An encapsulant film is made from a composition comprising (A) a non-polar ethylene-based polymer having a density of 0.850 g/cc to 0.890 g/cc; (B) an organic peroxide; (C) a silane coupling agent; and (D) a co-agent comprising triallyl phosphate.

Some embodiments of the present disclosure relate to photovoltaic module for use on a roof. In some embodiments, the photovoltaic module may include a solar cell and a polymeric continuous fiber tape. In some embodiments, the polymeric continuous fiber tape comprises a polymer and glass fiber. In some embodiments, the glass fiber is present in an amount greater than about 50% by weight based on a total weight of the polymeric continuous fiber tape. In some embodiments, the polymeric continuous fiber tape comprises an elastic modulus greater than 1 GPa and an optical transmission greater than 80%.

Disclosed is a color solar cell module including a transparent substrate, a plurality of solar cells disposed on one side of the transparent substrate and each having a light receiving part, and a color layer disposed on a surface of each of the plurality of solar cells on an opposite side surface of the light receiving part.

The present disclosure discloses a low-water-vapor-permeability polyolefin-elastomer film and its preparation method. The film comprises: 50-100 mass parts of a matrix resin, 0-40 mass parts of a modified resin, 0.001-2 mass parts of an activator, 0.1-3 mass parts of an organic peroxide, 0.02-5 mass parts of an assistant cross-linker, 0.02-2 mass parts of a silane coupling agent, 0.005-2 mass parts of a light stabilizer, and 0-20 mass parts of a water blocking filler. In the present disclosure, by adding the modified resin and the activator that have an active group, a cross-linking degree and a cross-linking density of the film are improved, and a water-vapor permeability is reduced; by adding the water blocking filler, the water blocking property of the film is further improved, thereby ensuring reliability of the assembly, and prolonging service life of the assembly.

Structured photovoltaic assemblies and method of manufacture therefor. The assemblies can be assembled similar to flex circuits and have mechanical support structures disposed within the assembly. The supports can be sized and shaped to one or a group of solar cells in the assembly. The solar cells supported by a particular support may be interconnected with cells supported by a different support. The supports can be transparent. The connection of the interconnects to the solar cells can be enhanced by forming protrusions in vias through openings in the Insulating layer that are aligned with the solar cells. Alternatively, the openings can be filled with a conductive material in such forms as powder, ink, paste, or metal nanoparticles, and a laser can be used to melt and/or sinter the material to form the connection to the solar cell. These techniques can withstand large temperature swings over a large number of cycles, which occur in, for example, space applications.

A colored solar module is provided, in which at least one solar cell is embedded in an encapsulation layer, and a transparent plate is disposed on the encapsulation layer. The transparent plate has a single coating layer containing quartz for attaching onto the encapsulation layer so as to reflect the desired color light.

Provided is a hydrosilylation reactive composition that has a sufficient pot life at room temperature, that can be cured at low temperature by exposure to high energy radiation, and that produces a stable semi-cured product during the curing process, and to provide a semi-cured product and a cured product obtained using this hydrosilylation reactive composition. The composition comprises: (A) a compound containing at least one aliphatically unsaturated monovalent hydrocarbon group in the molecule; (B) a compound containing at least two hydrogen atoms bonded to silicon atoms in the molecule; (C) a first hydrosilylation catalyst exhibiting activity in the composition without exposure to high energy radiation; and (D) a second hydrosilylation catalyst not exhibiting activity unless exposed to high energy radiation, and exhibiting activity in the composition by exposure to high energy radiation.

A method of fabricating a solar cell assembly comprising a plurality of solar cells mounted on a flexible support, the support comprising a conductive layer on the top surface thereof divided into two electrically isolated portions—a first conductive portion and a second conductive portion. Each solar cell comprises a front surface, a rear surface, and a first contact on the rear surface and a second contact on the front surface. Each one of the plurality of solar cells is placed on the first conductive portion with the first contact electrically connected to the first conductive portion so that the solar cells are connected through the first conductive portion. A second contact of each solar cell is then connected to the second conductive portion by an interconnect. The two conductive portions serve as bus bars representing contacts of two different polarities of the solar cell assembly.

A solar cell module includes a solar cell string, a first encapsulant, a second encapsulant having a viscoelasticity greater than a viscoelasticity of the first encapsulant, a front-side protective plate, and a back-side protective sheet. The solar cell string includes a plurality of solar cells and a line member which electrically connects the plurality of solar cells. The lengthwise direction of the line member is different from the maximum expansion and contraction direction of the back-side protective sheet.

A photovoltaic device includes: a silicon substrate having a front surface having a texture; and an amorphous silicon layer having an uneven surface corresponding to the texture, wherein the amorphous silicon layer is amorphous in peak portions and slope portions extending between the peak portions and valley portions of the uneven surface, and has crystalline regions which grow, in a pillar manner, approximately perpendicularly from a substrate surface of the silicon substrate in the valley portions, the crystalline regions being discretely present along upper ends of the valley portions, the upper ends being opposite lower ends of the valley portions, the lower ends being in contact with the silicon substrate, wherein coverage of the crystalline regions in the valley portions is higher than coverage of amorphous regions in the valley portions.