A solar cell for a solar cell array with one or more grid on a surface thereof, wherein electrical connections are made to the grids in a plurality of locations positioned around the solar cell; and the electrical connections extend to one or more conductors located under the solar cell. The conductors located under the solar cell are buried within a substrate, and each of the conductors comprises a low resistance conducting path that distributes current from the solar cell. The conductors are loops, U-shaped, or have only up or down pathways. The solar cell comprises a full cell that has four cropped corners and the locations are in the cropped corners.

A method for producing a photovoltaic solar cell, including the method steps: A. providing at least one solar cell precursor having at least one base and at least one emitter; B. providing a metal film on a back side of the solar cell precursor, so that the metal film is electrically conductively connected to the base or the emitter, the metal film being formed as an integral component of the back side contact and the solar cell being terminated on the back side. The at least one cell connection region on at least one side of the metal film overhangs the edge of the solar cell precursor by at least 1 mm, preferably by at least 3 mm.

A photovoltaic device is described, the device comprising a transparent conducting electrode layer; a back contact layer comprising at least one MXene material; and an active layer, comprising a photovoltaic active material, disposed between the transparent conducting electrode layer and the back contact layer. Also described is a method of producing a photovoltaic device, the method comprising the steps of providing substrate, depositing a transparent conducting electrode over the substrate; depositing an active layer comprising a photovoltaic material over the transparent conducting electrode; and depositing an MXene layer material over the active layer. A method of generating electricity using the disclosed device is also described.

A solar power system may comprise a back sheet that comprises an interconnect circuit coupling a plurality of cell tiles. A tiled solar cell, comprising a solar cell and encapsulating and glass layers, is inserted into the cell tiles of the back sheet. Each solar cell is individually addressable through the use of the interconnect circuit. Moreover, the interconnect circuit of the back sheet is programmable and allows for dynamic interconnect routing between solar cells.

A photovoltaic device including: a first amorphous semiconductor layer (3) and a second amorphous semiconductor layer (4) both on a back face of a semiconductor substrate (1); electrodes (5, 6); and a wiring board (8). The electrodes (5, 6) are disposed on the first amorphous semiconductor layer (3) and the second amorphous semiconductor layer (4) respectively. The wiring board (8) has wires (82) connected to the electrodes (5) by a conductive adhesive layer (7). The wiring board (8) has wires (83) connected to the electrodes (5) by the conductive adhesive layer (7). The electrodes (5) include conductive layers (51, 52). The electrodes (6) include conductive layers (61, 62). The conductive layers (51, 61) are composed primarily of silver. The conductive layers (52, 62) cover the conductive layers (51, 52) respectively. Each conductive layer (52, 62) is composed of a metal more likely to be oxidized than silver.

Discussed is a solar cell including a semiconductor substrate, a conductive region disposed in the semiconductor substrate or over the semiconductor substrate, and an electrode electrically connected to the conductive region. The electrode includes a first electrode part and a second electrode part disposed over the first electrode part. The second electrode part includes a particle connection layer formed by connecting a plurality of particles including a first metal and a cover layer including a second metal different from the first metal and covering at least the outside surface of the particle connection layer.

Discussed is a solar cell including a semiconductor substrate having an inclined part; first and second conductivity type regions formed at or on one surface of the semiconductor substrate; a first electrode connected to the first conductivity type region on the one surface of the semiconductor substrate; and a second electrode connected to the second conductivity type region on the one surface of the semiconductor substrate. At least one of the first and second electrodes includes a finger part including a plurality of inner finger parts extending in a first direction, and a plurality of outer finger parts extending in the first direction adjacent to an edge of the semiconductor substrate; and a connection part connecting at least some of the plurality of outer finger parts on one side of the semiconductor substrate adjacent to the inclined part.

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.

A solar battery according to the present embodiment has an electrode, which includes a metal and an adhesive material, formed in a conductive region including a polycrystalline semiconductor layer, and thus, the electrical characteristics of the solar battery may be improved and the manufacturing process thereof may be simplified. More specifically, the solar battery includes a semiconductor substrate, and the conductive region including the polycrystalline semiconductor layer is positioned on one surface of the semiconductor substrate.