A photovoltaic module and a method for manufacturing the same are provided. The photovoltaic module includes a plurality of cell strings; a first encapsulating adhesive film and a second encapsulating adhesive film, where the photovoltaic module has a central region and a peripheral region, where the first encapsulating adhesive film defines at least one first hole and the second encapsulating adhesive film defines at least one second hole, and each first hole directly faces a corresponding second hole; and at least one filling structure, where the at least one filling structure includes a material having a crosslinking curing speed that is faster than a crosslinking curing speed of a material in the first encapsulating adhesive film and is faster than a crosslinking curing speed of a material in the second encapsulating adhesive film.

A resin composition for a solar cell encapsulant that is used for forming a solar cell encapsulant, the resin composition including at least one kind of ethylene-polar monomer copolymer (A1) selected from an ethylene-vinyl ester copolymer and an ethylene-unsaturated carboxylic acid ester copolymer, an epoxy group-containing ethylene-based copolymer (A2) (excluding the ethylene-polar monomer copolymer (A1)), an ethylene-α-olefin copolymer (B), and a metal inactivating agent (C).

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.

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.

A method for manufacturing a flexible photovoltaic panel to be fixed to a double curvature support surface is provided. The method includes generating a numerical model of a flat structure that is curved to conform to the double curvature support structure, identifying, in the flat structure, compression zones subject to formation of creases or lifting as a result of a curvature imposed by the double curvature support surface, determining a pattern of photovoltaic cells to be arranged on the flat structure, producing a flat photovoltaic panel on the basis of the pattern of photovoltaic cells, and forming cut-outs in the compression zones, the cut-outs being configured to close as a result of the curvature imposed by the double curvature support surface.

A method for manufacturing a flexible photovoltaic panel to be fixed to a double curvature support surface is provided. The method includes generating a numerical model of a flat structure that is curved to conform to the double curvature support structure, identifying, in the flat structure, compression zones subject to formation of creases or lifting as a result of a curvature imposed by the double curvature support surface, determining a pattern of photovoltaic cells to be arranged on the flat structure, producing a flat photovoltaic panel on the basis of the pattern of photovoltaic cells, and forming cut-outs in the compression zones, the cut-outs being configured to close as a result of the curvature imposed by the double curvature support surface.

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 solar panel cutting unit according to an embodiment can separate layers of a solar panel from each other at once. The solar panel cutting unit separates thin layers of a solar panel from each other and includes a frame, a panel transporting mechanism that is provided at the frame and lowers the solar panel in a vertical direction such that adhesion lines of the thin layers are arranged downward, a pair of guide roller units that is positioned below the panel transporting mechanism and guides and lowers the solar panel, and a wire cutting mechanism that includes a pair of support rollers and cutting wires which connect the support rollers to each other and extend in the same direction as the adhesion lines such that the wire cutting mechanism separates the thin layers of the solar panel from each other.

A solar cell module includes an upper substrate, a lower substrate opposite the upper substrate, a solar cell panel positioned between the upper substrate and the lower substrate, the solar cell panel including a plurality of solar cells which are arranged in a matrix form and are connected to one another through a wiring member, a passivation layer configured to package the solar cell panel, a frame configured to surround an outer perimeter of the solar cell panel, a connection terminal configured to connect two adjacent strings in the solar cell panel, and a cover member configured to cover the connection terminal.

A solar cell module includes an upper substrate, a lower substrate opposite the upper substrate, a solar cell panel positioned between the upper substrate and the lower substrate, the solar cell panel including a plurality of solar cells which are arranged in a matrix form and are connected to one another through a wiring member, a passivation layer configured to package the solar cell panel, a frame configured to surround an outer perimeter of the solar cell panel, a connection terminal configured to connect two adjacent strings in the solar cell panel, and a cover member configured to cover the connection terminal.