An insulating glazing having at least two panels made of transparent or semi-transparent material is provided. At least one of these panels is a luminescent solar concentrator.

Disclosed is a solar cell module, which comprises a solar cell module comprising a light transmitting element, a front encapsulant layer, a plurality of solar cells spaced from each other, a back encapsulant layer, and an encapsulation backsheet disposed in the module's thickness direction, the plurality of solar cells together forming a matrix which comprises a plurality of solar cell strings parallel with each other, each solar cell string being made up of a plurality of solar cells connected in series, there being a string gap formed between every two adjacent solar cell strings, and there being a cell gap formed between adjacent solar cells in each solar cell string, wherein the solar cell module further comprises a plurality of light redirecting films each of which comprises an optical structure, the light redirecting films being disposed on the solar cells' back surfaces opposite to their light receiving surfaces or the encapsulation backsheet's surface within the solar cell module, such that they spatially correspond to the string gaps and/or the cell gaps, and the optical structures being disposed to face the solar cell's back surfaces, such that the optical structures reflect light toward the interface between the light transmitting element and air, and the light is subsequently totally internally reflected back to the light receiving surfaces of the solar cells.

A reflective concentrator can include a primary reflector and a secondary reflector located radially outward of the primary reflector. The primary reflector can be a rotationally-symmetric, convex conical shape, radial sections of which may include an off-axis parabolic reflector with a focal point radially outward of the primary reflector. A secondary reflector may be located radially outward of the primary reflector, and may include a rotationally symmetric section of a toroidal space surrounding the primary reflector. In some embodiments, the secondary reflector may be convex or concave. Incident sunlight generally aligned with a rotational axis of symmetry of the primary reflector may be reflected off of the primary reflector, off of the secondary reflector, and back towards a point near the central peak of the primary reflector. The reflective concentrator may be aerodynamically stable, and may include an aerodynamic fairing on its read side to further increase the aerodynamic stability of the structure.

A solar cell and a solar laminate are described. The solar cell can have a front side which faces the sun during normal operation and a back side opposite front side. The solar cell can include conductive contacts having substantially reflective outer regions disposed on the back side of the solar cell. The solar laminate can include a first encapsulant, the first encapsulant disposed on the back side of the solar cell and a second encapsulant. The solar laminate can include the solar cell laminated between the first and second encapsulant. The substantially reflective outer regions of the conductive contacts and the first encapsulant can be configured to scatter and/or diffuse light at the back side of the solar laminate for substantial light collection at the back side of the solar cell. Methods of fabricating the solar cell are also described herein.

Angle insensitive/angle-robust colored filter assemblies are provided for use with a photovoltaic device to create a decorative and colored photovoltaic device assembly. The filter may be passive or active with an ultrathin reflective layer of high refractive index material, like amorphous silicon (a-Si). A passive filter may have transparent first and second pairs of dielectric materials surrounding the ultrathin reflective layer. An active filter may have transparent first and second electrodes and first and second doped hole/electron transport layer surrounding the ultrathin reflective layer. The filter can transmit a portion and reflect a portion of the electromagnetic spectrum to generate a reflected color output with minimal angle dependence. Angle insensitive colored photovoltaic device assemblies having high power conversion efficiencies (e.g., ≥18%) including a passive or active colored reflective filter and a photovoltaic device are also contemplated. The photovoltaic device may include a photoactive layer comprising crystalline silicon (c-Si).

Provided herein are systems and methods for storing energy. A photon battery assembly may comprise a light source, phosphorescent material, a photovoltaic cell, and a waveguide. The phosphorescent material can absorb optical energy at a first wavelength from the light source and, after a time delay, emit optical energy at a second wavelength after a time delay. The photovoltaic cell may absorb the optical energy at the second wavelength and generate electrical power. In some instances, a first waveguide may be configured to direct the optical energy at the first wavelength from the light source to the phosphorescent material and/or a second waveguide may be configured to direct the optical energy at the second wavelength from the phosphorescent material to the photovoltaic cell.

A method of making a light converting optical system comprising providing a first optical layer, a thin sheet of reflective light scattering material, a light source, a second optical layer approximately coextensive with the first optical layer, a continuous broad-area photoabsorptive film layer approximately coextensive with the first optical layer, positioning the thin sheet of reflective light scattering material parallel to the first optical layer, positioning the continuous broad-area photoabsorptive film layer between and parallel to the first optical layer and the thin sheet of reflective material, and positioning the second optical layer on a light path between the light source and the continuous broad-area photoabsorptive film layer. The first optical layer has a microstructured broad-area front surface comprising an array of linear grooves disposed side by side and extending along a straight line between two edges of the layer.

A wireless optical power transmission system comprising a transmitter and receiver, the transmitter comprising a laser emitting a beam, a scanning mirror for steering the beam towards said receiver and a control unit receiving signals from a detection unit on the receiver and controlling the beam power and the scanning mirror. The receiver has a photovoltaic cell having a bandgap energy of 0.75-1.2 e V, with a plurality of conductors on abeam receiving surface. A cover layer of material blocking illumination of wavelengths outside that of the laser, is disposed on the photovoltaic cell. The cover layer may have anti-reflective coatings on its top and bottom surfaces. The detection unit thus generates a signal representing the power of the laser beam impinging upon the receiver, independent of illuminations other than that of said laser beam. The control unit thus can maintain the laser power impinging on the receiver.

A space-based solar power station, a power generating satellite module and/or a method for collecting solar radiation and transmitting power generated using electrical current produced therefrom is provided. Each solar power station includes a plurality of satellite modules. The plurality of satellite modules each include a plurality of modular power generation tiles including a photovoltaic solar radiation collector, a power transmitter and associated control electronics. Numerous embodiments relate to efficient power generation tiles. In one embodiment, an efficient power generation tile includes: at least one photovoltaic material; and at least one concentrator that redirects incident solar radiation towards a photovoltaic material such that the photovoltaic material experiences a greater solar flux relative to the case where the photovoltaic material experiences unaltered solar radiation.

Device for generating energy from ambient light A device for generating energy from ambient light, particularly sunlight, comprises a transparent panel (15, 16) having frontally a lateral entry surface (A) for ambient light and having laterally an exit surface which is optically coupled to a photovoltaic conversion device (250). An optically active photoluminescent structure (18) is arranged downstream of the entry surface, which is able and configured to emit emission radiation upon excitation by radiation incident thereon. The emission radiation propagates partially via the panel (15, 16) to the exit surface (U) and to the conversion device. The conversion device comprises an associated array of mechanically interconnected photovoltaic modules (200), each comprising one or more photovoltaic cells. The modules (200) are electrically connected between a first conductor (210) on an optically active frontal side and a second conductor (220) on an opposite, back side. Successive modules in the array overlap each other such that a first conductor of one module and a second conductor of a subsequent module make contact with each other.