A solar cell panel can include a plurality of solar cells; and a diode member connected to the plurality of solar cells, the diode member being formed of a solar cell unit disposed within the solar cell panel under at least a portion of one of the plurality of solar cells at a non-light-incident region.

Photoelectric window blinds, which consist of a plurality of elongated lamellas, which are arranged in parallel and connected between each other by at least two stripes, equipped with a drive for their assembling, disassembling and changing an inclination angle, on which solar panels are mounted, the panels being connected between each other and equipped with a means for transmission of an obtained electric energy to external networks or to a means for storage. According to the invention, each solar panel is formed by at least two sections of solar elements, which are arranged on a base made of an electrically insulating material and covered by a temperature and moisture stable layer, coupled to each other and by a means for electrical connection embedded therein, and it is configured to receive at least one additional section. An edge section of each solar panel is equipped with a means for transformation of an output power, the means being a DC/DC transformer or a Schotky diode embedded into the base made of the electrically insulating material from a side of the panel faced towards the lamella, and coupled to a shared bus that is connected to a DC-to-AC current transformer. Therewith, a cross-section profile of the lamellas has a C-shape with curved edges, which form guides for mounting the solar panels in a longitudinal direction, wherein a distance between edges of the sections of the solar elements of the solar panel and edges of the electrically insulating base equals to a width of the edges of the lamella guides.

This method for manufacturing a solar cell module comprises a step for applying an adhesive to a first adhesion region so that the first adhesion region and a second adhesion region are disposed alternately on a light receiving surface of a solar cell along a first direction, and a step for arranging a light receiving surface-side wiring material along the first direction on the light receiving surface side of the solar cell to which the adhesive has been applied. The step for arranging the light receiving surface-side wiring material comprises arranging the light receiving surface-side wiring material, in the first adhesion region and the second adhesion region of the solar cell so that, in a state in which a first holder is in contact with the holding region of the light receiving surface-side wiring material, the second adhesion region and the holding region overlap each other.

This method for manufacturing a solar cell module comprises a step for applying an adhesive to a first adhesion region so that the first adhesion region and a second adhesion region are disposed alternately on a light receiving surface of a solar cell along a first direction, and a step for arranging a light receiving surface-side wiring material along the first direction on the light receiving surface side of the solar cell to which the adhesive has been applied. The step for arranging the light receiving surface-side wiring material comprises arranging the light receiving surface-side wiring material, in the first adhesion region and the second adhesion region of the solar cell so that, in a state in which a first holder is in contact with the holding region of the light receiving surface-side wiring material, the second adhesion region and the holding region overlap each other.

A solar cell structure is disclosed that includes a first metal layer, formed over predefined portions of a sun-exposed major surface of a semiconductor structure, that form electrical gridlines of the solar cell; a network of carbon nanotubes formed over the first metal layer; and a second metal layer formed onto the network of carbon nanotubes, wherein the second metal layer infiltrates the network of carbon nanotubes to connect with the first metal layer to form a first metal matrix composite comprising a metal matrix and a carbon nanotube reinforcement, wherein the second metal layer is an electrically conductive layer in which the carbon nanotube reinforcement is embedded in and bonded to the metal matrix, and the first metal matrix composite provides enhanced mechanical support as well as enhanced or equal electrical conductivity for the electrical contacts against applied mechanical stressors to the electrical contacts.

This specification describes automated reel processes for producing solar modules and solar module reels. In some examples, a method includes receiving a continuous feed of photovoltaic devices on a photovoltaic device sheet. The method includes locating and bypassing one or more defective photovoltaic devices on the photovoltaic device sheet. The method includes installing bussing for the photovoltaic devices on the photovoltaic device sheet. The method includes feeding the photovoltaic device sheet to an encapsulation system to output a photovoltaic module sheet.

A special-figure design ribbon for connecting back contact cells includes a body, a plurality of first solder joints, and a plurality of second solder joints. The plurality of first solder joints and the plurality of second solder joints are respectively located on two sides of the body in a width direction. Each of the first solder joints stretches outward from a first side of the body. Each of the second solder joints stretches outward from a second side of the body. A shape of each first solder joint is different from a shape of each second solder joint. Center lines of at least one set of the first solder joint and the second solder joint adjacent to each other are staggered from each other in the width direction of the body.

The present disclosure provides a support device for conveying at least one solar cell element in a transport direction, wherein the support device comprises a support element configured for supporting the at least one solar cell element and an electric arrangement configured for providing an electrostatic force for holding the at least one solar cell element on the support element.

An intermediate series-connecting layer, a laminated photovoltaic device and a fabricating method are provided. The intermediate series-connecting layer is light-transmittable; the intermediate series-connecting layer includes a longitudinal conducting layer; and the longitudinal conducting layer is formed by nano-sized conducting columns that longitudinally grow; or the longitudinal conducting layer includes nano-sized conducting units that are separately distributed, and insulating and separating bodies located between neighboring the nano-sized conducting units, and the insulating and separating bodies transversely insulate the nano-sized conducting units. A large quantity of grain boundaries or interfaces are located between the nano-sized conducting columns, and have a poor transverse conducting performance, the longitudinal conducting layer has a poor transverse conducting capacity, the charge carriers are mainly longitudinally transmitted, and there is substantially no transverse current. Alternatively, the nano-sized conducting units are insulated by the insulating grids in the transverse direction.

A photovoltaic device including a photovoltaic cell and method of use is disclosed. The photovoltaic cell includes at least a first photovoltaic layer and a second photovoltaic layer arranged in a stack. The first photovoltaic layer has a first thickness and receives light at its top surface. A second photovoltaic layer has a second thickness and is disposed beneath the first photovoltaic layer and receives light passing through the first photovoltaic layer. The first thickness and the second thickness are selected so that a first light absorption at the first photovoltaic layer is equal to a second light absorption at the second photovoltaic layer. The photovoltaic cell is irradiated at its top surface with monochromatic light to generate a current.