A solar cell module includes a plurality of solar cells, each solar cell including a semiconductor substrate, an emitter region, a back surface field region a first electrode connected to the emitter region, a second electrode connected to the back surface field region, and a conductive line connected to one electrode of the first and second electrodes using a conductive adhesive and insulated from the other electrode of the first and second electrodes through an insulating layer, the conductive line being used to connect a plurality of solar cells in series. A thickness of the conductive adhesive between the one electrode and the conductive line is greater than a thickness of the insulating layer between the other electrode and the conductive line.

A photo-voltaic cell has a first and second two-dimensional array of contact points on the first surface, each coupled to a respective one of base and emitter areas in or on the semi-conductor body. Electrically separate first and second conductor structures on the first surface emanate from each contact point, coupled to contact points of the first and second two-dimensional array respectively. The first conductor structure comprises sets of first conductor line branches, the first conductor line branches of each set branching out from a respective one of the contact points of the first two-dimensional array in at least three successive different directions at less than a hundred and eighty degrees to each other. The second conductor structure comprise second conductor line branches in at least three different directions in areas between respective pairs of adjacent non-parallel ones of the first conductor line branches, each second conductor line branch coupled at least to a respective one of the contact points of the second two-dimensional array.

A system and method of patterning dopants of opposite polarity to form a solar cell is described. Two dopant films are deposited on a substrate. A laser is used to pattern the N-type dopant, by mixing the two dopant films into a single film with an exposure to the laser and/or drive the N-type dopant into the substrate to form an N-type emitter. A thermal process drives the P-type dopant from the P-type dopant film to form P-type emitters and further drives the N-type dopant from the single film to either form or further drive the N-type emitter.

Interconnects for optoelectronic devices are described. For example, an interconnect for an optoelectronic device includes an interconnect body having an inner surface, an outer surface, a first end, and a second end. A plurality of bond pads is coupled to the inner surface of the interconnect body, between the first and second ends. A stress relief feature is disposed in the interconnect body. The stress relief feature includes a slot disposed entirely within the interconnect body without extending through to the inner surface, without extending through to the outer surface, without extending through to the first end, and without extending through to the second end of the interconnect body.

A method for producing a back-contacting solar-cell module and a back-contacting solar-cell module. The method includes: providing a first stacked member, wherein the first stacked member includes a first sheet member; a surface of the first sheet member is provided with a plurality of first electrically conducting sites; the first stacked member further includes electrically conducting protrusions that are formed on the first electrically conducting sites of the first sheet member, gluing and insulating space rings at the peripheries of the first electrically conducting sites; providing a second stacked member, wherein the second stacked member includes a second sheet member; a surface of second sheet member is provided with a plurality of second electrically conducting sites; stacking and laminating first stacked member and second stacked member, the electrically conducting protrusions abut second electrically conducting sites, gluing and insulating space rings glue first sheet member and second sheet member together.

The present disclosure relates to an internally series-connected perovskite solar cell module and a preparation method thereof. The perovskite solar cell module comprises a plurality of sub-cell packs arranged longitudinally. Each sub-cell pack includes a positive electrode tab, a negative electrode tab, and a plurality of cell units arranged horizontally. An internal structure of the positive electrode tab, the negative electrode tab, and the plurality of cell units includes a substrate, a front electrode layer, a light-absorbing layer, and a back electrode layer from bottom to top. The present disclosure allows the back electrode layer to function as a conductor connecting each of the plurality of sub-cell packs through an appropriate laser scribing process, which realizes the series connection effect of the perovskite solar cell module by replacing busbars, thereby greatly avoiding the problem of poor contact when using busbars for series connection.

This present application provides a back contact solar cell and solar cell module, comprising: a substrate, provided with a substrate front surface and a substrate back surface opposite to each other, wherein the substrate front surface is close to a main-light-receiving surface of the cell, and the substrate back surface is close to a non-main-light-receiving surface of the cell; P-type polarity region, including a first doped semiconductor layer; N-type polarity region, including a second doped semiconductor layer, the N-type polarity region and the P-type polarity region are alternately located on side of the substrate back surface, wherein, a thickness of the second doped semiconductor layer along a normal direction of the cell is smaller than a thickness of the first doped semiconductor layer along the normal direction; and an isolation region, located between each two adjacent N-type polarity region and P-type polarity region. The back contact solar cell and solar cell module provided by this application can take into account the electrical and optical properties of the solar cell, further improving the short-circuit current, open-circuit voltage and photoelectric conversion efficiency of the solar cell.

A curved photovoltaic member includes a solar cell, a front plate, a conductive layer, and a back plate. The front plate is located at a side of the solar cell where a light receiving surface is located. The conductive layer is electrically connected to the solar cell and is located at a side of the solar cell where a back surface is located. The back plate is located at a side of the conductive layer away from the solar cell.

A cell assembly includes a first doped region. The first doped region includes a first passivated contact region disposed on the silicon substrate, and a second passivated contact region disposed on the first passivated contact region. The first passivated contact region includes a first doped layer, a first passivation layer, and a second doped layer. The second passivated contact region includes a second passivation layer and a third doped layer. The second passivated contact region includes an opening for connecting a conductive layer of the solar cell to the first passivated contact region.

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.