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 light guide apparatus that can redirect light impinging on the apparatus over a wide range of incident angles and can concentrate light without using a tracking system and methods for fabrication. This apparatus uses conditions of total internal reflection and refraction near the critical angle for total internal reflection (near TIR) in order to trap light within the apparatus.

A light-concentrating lens assembly for a solar energy system, the assembly comprising a plurality of concentrically arranged paraboloid mirror reflectors, a conical light guide extending below the plurality of paraboloid mirror reflectors, an inner central cone disposed along a central axis of the concentrically arranged paraboloid mirror reflectors, and a compound paraboloid concentrator disposed beneath the inner central cone.

A solar concentrator assembly (102) comprises a concave mirror (108) for collecting radiation that is collimated and has uniform distribution from a source and a convex mirror (110). The concave mirror (108) is configured to reflect the radiation to the convex mirror (110) and the convex mirror (110) is configured to reflect the radiation as a concentrated collimated beam in an emission direction that is angularly offset from the source. The concave mirror (108) and convex mirror (110) each have a focal length that varies along one axis such that the radiation collected by the concave mirror (108) is transmitted from the convex mirror (110) with uniform distribution.

A solar concentrator assembly (102) comprises a concave mirror (108) for collecting radiation that is collimated and has uniform distribution from a source and a convex mirror (110). The concave mirror (108) is configured to reflect the radiation to the convex mirror (110) and the convex mirror (110) is configured to reflect the radiation as a concentrated collimated beam in an emission direction that is angularly offset from the source. The concave mirror (108) and convex mirror (110) each have a focal length that varies along one axis such that the radiation collected by the concave mirror (108) is transmitted from the convex mirror (110) with uniform distribution.

A light guide apparatus that can redirect light impinging on the apparatus over a wide range of incident angles and can concentrate light without using a tracking system and methods for fabrication. This apparatus uses conditions of total internal reflection and refraction near the critical angle for total internal reflection (near TIR) in order to trap light within the apparatus.

A light guide apparatus that can redirect light impinging on the apparatus over a wide range of incident angles and can concentrate light without using a tracking system and methods for fabrication. This apparatus uses conditions of total internal reflection and refraction near the critical angle for total internal reflection (near TIR) in order to trap light within the apparatus.

A light-heat gathering solar energy device belonging to the energy device, which is a device for decreasing the area occupied by the solar energy device and increasing the light-heat absorbing efficiency of the sun light, comprising: a bracket structure, which is a structural member having a hollow body; at least one solar energy absorbing device disposed within the hollow body of said bracket structure, the hollow body is formed by the container wall having a geometry structure of upper-wide lower-narrow shape, and at least one cup-shaped bottom structure is disposed therein, said container wall is composed of an outer wall and an inner wall, said outer wall is made of a light-heat absorbing material, said inner wall is made of a light reflecting material, allowing invisible light to penetrate, inward and downward reflection is enabled in the energy absorbing device through the inner wall when the sun light irradiates from the top to the bottom such that the light-heat energy gathering effect is produced within the solar energy absorbing device, and said cup-shaped bottom structure is made of a light-heat absorbing material without a light reflecting layer. Different materials are used in the invention based on different applications, and the device can be used as a solar energy electricity device or a heat energy device and as equipment configured to provide heat energy and electricity.

A light-heat gathering solar energy device belonging to the energy device, which is a device for decreasing the area occupied by the solar energy device and increasing the light-heat absorbing efficiency of the sun light, comprising: a bracket structure, which is a structural member having a hollow body; at least one solar energy absorbing device disposed within the hollow body of said bracket structure, the hollow body is formed by the container wall having a geometry structure of upper-wide lower-narrow shape, and at least one cup-shaped bottom structure is disposed therein, said container wall is composed of an outer wall and an inner wall, said outer wall is made of a light-heat absorbing material, said inner wall is made of a light reflecting material, allowing invisible light to penetrate, inward and downward reflection is enabled in the energy absorbing device through the inner wall when the sun light irradiates from the top to the bottom such that the light-heat energy gathering effect is produced within the solar energy absorbing device, and said cup-shaped bottom structure is made of a light-heat absorbing material without a light reflecting layer. Different materials are used in the invention based on different applications, and the device can be used as a solar energy electricity device or a heat energy device and as equipment configured to provide heat energy and electricity.

The present invention is related to the field of solar concentrators and associated energy conversion apparatus. More particularly, the invention discloses a solar tracking apparatus particularly advantageous for use with solar concentrating optics comprising compound conical concentrators, wherein modular tracking means and integration provide fast drop-in replacement, as well as low-material usage. Also disclosed are improved structures and methods for producing stackable frustum structures of the embodied optical concentrator. Additional structures specific to the inventive solar tracker are also disclosed.