An article for reflecting solar energy includes a coating stack having solar reflecting films and metal oxide films, the coating stack applied on a major surface of a glass substrate, and a protective overcoat comprising a first and a second surface, wherein the first surface of the protective overcoat is disposed toward the solar reflective films and metal oxide films; and a polymer encapsulant over outer wall surfaces of the coating stack, the second surface of the protective overcoat and over peripheral edges of the coated article, the encapsulant having a base layer, a top layer and metallic corrosion-inhibitive material in the base layer.

A space-stable thin film composite coating is provided that exhibits high IR emittance properties similar to OSR mirrors, and which is thin enough to be applied to a flexible substrate. The composite coating can include hundreds of alternating layers of aluminum oxide and silicon dioxide vacuum deposited to individual layer thickness of about 150 Angstroms and 50 Angstroms, respectively. The composite coating can be attached to substrates having complex geometries, for example, at various points during integration and production of hardware. The thin film can increase thermal design efficiency, reduce radiator mass and costs, and reduce production time-frames by eliminating the complexity of OSR mirror bonding.

The present invention relates to an optical system for concentrating incoming light comprising a plurality of concentrating optical elements (100) with a front surface (102) arranged to receive incoming light and a back surface (103) arranged to exit light, wherein the front surface is larger than the back surface. Adjacent concentrating optical elements are separated by gaps (101) and the refractive index of the material in a concentrating optical element is higher than the refractive index of the gap. The geometry of the concentrating optical elements is optimized to enhance the light concentration.

The invention relates to a solar energy collection system that uses linear parabolic concentrators designed on a small scale and with a modular configuration that allows optimum usage of solar collection surface area in places such as the roofs or flat roofs of factories or shops where space is generally small or irregular. The solar collector is coupled in rows actuated by a fully autonomous system for electronically controlling solar tracking, the operation of which is based on an algorithm programmed in a microcontroller. An autonomous solar tracking system can efficiently control two parallel rows with a pre-defined number of solar concentrators, as well as automatically detecting the presence of impurities on a reflecting radiation surface for the maintenance thereof. The thermal energy produced is harnessed by a heat exchanger, the operation of which is based on conduction, convection and radiation for dehydration uses.

Techniques for hybrid solar thermal and photovoltaic energy collection are provided. In one aspect, a photovoltaic concentrating thermal collector (PVCTC) includes: a thermal absorber collector; and bent solar panels forming a parabolic shaped trough reflector partially surrounding the thermal absorber collector so as to reflect incident light onto the thermal absorber collector. A PVCTC system including an array of PVCTC units and a method for hybrid electrical and thermal energy production are also provided.

Solar photovoltaic window blind slats for power generation from internal and external light sources are provided are provided. A plurality of solar cells are attached to at least two sides of a slat core. Distributed maximum power point tracking optimizer components are associated with each solar cell. The solar cells and corresponding distributed maximum power point tracking optimizer components on each slat side are connected in electrical series.

Prior art solar energy arrangements are typically structurally complex, have a limited concentration factor and temperature, and their dimensions are large. There is provided a solar energy arrangement and corresponding method for utilizing solar energy by directing sunrays or sunbeams with at least one solar concentrator towards at least one application, device or equipment utilizing solar energy, and a corresponding method, system and computer program product for implementing an arrangement for utilizing solar energy.

A mirror for a solar reflector has at least one sensor integrated in the body of the mirror itself, the body of the mirror being all the layers of the mirror. At least one processor is integrated in the body of the mirror, associated with the sensor, thus generating an intelligent device and an intelligent mirror or smart mirror. A method of assembling the mirror itself and a management system for mirrors that make up a solar field is provided.

A solar receiver includes a porous structure with a uniform or a varying porosity. The porous structure may include specular reflective region on at least one surface and a diffusive reflective region on at least one surface.

The present invention relates to a system for a parabolic solar concentrator (SCA) having a substantially continuous reflective surface aiming to maximize the efficiency of the parabolic solar concentrator and of its fabrication method. The system of the present invention allows the fabrication of a low cost parabolic solar concentrator, based on a torsion bar, ribs and a plurality of reflective pieces of sheet metal preferably covered with a reflective film. The parabolic solar concentrator according to a preferred embodiment allows the reduction of surfaces shading the reflective surface. Another advantage is the lack of presence of supporting or movement elements protruding in the concave side of the parabola, not including receiver tube components and supports, thereby increasing the reflection efficiency and solar collection.