One embodiment of the invention can provide a solar panel. The solar panel can include a plurality of strings of photovoltaic strips sandwiched between a front cover and a back cover. The strings can be arranged into an array that includes multiple blocks, and a respective block can include a subset of strings that are electrically coupled to each other in parallel. The subset of strings within the block can be coupled to a bypass diode. The multiple blocks can be electrically coupled to each other in series.

A solar cell module includes a plurality of solar cells including a first solar cell and a second solar cell adjacent to each other, wherein each of the plurality of solar cells including at least one first current collector and at least one second current collector, wherein the at least one first current collector and the at least one second current collector being positioned on a non-light incident surface of each of the plurality of solar cells, which is opposite to a light incident surface of each of the plurality of solar cells, an insulating film having a conductive pattern part positioned on the insulating film, wherein the conductive pattern part including a first pattern which is connected to the at least one first current connector 161 of the plurality of solar cells and a second pattern which is connected to the at least one second current connector of the plurality of solar cells, wherein the first pattern being spaced apart from the second pattern; and an insulating sheet between the an insulating film and the non-light incident surface of the plurality of solar cells.

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).

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.

Photovoltaic cells, methods for fabricating surface mount multijunction photovoltaic cells, methods for assembling solar panels, and solar panels comprising photovoltaic cells are disclosed. The surface mount multijunction photovoltaic cells include through-wafer-vias for interconnecting the front surface epitaxial layer to a contact pad on the back surface. The through-wafer-vias are formed using a wet etch process that removes semiconductor materials non-selectively without major differences in etch rates between heteroepitaxial III-V semiconductor layers.

A bifacial photovoltaic module with at least one bifacial solar cell is provided. The at least one bifacial solar cell includes a substrate with a front-side and a rear-side. The front-side is the light incident side and the rear-side has rear-side contact structure. The rear-side contact structure includes a plurality of electrically conductive contact fingers, which have a first metal, a plurality of solder pads electrically connected to the contact fingers. The solder pads have a top. The solder pads have a second metal, which is different from the first metal. The rear-side contact structure further includes several cell connectors electrically connected to the solder pads. The top of the solder pads is free from the contact fingers in an area along one direction. The cell connectors are disposed planar on or above this area.

A method including providing a substrate comprising a device layer on which a plurality of device cells are defined; depositing a first dielectric layer on the device layer and metal interconnect such that the deposited interconnect is electrically connected to at least two of the device cells; depositing a second dielectric layer over the interconnect; and exposing at least one contact point on the interconnect through the second dielectric layer. An apparatus including a substrate having defined thereon a device layer including a plurality of device cells; a first dielectric layer disposed directly on the device layer; a plurality of metal interconnects, each of which is electrically connected to at least two of the device cells; and a second dielectric layer disposed over the first dielectric layer and over the interconnects, wherein the second dielectric layer is patterned in a positive or negative planar spring pattern.

An embodiment includes an apparatus comprising: a first photovoltaic cell; a first through silicon via (TSV) included in the first photovoltaic cell and passing through at least a portion of a doped silicon substrate, the first TSV comprising (a)(i) a first sidewall, which is doped oppositely to the doped silicon substrate, and (a)(ii) a first contact substantially filling the first TSV; and a second TSV included in the first photovoltaic cell and passing through at least another portion of the doped silicon substrate, the second TSV comprising (b)(i) a second sidewall, which comprises the doped silicon substrate, and (b)(ii) a second contact substantially filling the second TSV; wherein the first and second contacts each include a conductive material that is substantially transparent. Other embodiments are described herein.

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 welding method for a welding strip of a back-contact solar cell chip includes the following steps: firstly, welding small chip assemblies of a back-contact solar cell to be interconnected to form a small cell string through an interconnected bar; then, punching the small cell string into small cell assemblies separated from each other through a cutting or punching process; subsequently, flexibly welding the small cell assemblies by a bus bar to reach a required length of a finished assembly product; and finally, breaking the bus bar through a post cutting or punching process to form cell assemblies with positive and negative electrodes connected in series or in parallel. The method makes the welding surfaces of the solar cell chips be on the same surface through using the back-contact solar cell chips, so that the interconnected bar of the solar cell chips can be welded rapidly and continuously.