A hybrid photovoltaic (PV) device includes: a rigid PV segment, having one or more PV cells that convert light to electricity, wherein the rigid PV segment is non-foldable and non-bendable; a co-located flexible PV segment, wherein the flexible PV segment is foldable or bendable without being damaged; electric connectors, that connect between (i) electric current or voltage generated by the rigid PV segment, and (ii) electric current or voltage generated by the flexible PV segment; a unified encapsulation layer, encapsulating together both the rigid PV segment and the co-located flexible PV segment. The rigid PV segment, the co-located flexible PV segment, the electric connectors, and the unified encapsulation layer, form together the hybrid PV device as a single stand-alone PV device that converts light to electricity, and has at least one rigid region corresponding to the rigid PV segment and at least one flexible region corresponding to the co-located flexible PV segment.

The present invention relates to a composition for an encapsulant film including an ethylene/alpha-olefin copolymer having high volume resistance and light transmittance, and an encapsulant film using the same.

A first plurality of roofing shingles installed in a first plurality of rows on a roof deck, and a second plurality of roofing shingles installed in a second plurality of rows. An edge of one of the second roofing shingles in each of the second rows is offset from the edge of another one of the second roofing shingles in another adjacent one of the second rows. An edge of a first photovoltaic shingle is juxtaposed with the edge of a first roofing shingle of the second roofing shingles in a first row of the second rows. The edge of at least another photovoltaic shingle in at least one of another row of the second rows is substantially aligned with the edge of the first photovoltaic shingle. An additional roofing shingle is installed intermediate one of the second roofing shingles and one of the photovoltaic shingles.

A portable solar photovoltaic (PV) electricity generator module comprises a plurality of smart power slat (SPS) units, each SPS unit comprising a plurality of solar cells electrically connected together based on a specified cell interconnection design, and, N at least one power maximizing integrated circuit collecting electricity generated by the plurality of solar cells. The plurality of SPS units are mechanically connected such that the SPS units can be retracted for volume compaction of the module, and can be expanded for increasing PV electricity generation by the module. The module can be used as part of an electric power supply with a maximum power point tracking (MPPT) power optimizer, storage battery and leads to connect to a load. The load can be AC or DC.

The present invention relates to a polymer composition (I) comprising at least the following components: (A) 87.00 to 99.79 wt.-% based on the overall weight of the polymer composition (I) of a specific polymer, (B) 0.20 to 10 wt.-% based on the overall weight of the polymer composition (I) of a specific copolymer of ethylene and (C) 0.01 to 3.00 wt.-% based on the overall weight of the polymer composition (I) of a compound according to Formula (a), whereby components (A), (B) and (C) add up to 100 wt.-%. In addition, the present invention refers to a photovoltaic module comprising at least one layer comprising polymer composition (I), to a method for improving the storage stability and/or transport stability of polymer (A) and to the use of components (B) and (C) for improving the storage stability and/or transport stability of a polymer (A).

Provided are a lightweight solar power generation panel and a method of preparing the same. The lightweight solar power generation panel comprises a substrate, an insulating layer, a cell layer and a support layer which are stacked in sequence; a material of the substrate comprises any one or a combination of at least two of polypropylene, polyvinyl chloride, polyethylene, polymethyl methacrylate, polycarbonate, polystyrene or an acrylonitrile-butadiene-styrene copolymer. The low-density substrate material is used in the lightweight solar power generation panel provided by the present disclosure so that the entire solar power generation panel is lighter and portable.

To provide a coating material capable of forming a solar cell module excellent in the weather resistance, the power generation efficiency and the design, a cover glass, a solar cell module comprising the cover glass, and an outer wall material for building. The cover glass of the present invention is a cover glass comprising a glass plate and a layer containing a fluorinated polymer having units based on a fluoroolefin, on at least one surface of the glass plate, which has an average visible reflectance of from 10 to 100%, and an average near infrared transmittance of from 20 to 100%.

A photovoltaic module includes at least one solar cell, an encapsulant encapsulating the at least one solar cell, a frontsheet juxtaposed with the encapsulant, and backsheet juxtaposed with the encapsulant. The frontsheet includes a glass layer, a polymer layer attached to the glass layer, and an adhesive layer attaching the polymer layer to the glass layer. The backsheet includes a single-layer, moisture-resistant, fire-retardant membrane.

A photovoltaic module having a superstrate layer, an encapsulant having an upper layer and a lower layer, the upper layer being juxtaposed with a lower surface of the superstrate layer, and a photovoltaic layer intermediate the upper layer and the lower layer of the encapsulant. A first portion of the upper layer of the encapsulant includes a first light scattering value as measured in accordance with an ASTM E430 standard, and a second portion of the upper layer of the encapsulant has a second light scattering value as measured in accordance with the ASTM E430 standard. The second light scattering value is greater than the first light scattering value.

The present disclosure discloses a solar module, including solar cells, each solar cell includes a front surface and a rear surface arranged opposite to each other. The solar cell includes a semiconductor substrate and busbars located on one side of the semiconductor substrate, first electrode pads are provided at the busbars, a number of the first electrode pads ranges from 6 to 12. The solar module includes an electrode line with one end connected to the first electrode pads of the busbars on front surface of the solar cell and the other end connected to the first electrode pads of the busbars on rear surface of the adjacent solar cell. A relation between a diameter of the electrode line and a number of the busbars is 116.55x.sup.2−92.03x+27.35<y<582.75x.sup.2−425.59x+92.58, x denotes the diameter of the electrode line, and y denotes the number of the busbars.