An ultra-supercritical (USC) tower-type solar heat absorber includes a grille-hot-plate current-sharing screen, a tube row, and a graphite filling layer. The grille-hot-plate current-sharing screen is assembled by a plurality of grille hot plates. Each of the plurality of grille hot plates includes a liquid-absorbing core and a grille, and is filled with a phase-transition working medium (such as sodium, potassium, and lithium) and pumped to a vacuum state. When sunlight is reflected and concentrated on the grille-hot-plate current-sharing screen, the phase-transition working medium absorbs heat and evaporates on an evaporation surface of a grille hot plate, is condensed on a condensation surface of the grille hot plate, and returns to the liquid-absorbing core through a grille to produce a stable two-phase flow, which allows efficient heat transfer, homogenizes a surface heat-flow density, and greatly reduces a temperature difference and a thermal stress on a surface of the grille-hot-plate current-sharing screen.

A curved surface absorber type solar fluid heater having radially spaced curved surfaces, preferably hemispherical and closed at bottom periphery, defining a closed chamber termed as collector which receives a fluid to be heated. The curved surface absorber type solar fluid heater encompasses two radially spaced transparent curved surfaces preferably hemispherical, closed at bottom periphery, placed over collector termed as a glazing, and an insulated hemispherical hot fluid tank, placed within the cavity of inner curved surface of the collector and bottom insulation. A plurality of plumbing connections is made between the collector and the hot fluid tank with arrangement of non-return valves to prevent backflow of fluid from hot fluid tank towards the collector. An air vent is located at the highest position of the collector. A drain plug is located at a lowest position on the collector.

A solar collector adapted to absorb thermal heating from the sun, wherein said solar collector comprises hollow sections adapted to house a medium. The solar collector is a self-supporting composite solar collector produced from a composite material constituted of at least a first and second material, wherein said first and second materials have equal or substantially equal coefficients of elasticity.

A system comprises: at least one heat exchange panel (700) comprising: a main body (100) comprising a sealed cavity in which is provided a fluid in both liquid and gas phases and being configured to communicate heat energy by allowing evaporation of the liquid at one location and condensation of the liquid at a different location in the cavity; and at least a first heat exchanger part (130, 210a, 211a) including an inlet and an outlet for allowing the passing of fluid through the heat exchanger, the first heat exchanger part being thermally coupled to the heat spreading part so as to communicate heat energy between fluid flowing through the first heat exchanger part and the heat spreading part and thus the environment in which the heat spreading part is present. A controller is configured to cause control of pumps and valves to as to cause the system to operate in a number of different modes of operation, wherein the system is operable in an active heating mode of operation in which the controller controls the heat pump, the one or more fluid pumps and the valves to provide the system with: a first fluid circuit in which fluid is pumped through the heat exchange panel and a first side of the heat pump, a second fluid circuit in which fluid is pumped through the heat tank and the second side of the heat pump, and transfer by the heat pump of heat energy from the first fluid circuit to the second fluid circuit.

A flat plate heating solar panel comprised of polymer materials that can withstand relatively high temperatures. The polymer materials utilized in the panel have similar thermal expansion characteristics so that different components can by connected to each other without excessive stresses and damage during temperature changes, and with major components capable of being fabricated by molding processes, including extrusion and injection molding. An expansion joint or slot is provided in the enclosure frame to allow relative movement between the header connector and the frame in order to minimize stresses when large temperature differences exist between the absorber/header and the frame, and the slot design also provides a vent to relieve excessive air pressures inside the panel at high temperatures. An electronic controller with wireless capability, powered by a small photovoltaic solar cell with energy storage by a supercapacitor or an ultracapacitor, is integrated with the panel to operate a pump to circulate a heat transfer fluid through the panel when heating capability exists and when heat is needed to increase the temperature of the substance to be heated by the panel.

A heat collector includes a body including a hollow portion extending from a first end to a second end of the body and being a metal-extruded body having a light-receiving surface to receive sunlight, a pair of lids adjacent to the first end and the second end and covering the hollow portion, an inlet located in one of the pair of lids to allow a heating medium to enter the hollow portion, and an outlet located in one of the pair of lids to allow the heating medium to exit the hollow portion.

The subject of the present application is an arrangement of sandwich panels already used in buildings in a way that makes them capable of collecting solar radiation and ambient heat and transferring the energy out of the roof. The structural elements of the present invention consist of a heat insulating core sandwiched between external and internal sheets with load-bearing capacity, similar to the make-up of the known load-bearing sandwich panels. Whether the sheet profiles are placed in the direction of the ridge beam or of the rafters, with the appropriate set of them, hollow structure is created on the surface and in the core of the panel in the direction of the rafters, in the entire length of the roof, functioning as pathways for gaseous materials (air ducts (1, 4)). If these air ducts, both external and in the core, are connected at the end facing each other, i.e. at the upper air turn chamber (8), the substance in them will start to flow on its own using solely gravitational forces in reaction to heat reaching the panel's external surface, i.e. the external profiled metal sheet (2). If a given point of the panel is cooled by heat exchanger (6), the spontaneous flow will remain continuous. Cooling transports the heat collected in the air ducts (hot air duct (1) and cold air duct (4)) out of the system, and this heat is utilized to provide for our energy needs. The subject of the application is, therefore a sandwich panel which functions as a thermal collector, hereinafter heat collector sandwich panel (3), which serves as the roof structure of a building, or is an integral part of the roof structure and meets without fail all protection requirements set for roof constructions. Due to its special design it is capable of collecting ambient heat, and transferring this heat to heat storage by the use of compatible, known auxiliary appliances.

The invention provides a panel comprising at least the following components: a) at least one hollow container; b) an inlet; c) an outlet; and wherein the inlet is connected to the end of the at least one hollow container; and the outlet is connected to an opposite end of the at least one hollow container; and wherein the at least one hollow container comprises at least one component formed from a composition comprising the following components: A) an ethylene-based polymer; B) a compound selected from Formula 1, as described herein; and C) a compound selected from Formula 2, as described herein; and wherein the weight ratio of Component C to Component B (C/B) is greater than, or equal to, 1.

A building includes at least one structural member. The structural member includes a light-receiving surface that is formed by extrusion or casting of a metal and is irradiated with sunlight, a structural member main body in which a hollow portion extending from a first end portion toward a second end portion is formed, a pair of lid portions that are respectively disposed at the first end portion and the second end portion, and close the hollow portion, an inlet that is provided in any one of the pair of lid portions and through which a heating medium flows into the hollow portion, and an outlet that is provided in any one of the pair of lid portions and through which the heating medium flows out from the hollow portion.

An aspect of the present disclosure is a receiver for receiving radiation from a heliostat array that includes at least one external panel configured to form an internal cavity and an open face. The open face is positioned substantially perpendicular to a longitudinal axis and forms an entrance to the internal cavity. The receiver also includes at least one internal panel positioned within the cavity and aligned substantially parallel to the longitudinal axis, and the at least one internal panel includes at least one channel configured to distribute a heat transfer medium.