A versatile silicone resin reflective substrate which exhibits high reflectance of high luminance light from an LED light source over a wide wavelength from short wavelengths of approximately 340-500 nm, which include wavelengths from 380-400 nm near lower limit of the visible region, to longer wavelength in the infra-red region. The silicone resin reflective substrate has a reflective layer which contains a white inorganic filler powder dispersed in a three-dimensional cross linked silicone resin, the inorganic filler powder having a high reflective index than the silicone resin. The reflective layer is formed on a support body as a film, a solid, or a sheet. The silicone resin reflective substrate can be easily formed as a wiring substrate, a packaging case or the like, and can be manufactured at low cost and a high rate of production.

According to one embodiment, a photovoltaic cell device includes an optical waveguide including a first main surface, a second main surface opposed to the first main surface, and a side surface, an optical element opposed to the second main surface, containing cholesteric liquid crystal, and reflecting at least a part of incident light via the optical waveguide toward the optical waveguide, a photovoltaic cell opposed to the side surface, and a protective film, and the protective film is provided to be in contact with the first main surface.

Disclosed are a photovoltaic module, an integrated photovoltaic/photo-thermal module and a manufacturing method thereof. The photovoltaic module includes: a front glass plate (1), a first back plate (4), an adhesive layer (3) located between the front glass plate and the first back plate, and cell sheets (5) located in the adhesive layer. At least a hollow layer (2) is included between the front glass plate and the adhesive layer. Since the photovoltaic module and the integrated photovoltaic/photo-thermal module include the hollow layer, making the integrated photovoltaic/photo-thermal module itself has a partial heat insulation function without the need to add a front glass blocking plate or a hollow heat insulation layer directly in front of the light-receiving surface of the module, thereby simplifying the structure and manufacturing process of the integrated photovoltaic/photo-thermal module.

A flight vehicle of an embodiment includes a wing, double-side generation type solar cells, and a light reflecting part. The wing has an outer shell member. The outer shell member has transmittance. The wing is formed by an outer shell member in a hollow shape. The solar cells are disposed on the upper surface of the wing. The light reflecting part is provided on an inner surface of the outer shell member.

An embodiment of the present disclosure provides a manufacturing method of a solar cell module and a solar cell module. The manufacturing method of a solar cell module includes: providing a solar cell string; fabricating a back plate, a reserved hole being opened in the back plate; providing a front plate; arranging the solar cell string on the front plate; injecting an encapsulant material; and curing the encapsulant material, to obtain the solar cell module. The solar cell module is manufactured by directly curing the injected encapsulant material and no lamination process is performed, which can avoid defects such as hidden cracks of solar cells and breakage of the welding strip caused by the lamination process, which can reduce an amount of the encapsulant material used, reduce a distance between the back plate and the solar cell string and improve the energy conversion efficiency.

A back contact solar cell string includes: at least two cell pieces, where each cell piece comprises positive electrode regions and negative electrode regions alternately disposed with each other; insulation layers, covering the positive electrode regions on one side of the cell piece and the negative electrode regions on another side of the cell piece; and a first bus bar, connected to two adjacent cell pieces and electrically connected to the positive electrode regions and the negative electrode regions in the two adjacent cell pieces that are not covered by the insulation layers.

A method of passive cooling for a high concentrating photovoltaic, the high concentrating photovoltaic, includes a photovoltaic receiver, a parabolic dish reflector and a plurality of thermally conductive heat pipes having a direct thermal contact between the receiver and the reflector to transfer excessive heat. The method includes receiving sunlight by the parabolic dish reflector, reflecting the sunlight towards the photovoltaic receiver that converts the sunlight into electricity and heat, transferring the heat through the thermally conductive heat pipes and absorbing the heat by the reflector serving a dual purpose as a heat sink. A reduction in weight and cost is accomplished by incorporating the flat heat pipes.

An optomechanical system for absorbing light or emitting light, comprising as static frame element, an optical arrangement, a light absorbing/emitting substrate and a shifting mechanism. The shifting mechanism moves at least one layer of the optical arrangement relative to the light absorbing/emitting substrate or vice versa, wherein the movement is through one or more translation element relative to the static frame element in such a way that the transmitted light can be optimally absorbed by the light absorbing/emitting substrate, or that the incident light emitted by the light absorbing/emitting substrate can be optimally transmitted by the optical arrangement. Furthermore, the present invention also relates to a corresponding method for absorbing light or emitting light with the aforementioned optomechanical system.

Provided are a photovoltaic module, comprising a solar cell string having a plurality of solar cells arranged in sequence, adjacent solar cells being connected by solder strips, the solder strip being connected to a front surface of one solar cell and to a back surface of the other solar cell, a long-side dimension of the solar cell being within a range of 150 mm to 220 mm; two protective adhesive layers respectively covering front and back surfaces of the solar cell string, a dimensional difference between thicknesses of one protective adhesive layer and the solder strip being defined as first thickness, a ratio of the first thickness to the thickness of one protective adhesive layer being not less than 0 and not greater than 20%; a transparent plate covering the protective adhesive layer on the front surface; and a back plate covering the protective adhesive layer on the back surface.

The present inventive concept relates to a thermal radiation body for cooling a heating element, which includes a pattern unit including a pore part provided as an empty space or filled with a gas phase and a cover part covering the pore part and dissipates heat of the heating element through heat radiation.