There is provided a photoelectric conversion element which includes an n-type single crystal silicon substrate (1). The n-type single crystal silicon substrate (1) includes a central region (11) and an end-portion region (12). The central region (11) is a region which has the same central point as the central point of the n-type single crystal silicon substrate (1) and is surrounded by a circle. The diameter of the circle is set to be a length which is 40% of a length of the shortest side among four sides of the n-type single crystal silicon substrate (1). The central region (11) has a thickness t1. The end-portion region (12) is a region of being within 5 mm from an edge of the n-type single crystal silicon substrate (1). The end-portion region (12) is disposed on an outside of the central region (11) in an in-plane direction of the n-type single crystal silicon substrate (1), and has a thickness t2 which is thinner than the thickness t1. The end-portion region (12) has average surface roughness which is smaller than average surface roughness of the central region (11).

Methods are disclosed for assembling PV modules using connectors that have strain relief elements. Strings can be inspected individually and dimensional information can be obtained to layup the strings into a PV module in a specific manner. Portions of the strings can be soldered using elevators to lift connectors into place, and then applying heat to both sides of the connector.

A photovoltaic module can be constructed from one or more strings, with each of the strings being constructed from a plurality of cascaded solar cells. A connector can electrically connect the strings to one another. The connector can include strain relief connectors that extend between the connector and the strings to help reduce effects caused by thermal expansion.

The present invention concerns a plating method for manufacturing of electrical contacts on a solar module wherein the wiring between silicon solar cells in a solar module is deposited by electroplating onto a conductive seed. The wiring between individual silicon solar cells comprises wiring reinforcement pillars which improve the reliability of said wiring.

Approaches for fabricating spot-welded and adhesive bonded interconnects for solar cells, and the resulting solar cells, are described. In an example, a solar cell includes a substrate having a back surface and an opposing light-receiving surface. A plurality of alternating N-type and P-type semiconductor regions is disposed in or above the back surface of the substrate. A conductive contact structure is disposed on the plurality of alternating N-type and P-type semiconductor regions. An interconnect structure is electrically connected to the conductive contact structure. The interconnect structure includes a plurality of protrusions in contact with the conductive contact structure. Each of the plurality of protrusions is spot-welded to the conductive contact structure and is surrounded by an adhesive material.

A photovoltaic module generates electrical power when installed on a roof. The module is constructed as a laminated sandwich having a transparent protective upper layer adhered to a photovoltaic layer. The photovoltaic layer is adhered to the top of a rigid layer, preferably formed from a fiber reinforced plastic. A tapered edge seal is disposed about the peripheral outer edge of the module, so that water and debris easily run off Preferably, the tapered edge seal is disposed adjacent the photovoltaic layer, and above the rigid substrate layer. The tapered edge seal is thinner at the outer peripheral portion thereof than at a portion thereof adjacent the photovoltaic layer. The laminated module preferably has a layer of double stick tape on the bottom to adhere the module to the surface of a roof.

An electrode assembly for connecting a front surface of a first solar cell to a back surface of a second solar cell, the electrode assembly comprising: a plurality of conductive elements, wherein at least one of the conductive elements comprises: a first surface for contacting the front surface of the first solar cell; and a second surface for contacting the back surface of the second solar cell, the second surface being arranged opposite the first surface; wherein at least a portion of each of the first and second surfaces comprises a coating for connecting the respective surfaces of the at least one conductive element to a surface of the solar cell; wherein the second surface is configured to define a contact area which is substantially smaller than the contact area defined by the first surface.

A solar cell assembly (100) comprising: a layered structure (102) comprising a photovoltaic element and a conductive surface (111); and an electrode assembly (101) comprising a plurality of longitudinally extending, laterally spaced conductive elements (104a-104f) arranged side by side, the plurality of conductive elements comprising a first conductive element (104b) having a first cross-sectional area and a second conductive element (104a) having a second cross-sectional area that is larger than the first cross-sectional area, the electrode assembly arranged on the conductive surface of the layered structure such that the conductive elements are in ohmic contact with the conductive surface.

A solar module comprising a plurality of solar cell strings arranged side-by-side, each solar cell string having positive and negative terminals at opposite ends thereof, the plurality of solar cell strings comprising: a first group of adjacent solar cell strings, each oriented such that their positive terminals are disposed towards a first end of the solar module; and a second group of adjacent solar cell strings, each oriented such that their positive terminals are disposed towards a second end of the solar module opposite the first end, the positive terminals of the second group of solar cell strings electrically connected to the negative terminals of the first group of solar cell strings.

Embodiments of the present disclosure relates to the field of solar cells, and in particular to a solar cell and a production method thereof, and a photovoltaic module. The solar cell includes: a P-type emitter formed on a first surface of an N-type substrate and including a first portion and a second portion, a top surface of the first portion includes first pyramid structures, and a top surface of the second portion includes second pyramid structures whose edges are straight. A transition surface is respectively formed on at least one edge of each first pyramid structure, and each of top surfaces of at least a part of the first pyramid structures includes a spherical or spherical-like substructure. A tunnel layer and a doped conductive layer sequentially formed over a second surface of the N-type substrate. The present disclosure can improve the photoelectric conversion performance of solar cells.