A semiconductor module includes a light emitting element, a semiconductor element including a light receptor circuit disposed to receive light from the light emitting element, a light-transmissive insulating body disposed between the light emitting element and the semiconductor element, at least one of a first surface thereof facing the semiconductor element and a second surface thereof facing the light emitting element including a ragged region, a first light-transmissive bonding resin formed between the light emitting element and the light-transmissive insulating body, and a second light-transmissive bonding resin formed between the semiconductor element and the light-transmissive insulating body.

An EVA sheet for a photovoltaic module comprising microparticles, the main component of which is an ethylene-vinyl acetate resin is provided. A method for manufacturing an EVA sheet for a photovoltaic module comprising the steps of: (a) preparing microparticles, the main component of which is an ethylene-vinyl acetate resin; (b) dispersing the microparticles; and (c) sintering the dispersed microparticles is provided.

A photovoltaic module comprises a plurality of photovoltaic cells, and a polymeric film positioned on an incident light side of the plurality of photovoltaic cells, wherein the polymeric film transmits a range of wavelengths of the incident light spectrum and specularly reflects wavelengths outside of the range. An encapsulant layer is in contact with the polymeric film. The polymeric film may have a first surface area larger than a second surface area of the layer of photovoltaic cells. The polymeric film may have one or more through-holes so that encapsulant can penetrate through the through-holes at elevated temperature during lamination thereby bonding to a front glass of the photovoltaic module.

The present invention relates to a backsheet for photovoltaic modules comprising a polymeric layer comprising an aliphatic polyamide comprising 1,10-decanedioic acid. Examples of such aliphatic polyamides are polyamide 4,10, polyamide 5,10 or polyamide 6,10. Preferably polyamide 4,10 is present in the rear layer of the backsheet. A polyolefin layer is preferably present in the core layer of the backsheet. It is however also possible that the polyamide is present in the core layer and polyolefin is present in the rear layer of the backsheet. The polyolefin is preferably chosen from the group consisting of polyethylene, polypropylene or ethylene-propylene copolymers. More preferably the polyolefin is polypropylene. The backsheet preferably comprises at least a further polymeric layer comprising a polymer selected from the group consisting of an optionally functionalized polyolefin such as a maleic anhydride functionalized polypropylene homo or copolymer. The present invention further relates to a photovoltaic module containing essentially, in order of position from the front-sun facing side to the back non-sun-facing side, a transparent pane, a front encapsulant layer, a solar cell layer comprised of one or more electrically interconnected solar cells, a back encapsulant layer and the back-sheet according to the present invention.

Disclosed is a multilayer coating for a substrate such as a photovoltaic module or cell having flame retardant capability, the coating comprising two or more carrier or polymer layers, wherein at least one layer of the two or more carrier or polymer layers is a layer comprising a halogenated material and at least one other layer of the two or more carrier or polymer layers comprises at least one synergist. Also disclosed are substrates coated with the coating, a method of coating a substrate, and a method of manufacturing the coating.

An object of the present invention is to provide a luminescent ethylene-based copolymer which causes no problem of the shift or bleeding-out of a fluorescent body, which has a high workability, desired optical properties and a good light stability and which is easily handled in a kneading step; and a encapsulant composition for a solar cell, using this copolymer. Another object of the invention is to provide a encapsulant layer, for a solar cell, which is formed using the photovoltaic encapsulant composition to cause no problem of the shift or bleeding-out of a fluorescent body in this layer and to have desired optical properties and a good light stability; and a photoelectromotive module having this layer. The copolymer is a luminescent ethylene-based copolymer including, as a monomer component, a fluorescent dye compound having an unsaturated bond.

A photovoltaic panel support and system comprising a cross-linked closed cell foam structure and one or more photovoltaic panels is coupled to the cross-linked closed cell foam structure, is disclosed.

The present disclosure relates to a curable composition for an encapsulant film, the curable composition comprising: (A) a polyolefin; (B) a fumed alumina; (C) an organic peroxide; (D) a silane coupling agent; (E) a crosslinking co-agent; and, optionally, (F) an additive component comprising a UV stabilizer, wherein the polyolefin has a volume resistivity of less than 4.0E+15 ohm.Math.cm. The present disclosure further relates to an encapsulant film made from such a curable composition and a PV module containing such an encapsulant film.

One embodiment can provide a photovoltaic roof tile. The photovoltaic roof tile can include a transparent front cover, a back cover, a plurality of photovoltaic structures positioned between the front cover and the back cover, and a front-cover-colorant layer positioned on an interior surface of the transparent front cover that faces a top surface of the photovoltaic structures. A color of the front-cover-colorant layer can substantially match a color of the top surface of the photovoltaic structures, and the front-cover-colorant layer can be configured to cover regions of the interior surface that are not directly above the top surface of the photovoltaic structures, thereby enabling a substantially uniform appearance of the photovoltaic roof tile.

The disclosure provides a flexible solar panel, wherein a plurality of first main grid lines are arranged on a positive electrode surface of a solar cell body and are welded to a first solder strip; a plurality of second main grid lines are arranged on a negative electrode surface of the solar cell body and are welded to a second solder strip; a copper mesh is formed by a plurality of copper wires crossed transversely and vertically, and the copper mesh is composited on the positive electrode surface; a positive electrode EVA film is composited on the copper mesh; the solar cell body, the copper mesh and the positive electrode EVA film form a solar cell; a plurality of solar cells are connected in series and installed on a PCB board; a negative electrode EVA film covers the negative electrode surfaces of the solar cells.