A solar module is provided which has improved durability. A third wiring member (32a) includes a first portion (32a1), a second portion (32a2), and a third portion (32a3). In the first portion (32a1), metal foil (52) faces a solar cell (20). The first portion (32a1) is electrically connected to the solar cell (20). The second portion (32a2) is arranged on the solar cell (20) with the metal foil (52) facing the side opposite to the solar cell (20). The third portion (32a3) connects the first portion (32a1) and the second portion (32a2). A first wiring member (32b) electrically connects the second portions (32a2) of adjacent solar cell strings (10) to each other. The solar module (1) also includes an insulating sheet (60). The insulating sheet (60) is arranged between the first wiring member (32b) and the solar cell (20).

A high efficiency configuration for a string of solar cells comprises series-connected solar cells arranged in an overlapping shingle pattern. Front and back surface metallization patterns may provide further increases in efficiency.

A flexible solar module strand manufactured by a method including providing a first conveyor track for applying flexible solar cells; guiding the first conveyor track around two or more deflecting means; providing individual flexible solar cells; applying the individual solar cells to the first conveyor track; deflecting the first conveyor track by guiding the first conveyor track over a first one of the deflecting means; separating the first conveyor track from the at least one deflected solar cell strip in such a manner that the solar cells are released, with their respective first or second sides facing the first conveyor track, from the first conveyor track; and applying the at least one deflected solar cell strip to a first film web in such a manner that the solar cells are oriented, with their respective first or second sides separated from the first conveyor track, away from the first film web.

One or more solar cells are connected to a flex circuit, wherein: the flex circuit is comprised of a flexible substrate having one or more conducting layers for making electrical connections to the solar cells; the flex circuit is attached to a panel; and the solar cells are attached to the panel. The flex circuit can be attached to the panel so that the conducting layers are adjacent the solar cells, or the flex circuit can be attached to the panel so that the conducting layers run underneath the solar cells. The conducting layers can be deposited on the flexible substrate and/or the conducting layers can be embedded in the flex circuit, wherein the conducting layers are sandwiched between insulating layers of the flex circuit.

A high efficiency configuration for a solar cell module comprises solar cells conductively bonded to each other in a shingled manner to form super cells, which may be arranged to efficiently use the area of the solar module, reduce series resistance, and increase module efficiency. The front surface metallization patterns on the solar cells may be configured to enable single step stencil printing, which is facilitated by the overlapping configuration of the solar cells in the super cells. A solar photovoltaic system may comprise two or more such high voltage solar cell modules electrically connected in parallel with each other and to an inverter. Solar cell cleaving tools and solar cell cleaving methods apply a vacuum between bottom surfaces of a solar cell wafer and a curved supporting surface to flex the solar cell wafer against the curved supporting surface and thereby cleave the solar cell wafer along one or more previously prepared scribe lines to provide a plurality of solar cells. An advantage of these cleaving tools and cleaving methods is that they need not require physical contact with the upper surfaces of the solar cell wafer. Solar cells are manufactured with reduced carrier recombination losses at edges of the solar cell, e.g., without cleaved edges that promote carrier recombination. The solar cells may have narrow rectangular geometries and may be advantageously employed in shingled (overlapping) arrangements to form super cells.

Provided is a solar cell apparatus. The solar cell apparatus includes: a substrate; a first cell group on the substrate; a second cell group on the substrate; a first diode connected in parallel to the first cell group; and a second diode connected in parallel to the second cell group.

A string-forming system is described. The string-forming system may include at least a first cell-lifting mechanism and a second cell-lifting mechanism that can automatically arrange a set of strips of a photovoltaic structure into a cascaded formation. During operation, a controller can cause the first cell-lifting mechanism to lift a first strip from a first platform, and can cause the second cell-lifting mechanism to lift, from the first platform, a second strip that may follow the first strip on the first platform. The controller may then activate a first shifting actuator of the first cell-lifting mechanism or a second shifting actuator of the second cell-lifting mechanism to place a leading edge of the second strip above a trailing edge of the first strip.

The present invention relates to a fault diagnosis for a photovoltaic system. A fault diagnosis apparatus includes a temperature sensor unit measuring both an internal temperature value of the junction box and a surface temperature value of the solar module; a voltage sensor provided in the junction box; and an operation unit determining where a fault occurs among the solar module, an inside of the junction box, and the inverter by comparing measured values of the temperature sensor unit with a measured value of the voltage sensor. According to the present invention, initial investment cost is inexpensive. In addition, it is possible to detect solar module faults that are difficult to be checked by the naked eye.

Provided are a solar cell, a method for manufacturing a solar cell, and a photovoltaic module. A plurality of first pad groups and at least one second pad group are arranged along a first direction on a back surface of the solar cell. The second pad group is distributed in a region of the solar cell adjacent to a cut edge or a non-cut edge of the solar cell. The first pad groups are distributed in a region of the solar cell away from the cut edge or the non-cut edge. Along the first direction, a distance between a pad in the second pad group and a pad in the first pad group adjacent to the pad in the second pad group is greater than a distance between adjacent pads in adjacent first pad groups.

A solar cell and a photovoltaic module are disclosed. The photovoltaic module includes a substrate, busbars, and at least one marker. The busbars are arranged on a same side of the substrate, and include at least a first busbar and a second busbar, the first busbar and the second busbar have opposite polarities, the first busbar has a first pad, the second busbar has a second pad, the first pad and the second pad are arranged sequentially along a straight line parallel to an arrangement direction of the busbars, and a distance from a marker to the first pad is different from a distance from a same marker to the second pad.