A trim assembly is disclosed. The trim assembly includes a trim, where the trim has a curved form, and a trim mounting bracket, where the trim is mountable on the trim mounting bracket.

A hybrid receiver-combustor (100) for capturing heat energy from a solar source and a fuel source. The hybrid receiver-combustor (100) includes a vessel (110) for acting both as a combustion furnace and as a solar receiver, and a plurality of burners (180) for combusting an oxidant stream, such as an air stream, and a fuel stream. The vessel (110) includes a casing (120) defining a cavity (125) having an aperture (130) for receiving the concentrated solar radiation from the solar source. The cavity (125) provides a chamber defining a zone (126) which can function as a combustion zone for production of heat energy through a combustion process using the fuel and into which concentrated solar radiation can be received from the solar source through the aperture (130). A heat energy absorber (190) configured as a heat exchanger is provided to receive heat energy from concentrated solar radiation entering the cavity (125) through the aperture (130) and from combustion within the cavity. A fluidic seal system (135) is associated with the aperture (130) and is operable to establish a fluidic seal to restrict fluid flow through the aperture (130) during the combustion process. The fluidic seal comprises exhaust gas from the combustion process within the cavity (125).

Broadband reflectors include a UV-reflective multilayer optical film and a VIS/IR-reflective layer. In various embodiments, the VIS/IR reflective layer may be a reflective metal layer or a multilayer optical film. Concentrated solar power systems and methods of harnessing solar energy using the broadband reflectors and optionally comprising a celestial tracking mechanism are also disclosed.

A solar-collector roofing assembly (10) comprises a plurality of elongate spaced-apart primary support members (12) aligned in a horizontal plane and extending in a first direction A; a plurality of elongate spaced-apart secondary support members (14) having first and second end portions (38, 40) connected to corresponding said primary support members (12), first and second end portions (38, 40) on a respective primary support member (12)being vertically offset relative to each other; and at least one solar-energy collector panel (16) directly or indirectly supported by the secondary support members (14) so as to have a predetermined fall towards an associated primary support member (12).

A solar heat boiler is provided which is capable of avoiding damage to heat transfer tubes without increasing facility cost and construction cost. The solar heat boiler includes: a low-temperature heating device by which water supplied from a water supply pump is heated by heat of sunlight; a steam-water separation device by which two-phase fluid of water and steam generated in the low-temperature heating device is separated into water and steam; a high-temperature heating device by which the steam separated by the steam-water separation device is heated by the heat of sunlight; and a circulation pump by which the water separated by the steam-water separation device is supplied to the low-temperature heating device.

The molten salt solar tower system 100 is provided for controlling molten salt temperature in a solar receiver 130 for effective operation of the system 100 while without degrading physical properties of molten salt. The system 100 includes two circuits, first 140 and second 150. The first circuit 140 is configured to supply relatively cold molten salt in the solar receiver 130 for heating, and the second circuit 150 is configured to supply a predetermined amount of the relatively cold molten salt in the first circuit 140, as and when the temperature of the relatively hot molten salt circulating through the solar receiver 130 exceeds a predetermined set temperature value thereof.

A receiver system for a Fresnel solar plant is provided. The system includes an absorber tube defining a longitudinal direction and a mirror array that runs parallel to the longitudinal direction. The mirror array has a mirror-symmetrical curve profile having at least one top apex for concentrating light beams onto the absorber tube. The mirror array has ventilation holes in the region of the apex.

The cooling fixture for solar photovoltaic panels has a hollow support platform made from thermally conductive metal that contains a heat exchange medium, preferably water. The solar photovoltaic panel is supported atop the platform so that heat absorbed by the panel is transferred to the platform by conduction and through the media by convection. The platform is pivotally supported on a base frame, and can be adjusted to any desired angle by a brace releasably engaging lugs projecting from the edge of the platform. The heat exchange medium is circulated from the top of the platform to the bottom of the platform by a thermo-siphon effect through at least one thin, rectangular duct having at least one fin for cooling the medium by heat exchange with air.

High-temperature solar trap collectors provide near ambient temperature solar entry surfaces and negligible thermal radiation losses by counterflowing low velocity transparent gases or liquids (fluids) to nullify internal thermal diffusion and radiative heat losses at the solar entry surface. Small steradian (sr) baffling plus wavelength-selective materials trap the entire 0.35 u to 2.7 u incoming solar spectrum and heat highly absorbing internal surfaces to high temperatures; only a small solid angle of the 2 steradianson the order of 0.01 srof internal thermal radiation escapes. A nearly 100% efficient flat panel solar trapping embodiment exhibits alpha () absorption nearing 1.0 and radiant emission losses nearing 0.0 even at solar collection temperatures in excess of 1,000 K. Ultra high collection efficiency counterflow configurations are ideal for solar hot water, space heating, cooling, energy storage, and electric power generation applications.

A device is provided for the air-based solar thermal generation of process heat in order to assist in drying processes. The device may add the solar-thermally generated hot air as a function of the relative temperature of the solar-thermally generated hot air as a partial flow of the process air generated by other systems.