A high efficiency configuration for a solar cell module comprises solar cells arranged in an overlapping shingled manner and conductively bonded to each other in their overlapping regions to form super cells, which may be arranged to efficiently use the area of the solar module.

Embodiments of the present disclosure generally relate to flexible photovoltaic modules that include a multi-layered substrate. In some embodiments, the multi-layered substrate includes one or more layers that are configured to improve the elastic modulus, rigidity, or stiffness of a flexible substrate of a flexible photovoltaic module during a deposition process step at an elevated temperature that is used to form the flexible photovoltaic module. The one or more layers of the multi-layered substrate may also provide improved barrier properties that prevent environmental contaminants from affecting the performance of a formed photovoltaic module, which includes the multi-layered substrate, during normal operation.

Each of at least three solar cell strings has a first end and a second end in a first direction each including a connector. At the first end and the second end, a wire member is provided to which the connector of the first end of each of at least two solar cell strings out of the at least three solar cell strings and the connector of the second end thereof are connected. A first sheet member is provided to allow the wire member at the first end to be located in a specific positional relationship with the wire member at the second end, and a second sheet member is provided to allow the wire member at the second end to be located in a specific positional relationship with the wire member at the first end.

Each of at least three solar cell strings has a first end and a second end in a first direction each including a connector. At the first end and the second end, a wire member is provided to which the connector of the first end of each of at least two solar cell strings out of the at least three solar cell strings and the connector of the second end thereof are connected. A first sheet member is provided to allow the wire member at the first end to be located in a specific positional relationship with the wire member at the second end, and a second sheet member is provided to allow the wire member at the second end to be located in a specific positional relationship with the wire member at the first end.

The finger electrode is formed by hard-soldered silver paste. The melting point of the first type solder layer provided on the surface of the terminal wiring member is higher than the melting point of the second type solder layer provided on the surface of the wire. The first width, in the first direction, of the second type solder layer in the first portion where the wire is connected to the terminal wiring member is larger than the second width, in the first direction, of the second type solder layer in the second portion where the wire is connected to the finger electrode.

A photovoltaic converter for electric power generating panels includes a plurality of photovoltaic modules (5), each comprising a substrate (14), extending along a main direction (D) from a first end to a second end, and a plurality of photovoltaic devices (15), arranged on the substrate (14) in succession along the main direction (D). The photovoltaic converter further includes at least a bridge module (10, 11) insertion-connecting a respective upstream photovoltaic module (5) and a respective downstream photovoltaic module (5).

A conductive interconnection member includes: a conductive layer (1), and an insulating layer (4) and electrical connectors (2) located on one side of the conductive layer (1). The conductive layer (1) is provided with a conductive circuit; the insulating layer (4) is provided with openings (41), and the electrical connectors (2) are located in the openings (41) of the insulating layer (4); the electrical connectors (2) include a first electrical connector (21) and a second electrical connector (22); the first electrical connector (21) is used to be electrically connected to a first electrode (31) of a back contact solar cell (3) and the conductive circuit; the second electrical connector (22) is used to be electrically connected to a second electrode (32) of a back contact solar cell (3) and the conductive circuit; and the polarities of the first electrode (31) and the second electrode (32) are opposite.

A welding ribbon and a solar cell assembly are provided. The welding ribbon comprises a composite core and a coating wrapped around said composite core; the composite core comprises a plurality of welding cores, at least one first bending part is provided on each of said welding cores, and the plurality of welding cores are wound with each other by means of the respective first bending parts to form the composite core; in addition, at least one third bending part is also provided on the welding ribbon, at least one of the third bending parts is closely attached to the middle part of the corresponding battery sheet, and the direction of bending of the third bending part is perpendicular to the length direction of the welding core.

The disclosed invention provides a photovoltaic module with an improved electrode structure of a solar cell and having any of various shapes. The photovoltaic module includes electrode members each including a finger electrode and a busbar electrode on a front surface of a solar cell to correspond to the number of divided cells, wherein the finger electrode is disposed as a plurality of finger electrodes in a first direction parallel to a short side of a divided unit cell, and the busbar electrode includes a collection electrode line which extends in a second direction parallel to a long side of the divided unit cell and connects ends of the plurality of finger electrodes and a connecting electrode line which is branched off from an end of the collection electrode line and extends in the first direction to be electrically connected to another unit cell.

Provided is a solar cell and a photovoltaic module. The solar cell includes a semiconductor substrate and an electrode arranged on the semiconductor substrate. The electrode includes a plurality of fingers arranged in parallel to and spaced apart from each other. Each finger includes a transport electrode line and a plurality of electrical connection electrode lines in contact with the transport electrode line. In a thickness direction of the semiconductor substrate, a plurality of fingers on a light receiving surface of the semiconductor substrate are staggered with a plurality of fingers on a backlight surface of the semiconductor substrate.