An inflatable divergent Fresnel lens and non-imaging CPC based non-tracking high concentration ratio solar concentrator system comprises a flexible domed divergent Fresnel lens, and an inflatable non-imaging CPC concentrator with a domed transparent top cover and a flat transparent bottom cover. Where, the flexible domed divergent Fresnel lens is attached onto the said domed transparent cover of the said inflatable non-imaging CPC concentrator. When in operation, the oblique incident sunlight including beam light and diffuse light onto the domed divergent Fresnel lens, is deflected to change its direction, and consequently change its original incident angle relative to the said CPC concentrator from large to small, then eventually fall in the acceptance half-angle to be concentrated by the said CPC in large concentration ratio.

A method is provided for using asymmetrically focused photovoltaic conversion in a hybrid parabolic trough solar power system. Light rays received in a plurality of transverse planes are concentrated towards a primary linear focus in an axial plane, orthogonal to the transverse planes. T band wavelengths of light are transmitted to the primary linear focus, while R band wavelengths of light are reflected towards a secondary linear focus in the axial plane. The light received at the primary linear focus is translated into thermal energy. The light received at the secondary linear focus is asymmetrically focused along a plurality of tertiary linear foci, orthogonal to the axial plane. The focused light in each tertiary linear focus is concentrated into a plurality of receiving areas and translated into electrical energy. Asymmetrical optical elements are used having an optical input interfaces elongated along rotatable axes, orthogonal to the axial plane.

The invention relates to a semiconductor structure made of a substrate and a semiconductor layer which are bonded integrally to each other via a thermally and/or chemically cured adhesive. Likewise, the invention relates to a method for the production of such integral bonds. Use in such semiconductor structures, in particular as solar cell or solar cell module.

Provided herein is a solar energy light collecting device, which includes a light reflection module, a sun tracking module, and a control module. The light reflection module includes reflection units, reflection unit support beams and a support wheel frame assembly. The sun tracking module includes an angle adjustment set, a height adjustment set, and a supporter set. The control module includes a sense control unit and a driving motor. The sense control unit senses the direction of the sunlight and controls the driving motor to drive the sun tracking module, such that the light reflection module faces the direction of the sunlight. Moreover, an additional balance adjustment module can also be adopted to resolve the spatial disposition problem.

A method of manufacturing a solar cell module includes: placing a light reflection member across a gap between adjacent two solar cells set on a work table; and attaching the light reflection member to respective ends of the adjacent two solar cells, by thermocompression-bonding respective overlap regions of the light reflection member with the adjacent two solar cells using a compression bonding head that includes: a first thermocompression bonding portion and a second thermocompression bonding portion each having a contact surface that comes into contact with the light reflection member; and a non-thermocompression bonding portion interposed between the first thermocompression bonding portion and the second thermocompression bonding portion and not thermocompression-bonding the light reflection member.

A light concentrator includes a luminescent concentrator and a gain medium. The luminescent concentrator includes a semiconductor material and the semiconductor material absorbs first photons. The first photons have energy greater than or equal to a threshold energy, and the semiconductor material emits second photons through a spontaneous emission process where the second photons have less energy than the first photons. The gain medium is optically coupled to the luminescent concentrator to receive the second photons. The gain medium absorbs the second photons, and in response to absorbing the second photons, the gain medium emits third photons through a stimulated emission process. The third photons have less energy than the second photons.

A solar panel assembly according to an example of the present disclosure includes a light-permeable panel, an opaque or solid region on the panel that at least partially blocks light from penetration through the panel, at least one solar array adjacent the panel, and at least one mirror situated such that at least some light permeating through the panel reflects off of the at least one mirror and onto the at least one solar array.

It is an object of the present invention to easily and inexpensively provide a structure of effectively utilizing a light incident on an invalid area of a solar cell. Moreover, it is another object to improve output characteristics of the solar cell by effectively utilizing the light. The gist of the present invention resides in a solar battery module in which plate-like solar cells are held between a light penetrable sheet member on a light receiving surface side and a sheet member on a back surface side, and internal apertures are filled. with a sealing resin, wherein a light diffusion section for diffusely reflecting a light or a light diffusion section of a white color is arranged in an invalid region of each solar cell.

A solar concentrator device comprising a solar concentrator element comprising a radiation transmissive surface, a radiation absorptive material and a radiation concentrating/collection point and disposed on the incident radiation side thereof a recapture element for recapturing at least a portion of radiation lost from the concentrator element has improved solar radiation collection efficiency by reintroducing recaptured radiation into the concentrator element or by propagating said recaptured radiation through the recapture element to a radiation concentration point associated with the recapture element. It has been found that planar elements having a grooved or corrugated outer surface make for very good recapture elements for planar concentrator elements.

A solar cell module, a solar cell module assembly, and a solar photovoltaic power generation system capable of reducing power loss are provided. A light-concentrating panel configured to collect light which is incident from the outside and a plurality of solar cell elements installed on the light-concentrating panel and configured to receive light which is collected by the light-concentrating panel are provided. Each of the plurality of solar cell elements is provided with a positive terminal and a negative terminal. The plurality of solar cell elements include a first solar cell element and a second solar cell element which are connected to each other in series via connection wiring and a third solar cell element which is not connected to the first solar cell element and the second solar cell element in series. The first solar cell element and the second solar cell element configure a first current path, and the third solar cell element configures a second current path.