A solar collector has an opaque cover heated by solar energy. Heat flows from the opaque cover by conduction, convection, and infrared emittance across a gap within an at least substantially airtight enclosure to an absorber containing a working fluid. The exterior surface of the opaque cover has high solar energy absorptance and the interior surface has high infrared emittance. The exterior surface preferably has low infrared emittance. In one embodiment, fully wetted surface geometry permits direct and reflected infrared absorption by the absorber. The opaque cover eliminates the weight, cost and other shortcomings of glass. A hollow continuous side wall with rounded corners provides an embodiment that is robust yet economical, that is easy to manufacture and seal, that permits a reduced thickness of the opaque cover and mitigates the destructive potential of severe winds, and that can withstand the compressive forces experienced by an evacuated solar collector.

A solar thermal collector adapted to be assembled from a flat pack configuration, comprising a conduit (6) configured to carry fluid and to absorb radiation, a base (1) above which the conduit (6) is mounted and a plurality of panels configured to interconnect with the base (1) to produce a housing (8) for the conduit (6).

A solar thermal collector adapted to be assembled from a flat pack configuration, comprising a conduit (6) configured to carry fluid and to absorb radiation, a base (1) above which the conduit (6) is mounted and a plurality of panels configured to interconnect with the base (1) to produce a housing (8) for the conduit (6).

A solar collector can comprise: a polymeric housing; a polymeric cover attached to the housing defining an internal volume of the solar collector; a solar energy absorber attached to the housing and located within an area defined by the housing and the cover; wherein the housing comprises a flexible sealing member; and wherein the cover comprises a honeycomb structure.

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.

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.

A solar thermal collecting system captures solar radiation into a vessel containing an opaque or partially opaque fluid medium. The solar radiation is reflected and intensified using interior parabolic reflectors inside the vessel to generate hot zones throughout the fluid medium; and the generated heat in the fluid medium is transported to a separate system designed to utilize the heat with minimal heat loss. The system of the present invention comprises a vessel that contains the fluid medium. An at least partially transparent or translucent lid enables passage of solar radiation into the vessel. The lid may have integrated solar panels to generate power from solar radiation. Multiple reflective parabolic reflectors integrated in the vessel focus solar radiation throughout the fluid medium to create hot zones that intensifies heating the fluid medium. The vessel is resilient to withstand variances in pressure and temperature. After fluid medium absorbs heat, an insulated conduit transports the heated fluid medium for storage or other beneficial uses such as conversion to power with minimal heat loss.

A solar thermal collecting system captures solar radiation into a vessel containing an opaque or partially opaque fluid medium. The solar radiation is reflected and intensified using interior parabolic reflectors inside the vessel to generate hot zones throughout the fluid medium; and the generated heat in the fluid medium is transported to a separate system designed to utilize the heat with minimal heat loss. The system of the present invention comprises a vessel that contains the fluid medium. An at least partially transparent or translucent lid enables passage of solar radiation into the vessel. The lid may have integrated solar panels to generate power from solar radiation. Multiple reflective parabolic reflectors integrated in the vessel focus solar radiation throughout the fluid medium to create hot zones that intensifies heating the fluid medium. The vessel is resilient to withstand variances in pressure and temperature. After fluid medium absorbs heat, an insulated conduit transports the heated fluid medium for storage or other beneficial uses such as conversion to power with minimal heat loss.

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.

A housing for a solar panel is provided and is comprised of a glazed element and a tray. The tray includes a plate, a pair of side walls, a top end cap and a bottom end cap. The tray also includes a lip configured to seat the glazed element. Wherein the plate, the pair of side walls, the top end cap, the bottom end cap are formed of a single material and configured as a single integral component and wherein the plate, the pair of side walls, the top end cap and the bottom end cap are collectively configured to form a cavity. Wherein said top end cap includes a top header, said top header extending the length of said top end cap and said top header extending outward from said top end cap and in a direction away from said cavity.