To overcome shortcomings of the conventional thermal receiver, embodiments of the technology disclosed herein are directed towards an improved thermal receiver. More particularly, the various embodiments of the technology disclosed herein relate to thermal receivers without a vacuum insulation, otherwise known as an approximation of a blackbody. Various embodiments of the technology disclosed herein enable greater absorption of sunlight collected by a parabolic solar trough concentrator compared with conventional thermal receivers.

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.

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.

A concentrated solar power (CSP) system includes channels arranged to convey a flowing solids medium descending under gravity. The channels form a light-absorbing surface configured to absorb solar flux from a heliostat field. The channels may be independently supported, for example by suspension, and gaps between the channels are sized to accommodate thermal expansion. The light absorbing surface may be sloped so that the inside surfaces of the channels proximate to the light absorbing surface define downward-slanting channel floors, and the flowing solids medium flows along these floors. Baffles may be disposed inside the channels and oriented across the direction of descent of the flowing solids medium. The channels may include wedge-shaped walls forming the light-absorbing surface and defining multiple-reflection light paths for solar flux from the heliostat field incident on the light-absorbing surface.

A heat exchanger is comprised of a plurality of chambers, wherein each of the plurality of chambers has a repeating pattern of shapes wherein each of the plurality of chambers consists of two opposite deflectors, wherein each 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 diverter, along with the shear barrier, forms a low pressure zone which creates a vortex. A coil for carrying a liquid wherein the coil consists of a long winding pipe forming tube bundles passing through all of the plurality of chambers.

A solar window system for a building is provided. The solar window system includes multiple heat generation encasements. Air inside each heat generation encasement is heated by solar energy. The solar window system further includes a storage tank for storing heat from the heated air. The solar window system also includes a set of connection pipes, wherein the set of connection pipes draw cold air from an indoor space inside the building into the plurality of heat generation encasements, connect each of the heat generation encasements to at least two other heat generation encasements, and transfer the heated air from the set of heat generation encasements to the storage tank.

A solar automatic heat collecting and equalizing tube, including: a glass tube, an absorption tube, and a baffle. The glass tube is sleeved on the absorption tube. The absorption tube is coated with a heat absorption layer. The space between the glass tube and the absorption tube is vacuum. The baffle is disposed in the inner cavity of the absorption tube and is configured to drive a fluid in the absorption tube to tumble up and down alternately. The baffle is spiral in shape and fixed in the absorption tube.

The invention provides a phase transformation heat exchange device. The device includes an inner tube, an outer tube, and a heat exchange medium; the space between the inner tube and the outer tube forms a whole or a part of a liquid phase region; a whole or a part of space inside the inner tube forms a vaporization region; the heat exchange medium with a relatively high pressure inside the liquid phase region enters the vaporization region with a relatively low pressure while being heated in vortex flow, and flows out of the device after being vapored, so as to complete heat exchange. The device can be applied to DSG systems of the solar energy photothermal field, and can also be applied to an input-output system of a heat storage system, or the field of boiler heating. It is achieved with safe operation, low cost, and good application range.

A system for collecting and storing solar energy as heat. In some embodiments, the system includes heat transfer passages for collecting and transferring heat, as well as ways of arranging passages to minimize thermal losses and redistribute heat. In some embodiments, the system includes an all-reflective solar collector with a largely clear aperture, using multiple light transfer conduits that rotate with the collector.

To overcome shortcomings of the conventional thermal receiver, embodiments of the technology disclosed herein are directed towards an improved thermal receiver. More particularly, the various embodiments of the technology disclosed herein relate to thermal receivers without a vacuum insulation, otherwise known as an approximation of a blackbody. Various embodiments of the technology disclosed herein enable greater absorption of sunlight collected by a parabolic solar trough concentrator compared with conventional thermal receivers.