Disclosed is a device with a heat exchanger having a first flow through which a first gaseous heat transfer medium passes and a second flow through which a second gaseous heat transfer medium passes. Upstream of the first flow, there is a combustion chamber, which optionally extends into the first flow. Two feed lines are attached to the first flow, of which the first feed line is connected to a thermal solar installation and the second feed line is connected to a source for a combustible gas-air mixture or for a non-combustible gas, in particular an oxygen-containing gas, such as air.

A solar water heater absorber absorbs the sun's energy on the surface of a twin-walled polycarbonate panel and conducts the heat from the sun through the panel wall into fluid flow through channels of the panel. The panel is an extruded polycarbonate glazing material that consists of two panes connected by longitudinal ribs to form a plurality of water channels that may further include twisted strips providing a helical water flow pattern that increases turbulence within the water channels. The panel is connected to large pipes or headers on the top and bottom ends of the panel that receive the heated fluid from the water channels, allow the heated fluid to exit the panel, and for return water to re-enter the panel in a solar water heating system.

A liquid-gas heat exchanger for use in a heat exchange system using solar energy has an insulated chamber adapted to allow hot air to pass therethrough. A coil member extends through the insulated chamber and is adapted to allow a heat transfer liquid to pass into and then out of the insulated chamber. The spacing between the windings of the coil are predefined and the coil is in a predetermined position inside the insulated chamber, so as to force the air to pass in between the coil windings and increase the air contact with the coil and provide a large heat exchange. Several baffle members are placed each side of the coil member and an interior area of the insulated chamber and force air to circulate multiple times through the coil member, thereby allowing for an efficient exchange from the hot air to the heat transfer liquid. The insulated containe contains the heat exchanger which is comprised of a plurality of chambers, wherein each the plurality of chambers has a repeating pattern of shapes wherein each of the chamber of th plurality of charribers consists of one deflector which deflector being opposite to another deflector, which other deflector is a mirror image of its opposite deflector but shifted approximately half a the wall length. Each of the deflectors is defined by a specific sequence of components starting with a rounded wall from which extends a shear barrier and the wall is terminated by a diverter.

The present invention relates to a solar surface receptor module that operates at a high temperature and comprises a channel (101) extending therethrough and along which a heat transfer occurs between a fluid (liquid or gas) moving in said channel (101) and at least one wall (104) of the receptor exposed to concentrated solar radiation, characterized in that the inner surface (105) of at least said wall includes turbulence-generating actuators (110) at the fluid inlet (102). The present invention also relates to a solar receptor therefor.

An air heating unit using solar energy has an inner core further comprised of at least one passageway within which air circulates while being interfered by baffles shaped, sized, and positioned so as to create turbulence in the air flow in order to homogeneously warm the air.

A device is provided which reduces the temperature of a solar PV panel. The device includes an enclosure comprising a heat sink attachable to a bottom side of the solar PV panel to provide an air channel, and a tornado tube. The tornado pipe may be oriented vertically to the plane of the earth, and may act as a solar chimney, instigating a flow of air to enter the enclosure through an air inlet. This air flow may be drawn across the heat sink and exit back to the atmosphere through the tornado tube.

A solar collector is provided. The collector comprises a monolithic flow control component to direct a flow of the heat transfer fluid between an inlet and outlet; and a solar absorber supported by the monolithic flow control component. The monolithic flow control component is able to support the solar absorber without any additional structural components to lend mechanical strength to the monolithic flow control component.

Photovoltaic thermal (PVT) apparatus 10 combines a photovoltaic panel (PV) panel 24 and solar air heater (SAH). The SAH includes body 12 with hollow interior 14 defining ducts 16a, 18a for air inlet 16 and air return 18. Jets 22 provide air to convey heat from the PV panel underside. Spaces between the jets provide drains 26 for warmed air to flow away. Flow modifiers/deflectors 124 can guide the airflow. A fan 42 pushes ambient air into the inlet 16 via air handling unit (AHU) 50. Return warm air flows via the AHU to escape via the ambient exhaust 40. A combined thermal transfer and storage unit 52 determines whether air from the PVT panel(s) diverts to the interior space. For cooler ambient conditions, the PVT apparatus can radiate heat to return cooled air into the space. The PVT apparatus can harvest condensation, heat/cool pools and industrial processes.

The element on which solar radiation is concentrated, specifically, a vacuum tube, remain static at all times with respect to the movements that a parabolic reflective surface may make according to the direction of solar radiation, such that inlet and outlet pipes of the vacuum tube do not need to be articulated, which facilitates the installation and insulation thereof and reduces production costs. The parabolic reflective surface can pivot 360° with respect to the vacuum tube without interfering with the pipes, allowing an active safety system for protecting against strong winds and preventing overheating to be produced, in addition to allowing the surfaces to be cleaned by means of nozzles spray pressurized water. The collector also includes passive safety means against strong winds.

A solar panel bracket with a water conducting function for carrying a plurality of solar photovoltaic panels, comprising: a plurality of first brackets, each of the first brackets is arranged in parallel with each other, each of the first brackets has a first water conducting groove; a plurality of second brackets, each of the second brackets is arranged in parallel with each other, each of the second brackets has a second water conducting groove, the second brackets and the first brackets are arranged perpendicular to each other, and the second brackets and the first brackets surround to form a plurality of square spaces, the solar photovoltaic panels are arranged on the square spaces; and a plurality of third water conducting groove groups, each of the third water conducting groove groups is disposed on the side of each of the first brackets, and each of the third water conducting groove group has a third water conducting groove, and the second water conducting grooves communicate with the third water conducting grooves.