A copolymer, a method of manufacturing a copolymer, an encapsulant for optoelectronic devices, and an optoelectronic device are provided. The encapsulant exhibiting excellent adhesion to front substrates and back sheets included in various optoelectronic devices can be provided. Also, the encapsulant capable of maintaining excellent workability and economic feasibility upon manufacture of the device without causing a negative influence on working environments and parts such as optoelectronic elements or wiring electrodes encapsulated in the optoelectronic device can be provided.

A method of bonding solar cell component to a support and the solar cell assembly thus obtained. The method of bonding solar cell component to a support comprises: disposing metallized traces on the support; dispensing bonding adhesive on front of the support or on back of the solar cell component; and laying down the solar cell component on the support and soldering the solar cell component to the metallized traces on the support. The support is a glass support with integrated circuits.

In one embodiment, harmful solar cell polarization is prevented or minimized by providing a conductive path that bleeds charge from a front side of a solar cell to the bulk of a wafer. The conductive path may include patterned holes in a dielectric passivation layer, a conductive anti-reflective coating, or layers of conductive material formed on the top or bottom surface of an anti-reflective coating, for example. Harmful solar cell polarization may also be prevented by biasing a region of a solar cell module on the front side of the solar cell.

Disclosed are optically transparent super-hydrophobic materials, and methods for making and using the same, that can include an optically transparent polymeric layer having a first surface and an opposing second surface. At least a portion of the first surface has been plasma-treated with oxygen and a fluorine containing compound. The treated surface includes nano- or micro-structures that are etched into the first surface and that are chemically modified with the fluorine containing compound. The nano- or micro-structures have a height to width aspect ratio of greater than 1, and a water contact angle of at least 150. The optically transparent polymeric layer retains its optical transparency after said plasma-treatment. Due to their optical transparency, chemical and thermal robustness, weatherability, and self-cleaning performance, the super-hydrophobic materials disclosed are useful in high performing solar cell units in harsh semi-arid environments.

A vehicle part with at least one integrated photovoltaic element includes a part body, at least one area of a barrier layer disposed on at least a portion of the surface of the part body; and at least one photovoltaic element disposed over an area of the barrier layer. Paint covers the portions of the surface of the part body surrounding the photovoltaic elements. A method of making a vehicle part having at least one integrated photovoltaic element includes applying at least one area of a barrier layer on at least a portion of the surface of the part and applying at least one photovoltaic element over an area of the barrier layer. A protective layer is applied over the surface of the photovoltaic element, the surface of the part is painted, and the protective layer can then be removed to expose the photovoltaic element.

Presently described are methods of making coating comprising aqueous fluoropolymer latex dispersions, aqueous fluoropolymer coating compositions, coated substrates, and (e.g. backside) films of photovoltaic cells. In one embodiment, the film comprises at least one fluoropolymer comprising repeat units derived from VF, VDF, or a combination thereof; inorganic oxide nanoparticles; and a compound that reacts with the repeat units derived from VF and VDF to crosslink the fluoropolymer and/or couple the fluoropolymer to the inorganic oxide nanoparticles. In another embodiment, the backside film comprises at least one fluoropolymer comprising repeat units derived from VF, VDF, or a combination thereof; and an amino-substituted organosilane ester or ester equivalent crosslinking compound.

Provided is a flexible printed circuit including: a film-shaped insulating base material having flexibility and having a withstand voltage value of at least 2000 V; and an electric conductor layer formed on the insulating base material and forming a circuit pattern, wherein with respect to the insulating base material, a principal component thereof is a polyimide and a filler content thereof is 0%. Thus, a flexible printed circuit can be obtained that has an insulating base material which suppresses decrease in withstand voltage performance even in a high humidity environment.

In one embodiment, harmful solar cell polarization is prevented or minimized by providing a conductive path that bleeds charge from a front side of a solar cell to the bulk of a wafer. The conductive path may include patterned holes in a dielectric passivation layer, a conductive anti-reflective coating, or layers of conductive material formed on the top or bottom surface of an anti-reflective coating, for example. Harmful solar cell polarization may also be prevented by biasing a region of a solar cell module on the front side of the solar cell.

A method for manufacturing a solar cell module that includes a solar cell based on a semiconductor substrate with front and rear surfaces, includesfabricating a solar cell from the substrate, anddepositing on at least the rear surface a coating layer.

The deposition step includes applying a coating powder on at least the rear surface, forming an adhered powder layer on said surface.

The method includes after the deposition step: performing a first annealing process on the solar cell module for transforming the adhered powder layer in a pre-annealed coating layer.

Further the method includescreating open contacting areas on the solar cell by removal of the adhered powder layer at locations of contacting areas on the solar cell , wherein the removal precedes the first annealing process, or by masking contacting areas on the solar cell 1, wherein the masking precedes the deposition step.

The invention relates to a photovoltaic module comprising (a) a front layer (1) arranged on the sunlight facing side of the photovoltaic module, wherein the front layer (1) comprises a first polypropylene composition, comprising a polypropylene, wherein the transmission of the front layer for light in the wavelength range of 350 nm to 1200 nm is on average at least 65% as compared to a situation without the front layer as determined according to ASTM D1003-13, (b) a sealing layer (2,4) which at least partly encapsulates a plurality of photovoltaic cells (3), wherein the sealing layer (2, 4) comprises a polyolefin elastomer composition comprising an ethylene--olefin copolymer and (c) a back layer (5), wherein the back layer (5) comprises a first reinforced polypropylene layer comprising a second polypropylene composition comprising a polypropylene and optionally a reinforcing filler, wherein the sealing layer is arranged between the front layer and the back layer.