The invention relates to an apparatus, system and method for a two-axis of curvature solar panel with doubly-curved solar cells. The solar panel comprises substrate and superstrate preforms having two-axis of curvature geometry and at least one rigid layer. The preforms may comprise one or more strengthened glass and/or polymer layers. A core comprising lower and upper encapsulant layers sandwiching a solar cell array is disposed between substrate and superstrate preforms forming a lamination stack. The solar cells may be tacked to the lower encapsulant layer. The preforms may be formed by flat lamination followed by thermoforming. The curved solar panel may comprise a flange suitable for assisting the assembly process and be made of materials with disparate mechanical and thermal properties. Aspects of the solar cells are recited that provide for the enabling double bendability of the cells within a doubly curved solar panel.

A semiconductor substrate, including a back surface having N-type conductive regions and P-type conductive regions. The N-type conductive regions are provided with first non-pyramidal texture structures, and the P-type conductive regions are provided with second non-pyramidal texture structures. A top surface of the first non-pyramidal texture structure is a polygonal plane, and a top surface of the second non-pyramidal texture structure is a polygonal plane. A one-dimensional size of the top surface of the first non-pyramidal texture structure is less than a one-dimensional size of the top surface of the second non-pyramidal texture structure. The one-dimensional size of the top surface of the first non-pyramidal texture structure is in a range of 5 m to 12 m. The one-dimensional size of the top surface of the second non-pyramidal texture structure is in a range of 10 m to 40 m.

Each solar cell 1 includes: a silicon substrate 2; a diffusion layer 3; a first collection electrode 4 contacting the diffusion layer 3; a first connection electrode 5 contacting the diffusion layer 3 and the first collection electrode 4; an insulation layer 7 having an opening portion extending therethrough; a second collection electrode 8 contacting the insulation layer 7 and connected to the single crystal silicon substrate 2 via the opening portion 70; and a second connection electrode 9 contacting the second collection electrode 8. The first connection electrode 5 and the second connection electrode 9 are separated from each other. The second collection electrode 8 and the single crystal silicon substrate 2 are separated from each other via the insulation layer 7 in almost all or all of an overlapping area of each two adjacent PERC solar cells 1.

A solar cell including: a substrate having front and back surfaces, the back surface including first and second regions staggered and spaced from each other, and a gap region provided between one first region and one adjacent second region, a plurality of first pyramidal texture structure regions formed corresponding to a plurality of gap regions and a distance between a top and bottom thereof is 2-4 m; 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 conductive layer(s) adjacent thereto, the boundary region including strip or line-patterned texture structures arranged at intervals.

An example of an apparatus to generate electricity from light with photovoltaic cells is provided. The apparatus includes a plurality of photovoltaic cells. The plurality of photovoltaic cells is to form a module. Furthermore, the apparatus includes an electro-conductive backsheet to connect the plurality of photovoltaic cells. The electro-conductive backsheet is to collect current from the plurality of photovoltaic cells. Each photovoltaic cell of the plurality of photovoltaic cells is formed on a silicon wafer by cutting along a {100} plane to provide a substantially square wafer and cleaving the substantially square wafer along a preferred cleavage plane.

Embodiments of the present disclosure provide a method for welding cell strings and a series welding machine. The method includes: forming an arrangement of a plurality of solar cells; inspecting the arrangement of the plurality of solar cells; providing a plurality of initial welding strips including first initial welding strips and second initial welding strips, the first initial welding strips interleave with the second initial welding strips in a first direction; cutting each of the first initial welding strips at first cutting positions, and cutting each of the second initial welding strips at second cutting positions, to obtain a plurality of welding strips; moving each welding strip in a second direction to form a set of welding strips; transferring the set of welding strips onto the arrangement of the plurality of solar cells; and welding the plurality of welding strips to corresponding solar cells to form a cell string.

Disclosed is solar cell, a photovoltaic module, and a method for manufacturing a photovoltaic module. The solar cell includes a substrate, first busbars and second busbars arranged on the substrate, first fingers connected to the first busbars, and second fingers connected to the second busbars. The first busbars and the second busbars have opposite polarities. The first fingers have a same polarity as the first busbars, and the second fingers have a same polarity as the second busbars. The substrate is provided with busbar pits. At least part of the first and second busbars are located in the busbar pits. Depths of the busbar pits range from 30 m to 50 m. Along a thickness direction of the substrate, ratios of the depths of the busbar pits to heights of the first busbars and/or the second busbars range from 10:3 to 6:5.

The present disclosure provides a non-solder pad ultrafine main busbar back-contact solar cell, a back-contact solar cell module, and a preparation method, wherein the back-contact cell includes a first finger and a second finger, a first main busbar line, a second finger, a first insulation layer, and a second insulation layer, wherein the widths of the first main busbar line and the second main busbar line in the X-axis direction are each independently 10-100 m; the first main busbar lines or the second main busbar lines are respectively provided in an extending manner or at intervals along the same axis perpendicular to the corresponding fingers connected thereto, and when spaced apart, the distance L between two adjacent corresponding main busbar lines in the Y-axis direction is 5-100 mm.

A solar cell module includes a plurality of solar cells each including a semiconductor substrate, first electrodes positioned on a front surface of the semiconductor substrate, and second electrodes positioned on a back surface of the semiconductor substrate, and a plurality of wiring members connecting the first electrodes of a first solar cell of the plurality of solar cells to the second electrode of a second solar cell adjacent to the first solar cell. At least a portion of the first electrodes includes first pads each having a width greater than a width of the first electrode at crossings of the wiring members and the first electrodes. A size of at least one of the first pads is different from a size of the remaining first pads.

The invention relates to a contact device for contacting multiple sub-cells of solar cells that are physically and electrically separate from one another and also to an arrangement and a method for characterising such sub-cells. The contact device comprises a planar carrier element with at least two back-side contact arrangements or at least two planar carrier elements each with at least one back-side contact arrangement, at least one front-side contact arrangement and at least one holding device for fixing the sub-cells on the planar carrier element or elements. Each back-side contact arrangement and each front-side contact arrangement corresponds to a back-side or front-side contact, respectively, of one of the sub-cells. Either the back-side contact arrangements of the individual sub-cells can be electrically contacted separately, while the front-side contact arrangements of all the sub-cells are electrically connected to a common front-contact arrangement and can be contacted with a common front-side potential, or the front-side contact arrangements of the individual sub-cells can be electrically contacted separately, while the back-side contact arrangements of all the sub-cells are electrically connected to a common back-contact arrangement and can be contacted with a common back-side potential. With the aid of the contact device, multiple sub-cells can be electrically characterised at the same time during a lighting operation or one after the other during successive lighting operations.