The invention to a method of making an interconnector assembly for electrically interconnecting solar cells, wherein the method comprises: feeding a plurality of (preferably elongated) electrical conductors that form an conductor array defining interspaces that are free from conductors; and applying at least one sheet, preferably made of electrically insulating material, to a side of the conductor array, wherein the sheet has at least one contact zone coming into contact with the conductors and intermediate portions overlapping with the interspaces of the conductor array. The invention also refers to an apparatus for fabricating an interconnector assembly for electrically interconnecting solar cells and to a rotatable heating drum.

Provided is a device and method for repairing photovoltaic cell string. The device for repairing photovoltaic cell string includes: a conveying device and a baking device. The conveying device is configured to drive a photovoltaic cell string placed on the conveying device to reciprocate along a first direction. The conveying device includes a first conveying component, a second conveying component and a third conveying component separately arranged. The baking device is arranged toward the second conveying component. The baking device is configured to heat the photovoltaic cell string located on the second conveying component, so that a protruding solder strip of a solar cell on the photovoltaic cell string is separated or fused at its connecting part.

Embodiments of the present disclosure provide a solar cell string, a solar cell module, a manufacturing apparatus and a manufacturing method thereof. The solar cell string includes at least two solar cells including first and second solar cells adjacent to each other; front and back surfaces of each of the at least two solar cells are respectively provided with a grid line, and the grid line on the front surface is connected with the grid line on the back surface by a solder strip, the first and second solar cells have an overlapping region, and the overlapping region is provided with a buffer pad covering at least one side surface of the solder strip located in the overlapping region, and the buffer pad is formed by a pad which is pre-arranged in the overlapping region and melted at high temperature.

An apparatus (100) for manufacturing a photovoltaic arrangement is provided. The photovoltaic arrangement includes a conductive tab element (30) and a plurality of overlapping solar cell pieces. The apparatus includes an assembling module (300). The assembling module is configured for assembling a partial photovoltaic arrangement including a first solar cell piece (10a) and the conductive tab element. The assembling of the partial photovoltaic arrangement includes providing the first solar cell piece and the conductive tab element in an overlapping configuration. The assembling module is configured for providing a second solar cell piece (10b) and a solar cell piece of the partial photovoltaic arrangement in an overlapping configuration. The solar cell piece of the partial photovoltaic arrangement may be the first solar cell piece or a third solar cell piece (10c). Providing the second solar cell piece and the solar cell piece of the partial photovoltaic arrangement in an overlapping configuration is performed after providing the first solar cell piece and the conductive tab element in an overlapping configuration.

Photovoltaic devices, and methods of fabricating photovoltaic devices. The photovoltaic devices may include a first electrode, at least one quantum dot layer, at least one semiconductor layer, and a second electrode. The first electrode may include a layer including Cr and one or more silver contacts.

A 12th solar cell and a 13th solar cell are provided to overlap in part as viewed from a side of a light receiving surface 22. A portion of a light receiving surface of the 12th solar cell and a portion of a back surface of the 13th solar cell face each other in an overlapping portion across a wire. The overlapping portion includes a part where a resin is located both between the light receiving surface of the 12th solar cell and the wire and between the back surface of the 13th cell and the wiring member.

A solar panel manufacturing apparatus includes a stage on which a substrate is placed, a pressing plate to press an adhesive applied on the substrate and thereby spread the adhesive via a solar cell arranged at a predetermined position on the adhesive, and to retain the position of the solar cell relative to the substrate, and a curing unit to cure only a part of the adhesive spread between the substrate and the solar cell, while the pressing plate is pressing the adhesive and retaining the position of the solar cell relative to the substrate.

A solar cell including: a substrate having front and back surfaces, the back surface includes first, second and gap regions, the first and second regions are staggered and spaced from each other in a first direction, and each gap region is provided between one first region and one second region adjacent thereto by recessing toward interior of the substrate; a first conductive layer formed over the first region; a second conductive layer formed over the second region, the second conductive layer has a conductivity type opposite to the first conductive layer; a first electrode forming electrical contact with the first conductive layer; a second electrode forming electrical contact with the second conductive layer; and a boundary region between the gap region and the first and/or second conductive layer adjacent thereto, and a line-pattern concave and convex texture structure is formed on the back surface corresponding to the boundary region.

A solar cell can include a built-in bypass diode. In one embodiment, the solar cell can include an active region disposed in or above a first portion of a substrate and a bypass diode disposed in or above a second portion of the substrate. The first and second portions of the substrate can be physically separated with a groove. A metallization structure can couple the active region to the bypass diode.

A solar cell can include a built-in bypass diode. In one embodiment, the solar cell can include an active region disposed in or above a first portion of a substrate and a bypass diode disposed in or above a second portion of the substrate. The first and second portions of the substrate can be physically separated with a groove. A metallization structure can couple the active region to the bypass diode.