisible incorporation behind and in thermal contact with a climate shield (94) of bituminous roofing felt or tar board on a building, said panel being made of a heat-conducting material and having at least one through- going fluid-impervious duct (91) embedded in said panel for passing a thermal energy carrying-capable fluid through it and having or being attached to a flat member (93) of heat-conducting material and substantial surface area intended to be mounted in direct physical contact with said climate shield. The solar panel provides excellent exploitation and transmission efficiency of sun radiation to an energy carrying-capable fluid in the fluid-impervious duct.

Abstract: A system and method of collecting solar energy from sunlight, employing a thermal generation apparatus having a solar collector module including a receiver in optical communication with an array of mirrors. The method comprises reflecting energy impinging upon the reflector assembly with a plurality of reflective elements. The plurality of reflective elements is configured to direct energy reflected therefrom onto the receiver. The solar collector module is configured to rotate about an axis; and an angular position of the plurality of reflective elements is changed in relation to relative movement of the sun with respect to earth.

Abstract: Examples and variations of apparatus and methods for concentrating solar radiations with trough solar energy collectors are disclosed. A support assembly for a trough solar energy collector has a plurality of transverse ribs attached to longitudinal rails and end assemblies secured to the rails. End assemblies may attach to longitudinal rails through transverse ribs, and guy wires may span from one of the end sections to the other. Transverse ribs may be formed of two rib sections with semi-parabolic shape. Solar energy collecting panels may be placed on the ribs and secured with cowlings and transverse panel-retaining strips, for instance.

Abstract: The radiation selective absorber coating of the invention includes two or more barrier layers arranged over each other on a substrate surface, an infrared-range reflective layer arranged on the two or more barrier layers, and at least an absorption layer arranged over the infrared-range reflective layer and a final antireflection layer arranged over the absorption layer. The absorber pipe, especially for a parabolic trough collector, is a steel pipe, on whose outer side the radiation selective absorber coating is applied. In the method of making the absorber pipe a first oxide barrier layer is provided on the outer side of the steel pipe by thermal oxidation, and then a second barrier layer, an infrared-range reflective layer, an absorption layer and a final antireflection layer are applied by gas-phase physical deposition.

Abstract: The present invention proposes a hybrid methodology and apparatus between photovoltaic (PV) and concentrated photovoltaic (CPV) solar panels to lower the photovoltaic solar energy production cost. In particular, the disclosed methodology addresses a simple quasi-parabolic trough PV (QPTPV) low concentration system with greater tolerance to tracker pointing errors. The quasi-parabolic trough (QPT) reflector is defocused to cover the width of a linear solar cells array, which is reduced from a large rectangular solar cells panel. In summary, the QPTPV system consists of low cost quasi-parabolic reflectors, a compact linear PV cells array and a lower cost relaxed pointing 2-axes tracker. The combination of these low cost technologies disclosed can achieve the lowest cost per kilowatt hour of photovoltaic energy production.

Abstract: A system for concentrating solar energy comprising a collector consisting of a number of reflective panels, a receiver which absorbs reflected energy, a working fluid which absorbs the energy, a highly transmissive cover and internal colorings or coatings to collect indirect radiation, and a solar tracking system to maintain reflector orientation. Optional photo-voltaic panels could also be used for providing electrical energy and are kept at near ambient temperatures. Under normal conditions, solar energy is concentrated by reflectors on the receiver, which transfers the energy to a working fluid which is then used for either hot water heating, desiccant drying for a solar air conditioner, or as a power source. Additional energy is collected from indirect sources using the greenhouse effect.

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: 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: An symmetric solar collector system is disclosed which comprises one or more reflectors in the shape of an asymmetrical vertically-biased parabolic trough, which allows for the reflectors to be stacked vertically, and have a zero footprint. The reflectors each include a reinforced absorber comprising two or more tubes attached to each other in truss-like fashion, with a sag to length ratio of less than about 1/500. In addition, although the vertically-biased trough shape lessens the amount of surface area available for water or ice to accumulate, the reflector surface is partially coated with a material that is highly absorptive of solar wavelengths, and thus, heats any accumulated water/ice to the point of evaporation.

Abstract: A solar air conditioning device (100) includes a solar collector assembly (30), an inlet assembly (10) at an entrance of the solar collector assembly, and an outlet assembly (50) at an exit of the solar collector assembly. The solar collector assembly includes a heat-absorbing set (31) and a transparent panel (38) being assembled to a top of the heat-absorbing set. The heat-absorbing set comprises a plurality of heat-absorbing units (32) engaged with each other. Each of the heat-absorbing units includes two adjacent supporting members (33) and a heat-absorbing plate (35) sandwiched between and buckled with the two supporting members. The heat-absorbing set defines an air channel (314) with the transparent panel and a heat-absorbing channel (315) below the air channel. The inlet and outlet assemblies are in fluidic communication with the heat-absorbing channel.

Abstract: A solar energy conversion system may include a receiver with a first heat transfer fluid channel having at least two opposite sides. Each side may present an external surface facing in a direction opposite to that of the external surface of the other opposite side. Each side may be configured to contact a heat transfer fluid carried in the first heat transfer fluid channel. A heliostat field may be configured to direct solar energy to each of the at least two opposite sides during the course of a day such that a thermal stress tending to bend the channel remains below a specified level.

Abstract: The absorber pipe for solar thermal applications consists of a metal pipe and a radiation-selective absorber coating applied to the outer surface of the metal pipe. The radiation-selective absorber coating consists of, in sequence from the outer surface toward an exterior: a diffusion barrier layer, a metallic reflective layer a cermet layer, and an anti-reflective layer. The diffusion barrier layer is an oxide layer on the outer surface of the preferably steel or stainless steel pipe which is formed by an oxidation process during tempering and which includes oxidized components of the metal pipe. The tempering is preferably performed in air in an oven at a temperature of 400 to 600° C. for 0.5 to 2 hours.

Abstract: It includes at least one module with a concave reflecting mirror surface which concentrates the light radiation towards certain devices in order to then obtain electrical or other type of energy. It also includes means for orienting that mirror surface according to the position of the sun. It is characterised in principle in that each module comprises a thin lightweight laminar body with an arched structure which incorporates the concave mirror surface, this laminar body being associated with certain stiffening supports which stabilise and stiffen that arched structure in order to maintain this shape, said structure being supported on some ground with the interposition of guide means by which the arched structure at least tilts towards one side or the other depending on the light sensor or timer which activates a device that positions each module in real time with the required orientation according to the position of the sun.

Abstract: A device (1, 20, 40) for collecting solar energy includes collector elements (3) and lens elements (2) for concentrating solar radiation onto the collector elements (3). The collector elements (3) are coupled via a conduit for energy transport to an energy processing unit. The lens elements (2) include at least one lens (2) which is arranged movably. Drive elements are provided to orient the at least one lens (2) about at least one orientation axis. The drive elements are provided with a control for the purpose of orienting the at least one lens (2) in at least substantially continuous and in at least substantially optimal manner relative to an actual position of the sun.

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 receiver is disclosed and includes a housing having a front, radiation-facing, end and a rear end, the front end being formed with a cavity therein. A window is mounted at the front end of the housing and projects inside the cavity. A receiver chamber is defined within the cavity between the housing and the window. The receiver chamber has a working fluid inlet for ingress of working fluid to be heated therewithin, and a working fluid outlet for egress therethrough of the heated fluid. A solar absorber is within the receiver chamber for absorbing the solar radiation and heating the working fluid. The solar absorber includes at least one tubular member configured for maintaining fluid isolation between contents thereof and contents of the receiver chamber. The solar absorber is configured for heating working fluid within the receiver chamber exterior to the tubular member, and working fluid within the tubular member.

Abstract: A solar heat collection system for heating water, the system comprising in one embodiment a plurality of lengths of water conduit pipe inside lengths of water conduit jacket pipe and spaced apart therefrom, with an insulating medium contained between the pipe and jacket pipe. The lengths of water conduit pipe are fluidly connected together to provide a circulation system for the water such that solar heat energy may be provided to a heat load. A variety of connection methods for connecting the lengths of piping are provided and the lengths of piping may be flexible for a variety of solar heat system installations.

Abstract: Solar electricity generation methods and apparatus are disclosed. In one general aspect, a solar cell is positioned to receive concentrated solar radiation and convert part of it into electricity and part of it into heat. A first heat exchanger is thermally coupled to the solar cell and includes microchannels that have a cross-sectional dimension to the center of the channel that is about equal to or less than the thermal boundary layer thickness for a working fluid. The heat exchanger transfers heat from the photovoltaic solar cell to the working fluid in the microchannels, and a second heat exchanger can then receive the transferred heat via a conduit. This heat can be used to generate additional electricity.

Abstract: A solar furnace includes an outer insulation chamber and an inner reaction chamber disposed inside the outer insulation chamber. The outer insulation chamber has an outer solar window which is in alignment with an inner solar window of the inner reaction chamber. The outer insulation chamber includes a multi-layered air-circulating tunnel. Each layer of the air-circulating tunnel has a solar window to form a multi-solar window opening. Within each solar window opening, there is a hot air curtain or hot flame curtain to cover the opening. When the concentrated solar beams pass through each solar window opening, photon beam reacts with the hot air curtain or hot flame curtain, and will further increase the temperature of hot air particles in the multi-layered air-circulating tunnel. An oil boiler is thermally connected to the inner reaction chamber. The oil boiler includes incoming and outgoing pipes disposed in a middle air-circulating tunnel to absorb the heat energy from the hot air curtain.

Abstract: An absorber tube is provided that includes an inner tube and an outer tube that at least partially surrounds the inner tube and is concentric with the inner tube. An expansion element is present and is configured for expanding in response to differences in thermal expansion between the inner tube and the outer tube. A getter is located radially at a position between the inner tube and the outer tube.

Abstract: The present invention relates to A roof-covering element (10), with an upper surface (11) and a lower surface (12), whereby for roof covering a plurality of elements (10) is juxtaposed in a particular way such that neighbouring elements (10) are interconnected by means of an interlocking arrangement (13, 14, 15), and whereby the roof-covering element (10) comprises means for exchanging heat with the environment, where at least one of the surfaces (11, 12) of the element (10) is at least partially made of a metal alloy. The particular roof-covering element (10) can in particular be made of an alloy comprising any combination of copper (Cu), zinc (Zn), manganese (Mn) and iron (Fe), i.e. the alloy CuZn40Mn2Fe1. The roof-covering element (10) according to the present invention can also comprise a cavity (16), provided inside the element (10), in which a fluid is circulable for heat exchange with the environment.

Abstract: The invention relates to an absorber (10), which can be used to produce heat by means of solar heating, the absorber comprising an upper metal sheet (12) facing the sun and a lower metal sheet (14) facing away from the sun, between which sheets conducting means (18, 54) are provided for the substantially linear and/or homogeneous conduction of a fluid from an inlet (20) to an outlet (24). The inlet (20) and/or the outlet (24) and/or the conducting means (18, 54) are formed by the upper metal sheet (12) and/or the lower metal sheet (14), wherein the inlet (20) and/or the outlet (24) and/or the conducting means (18, 54) can be produced by deep-drawing, thereby resulting in a particularly simple and cost-effective production of the absorber (10).

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 direct accumulation tank, defining a closed volume (2), comprising an inlet (3) for filling the tank with a fluid, and an outlet (4) for emptying the tank of the fluid, and exhibiting an upper surface (Ia) exposed to solar rays. The upper surface (Ia) exhibits a plurality of reliefs (5, . . . 5n) for defining a greater surface extension exposed to the solar rays.

Abstract: A solar air conditioning device (100) comprises a solar collector assembly (30), an inlet assembly (10) at an entrance of the solar collector assembly, and an outlet assembly (50) at an exit of the solar collector assembly. The solar collector assembly includes a heat-absorbing set (31) and a transparent panel (38) being assembled to a top of the heat-absorbing set. The heat-absorbing set comprises a plurality of heat-absorbing units (32) engaged with each other. A distance between the inlet assembly and the outlet assembly is equal to a longitudinal length of single heat-absorbing unit. The heat-absorbing set defines an air channel with the transparent panel and a heat-absorbing channel below the air channel. The inlet and outlet assemblies are in fluidic communication with the heat-absorbing channel.

Abstract: A solar collector including a plurality of hollow tubes, each tube directly joined, or indirectly joined by a web, to an adjacent tube; a first manifold connected to a first end of each tube; a second manifold connected to a second end of each tube; where at least two adjacent tubes are separated along a portion of their length so as to form a first section in which adjacent tubes are separated from one another and a second segment in which adjacent tubes are joined to one another. Also disclosed is a method for preventing damage to a tube mat solar collector which includes maintaining the hollow tubes of a solar collector in a substantially coplanar relationship in the absence of high wind conditions; permitting individual tubes to move about their longitudinal axis in response to high wind conditions; and returning the tubes to their longitudinal axis as the high wind conditions subside, the high wind conditions being wind of at least 15 miles per hour.

Abstract: A solar panel (10) has tubing (12) through which water from a swimming pool is recirculated. The tubing (12) is adapted to be exposed to the sun for heating the water to a temperature whereby the pool is heated. The solar panel (10) has a housing (14) for the tubing (12), and the housing (14) has a transparent screen (16) covering the tubing (12). In use, the housing (14) retains heat therewithin for increasing the temperature of the tubing (12) above that outside of the housing.

Abstract: The invention relates to a thin wall header with a variable cross-section for solar absorption panels, manufactured in nickel-based superalloy and formed by a main thin wall body (18) and by a plurality of nozzles (16,21). The header (10) is connected to a series of junction nozzles (16) wherein respective solar absorption tubes (14) are connected, and at least one inlet or outlet nozzle (21) wherein at least a fed tube is connected. The body (18) can have a spindle shape or can be formed by two frustoconical sections joined by the larger base, and can further have a central cylindrical section at the height of the inlet or outlet nozzles (21). It is applicable in the collection of fluids at high temperature, especially in solar panels.

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 tubular radiation absorbing device (1) designed for a solar heating application is described. The tubular radiation absorbing device has a metal central tube (3) and a glass tubular jacket (2) surrounding the central tube (3). A folding bellows (11) is connected between the central tube (3) and the tubular jacket (2), so that the tubular jacket and the central tube are movable relative to each other. A connecting element (20) connects an inner end of the folding bellows (11) with the central tube (3) and extends from the inner end of the folding bellows (11) through an inner annular space (30) between the folding bellows (11) and the central tube (3). The connecting element includes at least a part of a hydrogen window (50). A getter (6) is arranged in an outer annular space (33) between the folding bellows (11) and the tubular jacket (2).

Abstract: The system contains a plurality of elongated conduit. A height dimension of the elongated conduit is substantially less than a width dimension of the elongated conduit. A plurality of connecting elements is connected between the elongated conduits establishing a fluid path through the elongated conduit. A fluid is captured within the elongated conduit.

Abstract: Disclosed is a solar heater with a primary circuit course in a panel for heating two separate inter connected storage reservoirs.

Abstract: Apparatus for collection of solar energy includes at least one heat-transfer collector device comprising (i) a hollow core, adapted for passage of heat transfer fluid, and (ii) a preferably detachable laminar metallic cover configured to wrap around the and be in close physical contact with at least part of an outer surface of the core, while the outer surface of the cover is adapted for exposure to solar radiation by the presence of a solar energy absorptive coating.

Abstract: A solar thermal energy collector includes a receptacle and a tube. The tube is adapted to fit within the receptacle and defines a first region within the tube and a second region between the tube and an internal surface of the receptacle. A fluid is circulated between the first region and the second region for transferring of the solar thermal energy.

Abstract: This invention provides novel devices and methods for the heating of air with solar radiant energy. The devices of the present invention feature a housing partitioned into essentially isolated sections wherein the sections are in fluid communication with each other through a plurality of channels located within the partitions. The two unique features of the invention, essentially isolated sections and partitions comprising a plurality of channels, increase the temperature achieved by the solar heater by 1) creating multiple, sequential sections that function independently of each other providing a higher starting temperature in each section and, therefore, a higher final temperature, 2) providing second means of heating the air within the channels located within the partitions and, 3) by virtually eliminating the mixing of incoming cold air with the heated air of the solar air heater.

Abstract: A solar heat collector includes a trough extending along the ground. The solar heat collector further includes a first region within the trough. The first region extends along a length of the trough. The first region is configured to absorb solar radiation and to heat a fluid flowing within the first region with thermal energy resulting from the absorbed solar radiation. The solar heat collector further includes a second region between the first region and the ground. The second region is substantially thermally insulating the first region from the ground.

Abstract: An absorber (1) is made available for a thermal solar collector comprising an absorber sheet (3) and at least one thermal fluid tube (5) that is connected in a thermally conducting fashion to the absorber sheet (3), has at least one bent section (2), and is connected to the absorber sheet (3) outside the bent section (2) via a continuous welded joint. The continuous welded joint (7, 8) is also present in the bent section (2) of the thermal fluid tube (5).

Abstract: A solar collector panel which can also be utilized to display information and/or images and/or messages and having an external frame, with a transparent upper panel securely positioned within the frame. A lower panel is positioned within the frame and spaced in relation to the upper panel so as to provide a closed chamber between the upper panel and the lower panel, an upper surface of the lower panel having applied thereon heat conversion means for converting solar radiation to heat energy, the heat conversion means providing thereon information, an image or message which is visible above the upper surface of the upper panel. A back panel is positioned within the frame, so as to define a closed volume of air space between the lower panel and the back panel through which air may flow. Intake and exhaust pipes introduce air into the frame, and transfer heated air from the frame.

Abstract: A solar concentrating collector includes corrugated board parabolic support segments with flexible strips and side tabs over the cut edge to support a laminate with reflective coated film. The reflector assembly has supporting arms and pivots about a heat absorbing conduit secured to vertical extensions of adjacent stationary posts. Selected external surfaces are weatherproofed. The conduit includes vacuum insulators and means to isolate conduit from insulator expansion. Upper arms support pulleys and cable take-ups for continuous collector position changes. Cross members of the extended post secure the fixed conduit, and at a higher level, a programmable drive to rotate two cable capstans for cables that pivot two adjacent reflector assemblies. Other embodiments include triangular or square fluid conduits with planar surfaces for photovoltaic cells and a modified reflective surface to disperse solar rays into a band of reflected sunlight directed to photocell areas.

Abstract: A solar collector plate (2) has a solar radiation receiving front absorber plane (3) that is wiped at its rear side by a cooling liquid (4) flowing in channels (5). Cavities (7), preferably behind the channels (5) and integrated in the solar collector plate (2), and that can be closed off by the very liquid flow (4), provide a closed air volume that gives a dampening effect regarding kickbacks and pressure transients in the liquid (4).

Abstract: Volumetric solar receivers are disclosed. An illustrated volumetric solar receiver includes a heat absorbing cavity (1), a glass window, and a working fluid inlet pipe (2) and an outlet pipe (3) connecting with the heat absorbing cavity (1). The glass window comprises a double-layer hollow glass (41 and 42). The hollow portion of the glass window forms the inner cavity (43). This inner cavity (43) is provided with an outlet (44) connected to the heat absorbing cavity (1). The working fluid inlet pipe (2) is connected with this inner cavity (43) and further with the heat absorbing cavity (1) via the outlet (44) of this inner cavity. This arrangement keeps the temperature at the glass window low and prevents local overheating, and also avoids waste of heat carried away by the cooling fluid from the glass window.