A solar energy capture, conversion and storage system for use on a roof of a building for capturing and converting incident solar radiation to heat and electricity. The invention provides an optimized solar energy capture and conversion system that monitors immediately available incident radiation comprising a mounting structure which supports a matrix in which is embedded a conduit containing a working fluid. The fluid or fluid mixture includes at least one hydro-fluoro-ether (HFE). Valves are arranged to open/close ports which connect the solar energy capture system to either a combined heat/electrical generating system or an energy storage system that incorporates a phase change material to store heat energy. Control of the valves is supervised by an energy management system.

Solar receivers including a plurality of multi-scale solar absorbing surfaces arranged such that light or heat reflected from or emitted from one or more of the plurality of solar absorbing surfaces impinges one or more other solar absorbing surfaces of the solar receiver. The disclosed receivers increase the amount of absorbed energy from a concentrated light source, such as a heliostat field, and reduce radiative and convective heat losses.

A bladed solar thermal receiver for absorbing concentrated sunlight is disclosed. The receiver includes a plurality of panels arranged in a bladed configuration for absorbing sunlight. The bladed configurations can be radial or planar. The receiver design increases the effective solar absorptance and efficiency by providing a light trap for the incident solar radiation while reducing heat losses from radiation and convection.

A bladed solar thermal receiver for absorbing concentrated sunlight is disclosed. The receiver includes a plurality of panels arranged in a bladed configuration for absorbing sunlight. The bladed configurations can be radial or planar. The receiver design increases the effective solar absorptance and efficiency by providing a light trap for the incident solar radiation while reducing heat losses from radiation and convection.

A concentrator tube comprises a reflector portion having two walls; and an aperture closing an opening to the reflector portion. The aperture and the reflector portion extend longitudinally. The aperture is substantially flat relative to curvature of the reflector portion.

A concentrator tube comprises a reflector portion having two walls; and an aperture closing an opening to the reflector portion. The aperture and the reflector portion extend longitudinally. The aperture is substantially flat relative to curvature of the reflector portion.

Solar receivers including a plurality of multi-scale solar absorbing surfaces arranged such that light or heat reflected from or emitted from one or more of the plurality of solar absorbing surfaces impinges one or more other solar absorbing surfaces of the solar receiver. The disclosed receivers increase the amount of absorbed energy from a concentrated light source, such as a heliostat field, and reduce radiative and convective heat losses.

The invention can make up the entire roof of a building or vehicle, or be integrated into a portion of said roofs. This invention utilizes and reduces the amount of solar radiation that enters a building or vehicle via the roof. This system can include a water holding tank or a plurality of tanks, heat exchangers, fire sprinkler heads and various glazing options. Said heat exchangers are contained between the rafters or trusses, and takes advantage of thermal syphoning to store energy in said tank or said plurality of tanks. Additionally, this roof system can function as a fire suppression apparatus and a skylight apparatus that allows natural light into the structure, and may be integrated with LED lighting to illuminate the skylight glazing and interior space. The exterior upper covering may consist of a glazing material like tempered glass coupled with additional roofing elements or standard upper covering assemblies.

A solar energy capture, conversion and storage system for use on a roof of a building for capturing and converting incident solar radiation to heat and electricity. The invention provides an optimised solar energy capture and conversion system that monitors immediately available incident radiation comprising a mounting structure which supports a matrix in which is embedded a conduit containing a working fluid. The fluid or fluid mixture includes at least one hydro-fluoro-ether (HFE). Valves are arranged to open/close ports which connect the solar energy capture system to either a combined heat/electrical generating system or an energy storage system that incorporates a phase change material to store heat energy. Control of the valves is supervised by an energy management system.

A solar water-heating panel is provided, comprising a plurality of risers configured for utilizing solar radiation impinging thereon to heat a fluid therein. Each riser comprises a riser wall defining a fluid path for flow therethrough of the fluid. The panel further comprises one or more headers for facilitating delivery of the fluid between the panel and an external source of the fluid. The risers are parallely-arranged and separate from one another, and each comprises a longitudinal fin projecting sidewardly therefrom toward, and contacting, an adjacent riser.