Abstract: According to various aspects, exemplary embodiments are disclosed of solar thermal collectors, solar heating systems, and thin plate heat exchangers and absorbers. The thin plate heat exchangers and absorbers may be used for solar applications and/or non-solar applications. In an exemplary embodiment, a solar thermal collector generally includes a first layer comprising polymer and configured to allow sunlight to pass therethough. A second layer comprises polymer and is configured to absorb thermal energy from sunlight. The second layer includes edges heat sealed to edges of the first layer. A permeable core is disposed between the first and second layers. In operation, a heat transfer fluid may flow through the permeable core and directly contact the second layer, whereby thermal energy is transferrable from the permeable core and the second layer to the heat transfer fluid.

Abstract: An apparatus for producing superheated steam with solar energy is provided. The apparatus has a heat-transfer medium circuit with a heat transfer medium for absorbing the solar energy in the form of heat and a water/stream circuit with water and/or steam for forming the superheated steam. The water and/or the steam may flow in one direction in the water/steam circuit. For producing the superheated steam, the heat-transfer medium circuit and the water-steam circuit are thermally coupled to each other by a heat exchanger of a reheater. In the water/steam circuit, a water separator is arranged upstream of the heat exchanger in direction of flow for separating water and steam from each other, so that substantially only steam enters the heat exchanger. The heat exchanger and the water separator are arranged in a common reheating pressure vessel.

Abstract: The invention provides a solar power system for use as a solar roofing concept based on an absorber system with a solar thermal absorber and a circulation system for circulating absorber liquid through the absorber and a core system which extracts energy from the absorber liquid and provides hot water to a building. An intelligent controller uses data about external conditions to control the core system, where both current conditions and predicted conditions are taken into account. In preferred embodiments, the system can generate heat, hot water and electric energy to cover the need for a normal household. When excess heat is generated, the thermal energy can be used by an organic Rankine cycle (ORC) machine for electricity production. A forecasting and control unit using external weather measurements in combination with internet weather forecasts will by fuzzy logic calculate the optimum periods of time for use of the heat pump during the colder periods.

Abstract: A solar receiver is disclosed. The solar receiver is modular, has multiple tube panels in a rectangular/square/polygonal/circular configuration, and is designed for use with molten salt or another heat transfer fluid. The heat transfer fluid flows in a vertical serpentine path through the sides (facets) of the solar receiver. The solar receiver can be shop assembled and can be used with a support tower to form a solar power system.

Abstract: The field of invention relates generally to roof systems and particularly to sloped roofs, which can incorporate a ridge vent to exhaust hot attic gases. More particularly, the invention serves not only as an improved roof venting system but also acts as a solar water heater. The invention uses a novel method of utilizing hot escaping gasses from the attic space to heat water from below in its integrated solar collector as well as utilizing a system of baffles to exclude precipitation while also incorporating a clear panel to heat water from the sun's rays while venting hot gases from the attic space below.

Abstract: A solar water heating and cooling system including a solar energy collection assembly having a heat absorbing element, a heat exchanger and a shield. The system also includes a cooling assembly, the cooling assembly is integral with the shield. The system has a check valve in fluid communication with the solar collection assembly and the cooling assembly, and a fluid pump in fluid communication with the solar energy collection assembly. A working fluid is disposed within the solar energy collection assembly, the cooling assembly, the check valve and the fluid pump. A cooling loop is defined by the solar energy collection assembly, the cooling assembly and the check valve. When the fluid pump is off, the working fluid circulates through the cooling loop, but when the fluid pump is on, the working fluid circulates through a heating loop that is defined by the solar energy collection assembly and the fluid pump.

Abstract: A unit for harnessing solar power for heating water at high pressure, in which the circuit is exposed to freezing, comprising: a heat exchanger made as a single piece for a hydraulic circuit, made up of parallel polymer pipes (1) connected at one end thereof to a main branch-off pipe (2, 3) and, at the other end thereof, to a main collector pipe (2, 3); a sealed box (4) for a whole number of units connected in series, having a profile of regular section (5), reinforced by brackets that can be inserted in In corners, with a translucent face (6), the other face having an insulated cover (7); the profile having a geometry suitable for connecting the box to a support structure; the profile having a geometry suitable for holding the insulating material (8) and the rubber seals on the inner part of the translucent face (9); the profile being such that complementary profiles (10) may be assembled thereon, by snap-fitting, and the complementary profiles have a housing for rubber seals (11) on the outer part of the tr

Abstract: Systems and methods for operating environmental equipment using heat absorbed by manufactured surface coverings from incident solar radiation where fluid in conduits carried in the manufactured surface covering is heated and supplied to a heat exchanger to provide heat for various environmental equipment such as a hot water supply, a turbine-driven electrical generator, a chiller, a water purification system, and/or a distillation system. Efficiencies are maximized by use of thermally conducted aggregates in the manufactured surface covering.

Abstract: The invention, in some embodiments, relates to solar energy collectors, and methods of use thereof. In some embodiments, the invention relates to liquid-air transpired solar energy collectors, and methods of use thereof. In some embodiments, the invention relates to thermal energy transfer systems that comprise solar energy collectors, and methods of use thereof. In some embodiments of the invention, methods of constructing solar energy collectors are provided.

Abstract: A solar power system includes a steam turbine with a plurality of pressure stages, a first solar field for heating water or water steam, and a first heat exchanger. The first heat exchanger is operated with molten salt liquids. Further, with a method of operating such a solar power system, water steam from the first solar field is transferred to the first heat exchanger, where the water steam is heated by the first heat exchanger and routed to a high pressure stage of the steam turbine.

Abstract: A hybrid solar/non-solar thermal generation system includes a solar concentrator and collector, and fiber optic cables that transfer collected solar radiation to a solar to thermal converter. The solar to thermal converter converts the solar radiation to heat that is used to augment the heating of a working fluid in a boiler. The system has particular application for use in Rankine cycle power generation plants that employ non-solar sources to heat the working fluid.

Abstract: Apparatus and methods related to solar energy are provided. A modular solar panel includes heat pipes to transfer heat away from photovoltaic cells. The solar panel is supported on a tracking mechanism and the heat pipes are coupled in thermal communication with heat exchangers. The solar panel is positioned by the tracking mechanism to follow the sun across the sky. Heat is transferred from the photovoltaic cells to the heat pipes and in turn to the heat exchangers, and is ultimately rejected from the system.

Abstract: Systems, methods, and apparatus by which solar energy may be collected to provide heat, electricity, or a combination of heat and electricity are disclosed herein.

Abstract: A solar collector/heat exchanger includes a first panel of corrugated heat conductive material, a second panel of corrugated heat conductive material, and a third panel of corrugated material. A mounting structure mounts the first and second panels with the third panel sandwiched between the first and second panels. The mounting structure further defines an air flow path across the first and second panels. The corrugations of the first and second panels extend parallel to the air flow path and the corrugations of the third panel extend perpendicular to the air flow path so as to cause turbulence in air passing between the first and second panels.

Abstract: A solar energy collection system includes a primary solar receiver and a secondary solar receiver. The secondary solar receiver generates steam using energy from solar radiation incident thereon. The primary solar receiver receives the generated steam from the secondary solar receiver and superheats the steam using energy from solar radiation incident thereon. A plurality of heliostat-mounted mirrors reflects incident solar radiation onto one of the primary and secondary solar receivers. A controller aims a portion of the heliostat-mounted mirrors at the primary solar receiver such that a predetermined thermal profile is provided on a surface of the primary solar receiver.

Abstract: A solar water-heating apparatus comprises an outer container sized and configured to receive a smaller inner container. The inner container includes an opening formed in an upright wall and an opening formed in a floor. A gap is located between the two containers. Once the device has been filled with a liquid, the liquid present within the gap may be heated by solar energy. The device may include a valve to prevent unintended flow of the liquid.

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: A solar energy collection system includes a primary solar receiver and a secondary solar receiver. The secondary solar receiver generates steam using energy from solar radiation incident thereon. The primary solar receiver receives the generated steam from the secondary solar receiver and superheats the steam using energy from solar radiation incident thereon. A plurality of heliostat-mounted mirrors reflects incident solar radiation onto one of the primary and secondary solar receivers. A controller aims a portion of the heliostat-mounted mirrors at the primary solar receiver such that a predetermined thermal profile is provided on a surface of the primary solar receiver.

Abstract: Solar energy concentrating apparatus having an array of lenses to receive and concentrate the solar radiation towards a plurality of stationary targets. The lenses are supported on a moveable structure to enable the lenses to move laterally in the east-west and north-south directions. Each lens of the array is also configured to rotate about an axis extending in the north-south direction. Drive means is coupled to a plurality of lateral and rotational movements mechanisms to orientate the lenses towards the target as the sun moves throughout the day and year.

Abstract: Insulated solar panels provide that provide a solar thermal collector with means for limiting stagnation temperatures and preventing damage include: temperature limiting is provided by the insulated solar panel, isolating internal components from the environment, using passive closed systems within the sealed solar thermal collector, while also allowing alternative implementations as active systems and/or portions of the temperature limiting system outside the sealed solar thermal collector. A heat pipe can be used as a passive thermal switch, where the temperature induced action at a predetermined temperature causes an abrupt transition from a state of thermal isolation to a state of strong thermal coupling. Additionally, a set of siphon circulation pipes provides a passive closed system for temperature limiting.

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: Systems for producing vaporous working fluid are provided, including: a first fluid passage configured to convey a working fluid to a first solar heating system, wherein the first solar heating system heats the working fluid to produce a heated working fluid having a temperature t1 and a quality X1; a second fluid passage configured to convey a heat transfer fluid to a second solar heating system to produce a heated heat transfer fluid; and a heat exchanger configured to transfer heat from the heated heat transfer fluid to the heated working fluid. When X1<1, the heat transfer results in an increase in quality of the heated working fluid When X1=1, the heat transfer results in an increase in temperature of the heated working fluid. Methods of using the systems to produce vaporous working fluid are also provided.

Abstract: A heat rejection system for a solar power collector having an array of heliostat mirrors, the heat rejection system having a rail system supporting the array of heliostat mirrors, the rail system having a plurality of thermally conductive pipes, a reservoir positioned underground and connected to the rail system, a condenser connected to the thermally conductive pipes and the reservoir, and a coolant means circulating through the thermally conductive pipes, condenser and reservoir the heat rejection system operates as closed systems without the consumption of water and returns solar heat to the environment.

Abstract: According to one embodiment, a solar heat collecting apparatus comprises a first heat exchanging unit and a second heat exchanging unit. The first heat exchanging unit includes a first pipe through which a heat medium flows and a first heat receiving face which receives heat of sunlight reflected by a plurality of reflecting units. The first heat exchanging unit heats the heat medium flowing through the first pipe by using heat of the first heat receiving face. A second heat exchanging unit includes a second pipe through which the heat medium heated by the first heat exchanging unit flows, a second heat receiving face which receives heat of the sunlight reflected by a plurality of reflecting units, and a nozzle provided to the second pipe to discharge the heat medium flowing through the second pipe toward a back face of the second heat receiving face.

Abstract: A variety of methods of forming polymer manifolds and the resulting manifold structures are described. The described manifolds are well suited for use in heat exchangers and a variety of other applications. In one aspect a polymer manifold includes a multiplicity of tubes having first ends that are received by a manifold housing. A polymer film is secured to the manifold housing and to the ends of each of the tubes. The film is arranged to seal the housing while leaving the openings of the tubes exposed to thereby create a manifold. In some embodiments, a potting material is used to reinforce the film. In a method aspect, a manifold may be formed by positioning first ends of the tubes in a manifold housing and welding a polymer film to the manifold housing and to distal tips of the tubes. Openings for the tubes are then formed in the film by directing heat towards the film which melts or vaporizes the film in the regions of the tube openings.

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: The present invention includes a solar water heating system including: a water tank to hold water to be heated, an heat transfer fluid circuit including an heat exchanger associated with said water tank to heat water therein, a solar collection means in communication with said heat exchanger, an inlet connection to carry heat transfer fluid from said solar collection means to said heat exchanger where said water will be heated; and an outlet connection to carry heat transfer fluid from said heat exchanger to said solar collection means where said heat transfer fluid will be heated, said heat transfer fluid circuit including a reversibly evaporable heat transfer fluid which will absorb heat from said solar collection means and which will transfer said heat to said water in said water tank by means of said heat exchanger; and an diversion path being provided in said heat transfer circuit, whereby when a portion of heat transfer fluid changes to a gaseous state in said solar collection means, heat transfer fluid

Abstract: A window with an integral solar heat-absorber is provided in a compact, low-cost package. Two transparent panes are separated from one another to provide a first passageway for receiving a working fluid. The periphery of the panes is secured in a frame in which a heat exchanger is also secured, the heat exchanger having a second passageway for the working fluid and a third passageway for a service fluid. The first and second passageways are coupled to make a working fluid circuit.

Abstract: Solar heat collector, especially an evacuated-tube solar heat collector, filled with first solid heat storage and conducting material transfers the solar heat to an electric power heat insulated utensil through second heat conducting/transferring material for cooking foods and making coffee/tea. A set of solar cooking appliance having a solar heat collector filed with a first solid heat storage and conducting material and a solar cooking range filled with third solid heat storage and conducting material. The solar cooking range having a heat insulated enclosed compartment and also having a cooktop. The cooking range having a set of cooking chambers which are in thermal contact with the first and second heat storage and conducting material for cooking food therein. The cooking appliance also has a group of removable parts that cover the cooking chambers separately. An electric power heater provides a backup energy source and electric heat storage.

Abstract: A solar collector assembly comprises a plurality of heater collection tubes. A thermal enhancement manifold assembly is integrated into the solar collector assembly to enhance thermal efficiency. The enhancement manifold assembly includes a supply manifold subassembly which selectively distributes a refrigerant between at least two supply manifolds and a return manifold subassembly which distributes the refrigerant between at least two return manifolds. A thermal enhancing tube provides fluid communication between each supply manifold and respective return manifold. The thermal enhancing tubes are assembled within an interior volume of the solar heater collection tubes. Each manifold pairing is operatively governed by a respective fluid control valve. The manifold pairings alternate between an active state and an inactive state, optimizing thermal transfer between the collection tube and a refrigerant.

Abstract: A solar hot water and recovery system includes a water loop, a refrigerant loop and a solar loop. Cross-heat exchange occurs in a first heat exchanger between the heat transfer mediums of the refrigerant loop and the solar loop to produce a super-heated fluid stream which is returned to the air conditioning or heat pump unit. Cross-heat exchange also takes place in a second heat exchanger between the now-lower temperature heat transfer medium of the solar loop and the water loop to produce a heated water stream. The main objective of the system is to superheat refrigerant and use all excess heat for heating the water. The heat exchangers are preferably housed in the same heat recovery unit and arranged so that the refrigerant heat exchange area is before the water heat exchange area, thereby maximizing solar potential.

Abstract: A solar concentration plant which uses water/steam as a heat-carrying fluid, in any thermodynamic cycle or system for the exploitation of process heat, which is comprised of an evaporation subsystem, where saturated steam is produced under the conditions of pressure of the system, and a superheater subsystem through which the steam reaches the required conditions of pressure and temperature at the turbine inlet, and in which an attemperation system (10) may be incorporated, these being physically separated and interconnected by means of a drum (5) in which the separation of water and steam takes place, and in which a strategic control of the pointing of the field of heliostats (1) towards either of the subsystems (evaporator or superheater) may be carried out, with individual or group pointing of the heliostats, in such a way that they jointly control both the pressure within the drum (5) and the outlet temperature of the superheated steam (11).

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 generally relates to non-linear solar receivers particularly optimized for high temperature thermodynamic cycles. In one embodiment, the present invention relates to a non-linear solar receiver comprised of at least two heat exchangers with one first set of heat exchangers increasing the enthalpy in a relatively lower temperature to the one second set of heat exchangers increasing the enthalpy of either the thermodynamic cycle working fluid or a heat transfer fluid.

Abstract: A dual hybrid heating apparatus, method of assembly and operation to heat potable water in a tank by heat exchange with a fluid heated by free heat sources—waste heat from heat recovery units and insolation. Once a demand for heated potable water is satisfied, a controller issues commands that cause the fluid to bypass the tank and instead flow to a further heat exchanger. Temperature is monitored downstream—if excessive, then the fluid is sent to a heat dump. A further fluid is heated by heat exchange at the further heat exchanger and then routed to where a parabolic dish solar concentrator vaporizes it to turn a blade of a turbine generator to generate electricity. Heat is extracted from the vapor to form condensate, but the vapor also heats the condensate before being cooled by heat exchange with fluid cooled by a cooling tower.

Abstract: A free-floating, integrated, solar operated water heater appliance, for heating a body of water includes a flotation device for buoyantly supporting the appliance in the body of water. A water heater element, fueled by solar energy, heats water pumped through the heater element by an integral pump, driven by solar energy. A solar energy reflector/container supports the heater element and concentrates solar energy onto the outer surface of the heater element. A parabolic reflector concentrates solar energy onto the inner surface of the heater element. Water is circulated through the heater element and returned, in elevated temperature, to the body of water.

Abstract: A solar light (heat) absorption material is provided which has an excellent solar light (heat) absorbing ability and a simple structure, and may be usable as a low-cost and high-performance heat absorption/accumulation material, the inventive material being usable also as a solar light (heat) absorption/control building component that allows easy change of its solar light (heat) absorption/control ability. The material comprises particles dispersed into a liquid medium having a specific heat ranging from 0.4 to 1.4 cal/g/° C. and a melting point of 5° C. or lower. The dispersed particles have L*value of 30 or less as determined by the CIE-Lab color system (light source D65).

Abstract: A solar panel includes an inlet manifold, an outlet manifold spaced apart from the inlet manifold, and a plurality of pipes having a first end in open fluid communication with the inlet manifold and a second end in open fluid communication with the outlet manifold. A box-shaped cover formed of a polycarbonate material is disposed in ensleeving relation to the plurality of pipes. The box-shaped cover has a length at least slightly less than the distance between the inlet and outlet manifolds so that opposite ends of pipes in the plurality of pipes are exposed to ambient. The cover substantially prevents ventilation of the plurality of pipes and thus allows water temperatures in the panel to rise higher than possible in the absence of such cover. The exposure of the opposite ends of the pipes to ambient prevents water temperatures in the panel from exceeding a predetermined temperature.

Abstract: A solar thermal system comprising at least one solar system including a solar system working fluid flowing therethrough, and a solar receiver for heating the solar system working fluid by solar radiation admitted into the solar receiver, and a thermal energy system in fluid communication with the solar system and receiving the heated solar system working fluid so as to produce thermal energy.

Abstract: An evacuated solar thermal conductive device including a conductive heat receiving element having a heat receiving surface and a heat sink portion disposed away from the heat receiving surface. A heat resistant enclosure that includes a top encasing that is at least partially transparent, and a bottom encasing that is joined to the top encasing to create an airtight seal. The bottom encasing having a cavity for receiving at least part of the heat receiving element such that at least part of the heat sink portion is in direct contact with the bottom encasing. A vacuum is provided in a space within the enclosure between at least a part of the heat receiving surface and the top encasing. Solar energy is transmitted to the heat receiving surface through the transparent top encasing and is transferred through the heat receiving element to the heat sink portion.

Abstract: This relates to a heating device including a solar energy collector, the solar energy collector transferring collected solar energy to outside air. First collector panels are used to heat outside air which heated air is led to a heater, for example a space heater. Second collector panels are used to transfer solar energy to air led to a heat exchanger of a heat pump. The heat pump transfers the extracted heat to heat storage. The stored heat is added to the air coming from the first collector panels if the temperature of the air coming from the first collector panels is below a predetermined temperature.

Abstract: A solar thermal power plant is provided. The solar thermal power plant includes a thermal-electric power plant and a solar collection system in communication therewith to provide heat thereto for driving its operation and being designed to facilitate capture of thermal energy of incident solar radiation by a thermal transfer fluid flowing therethrough for providing the heat. The solar collection system includes one or more solar collectors configured for the capture. The solar collection system further includes at least one dual-purpose pipe configured for carrying heated thermal transfer fluid to the thermal-electric power plant, the dual-purpose pipe including a supply chamber for carrying the thermal transfer fluid therethrough, and at least one storage element in thermal communication with and in fluid isolation from the supply chamber, and being configured for storing thermal energy for providing heat for driving operation of the thermal-electric power plant.

Abstract: A method for storing heat from a solar collector CSTC in Concentrating Solar Power plants and delivering the heat to the power plant PP when needed. The method uses a compressed gas such as carbon dioxide or air as a heat transfer medium in the collectors CSTC and transferring the heat by depositing it on a bed of heat-resistant solids and later, recovering the heat by a second circuit of the same compressed gas. The storage system HSS is designed to allow the heat to be recovered at a high efficiency with practically no reduction in temperature. Unlike liquid heat transfer media, our storage method itself can operate at very high temperatures, up to 3000° F., a capability which can lead to greater efficiency.

Abstract: An air-to-air heat exchanging solar heater consists of at least one panel having a frame surrounding a mounting plate. At least one column of recycled aluminum cans consisting of about 17 cans stacked end to end. Each respective can has its top removed (thus having an open top) and the bottom wall having a plurality of holes, preferably four to eight holes ¾? in diameter. A baffled air column is therefore defined by the end-to-end stacked cans. A low power fan draws air through the column. Preferably, the at least one panel includes 17 columns of 17 cans and the entire assembly (except for the clear panel) is painted black with a high-temperature paint. The at least one panel includes hardware to create an air passage to an existing heating system and draws fresh air from outside.

Abstract: A system for converting solar energy to chemical energy, and, subsequently, to thermal energy includes a light-harvesting station, a storage station, and a thermal energy release station. The system may include additional stations for converting the released thermal energy to other energy forms, e.g., to electrical energy and mechanical work. At the light-harvesting station, a photochemically active first organometallic compound, e.g., a fulvalenyl diruthenium complex, is exposed to light and is photochemically converted to a second, higher-energy organometallic compound, which is then transported to a storage station. At the storage station, the high-energy organometallic compound is stored for a desired time and/or is transported to a desired location for thermal energy release.

Abstract: A solar collector/heat exchanger includes a first panel of corrugated heat conductive material, a second panel of corrugated heat conductive material, and a third panel of corrugated material. A mounting structure mounts the first and second panels with the third panel sandwiched between the first and second panels. The mounting structure further defines an air flow path across the first and second panels. The corrugations of the first and second panels extend parallel to the air flow path and the corrugations of the third panel extend perpendicular to the air flow path so as to cause turbulence in air passing between the first and second panels.

Abstract: A solar receiver for conversion of solar radiation to thermal energy includes an enclosure defining a cavity and having an aperture for receiving an influx of concentrated solar radiation. A heat exchanger is received within the cavity for transferring heat out of the solar receiver. The heat exchanger comprises a plurality of heat exchange cells arranged in polygonal array within the cavity. Each heat exchange cell comprises an inlet, an outlet, and a heat exchange matrix interposed within a first volume defined between a first plate and a second plate spaced apart from the first plate. The inlet and outlet are in fluid communication with the first volume and the first plate, second plate, and heat exchange matrix are monolithically bonded as a unit. The first plate receives concentrated solar radiation and the heat exchange media defines a pathway for a fluid flowing from the inlet to the outlet between the first and second plates.

Abstract: A solar heating apparatus is disclosed that, in one embodiment, comprises a heating coil with improved heating efficiency comprising a first lateral tube comprising rounded ends and an elliptical cross section for a portion extending between the ends that is connected by a rounded end cap to a second lateral tube also comprising rounded ends and an elliptical cross section for a portion extending between the ends.

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 covering device (1) suitable to realize at least part of the covering of a roof (50) or the like and comprising: a central portion (2) including at least one channelling element (5), suitable to contain a heat exchange fluid suitable to store thermal solar energy, at least one peripheral portion (3) comprising a cavity (15), suitable to contain the heat exchange fluid in fluid communication with at least one channelling element (5), the peripheral portion (3) comprising connection means (19) suitable to connect, in fluid communication, the cavity (15) with a cavity (15) of a further peripheral portion (3) part of a further covering device (1).