The photovoltaic module includes at least one cell string, including multiple solar cell sheets, and adjacent solar cell sheets in the multiple solar cell sheets are connected to each other by multiple welding strips. In some embodiments, the photovoltaic module further includes multiple welding strips, where each of the multiple welding strips is in electrical contact with a corresponding bus bar, each of the multiple welding strips includes multiple bending portions arranged continuously along a second direction. In addition, along the second direction, an orthographic projection of a central line of each of the multiple welding strips on a back surface of the solar cell sheet coincides with an orthographic projection of a central line of the corresponding bus bar and/or an orthographic projection of a central line of each of the multiple bonding pads on the corresponding bus bar on the back surface of the solar cell sheet.

Systems and methods are provided for wirelessly transferring power to a multi-junction photovoltaic cell of a space apparatus via a light emission system. The light emission system uses multiple lasers emitting different wavelengths and/or photon energies to produce electron-hole pairs in each layer of the multi-junction photovoltaic cell to prompt power generation by the multi-junction photovoltaic cell. The light emission system may be located on Earth or on another space apparatus. The multi-junction photovoltaic cell can convert sunlight and the light emitted by the light emission system into electrical energy.

Systems, methods and apparatus related to a multijunction solar cell. The apparatus comprises a first sub-solar cell, a second sub-solar cell in series with the first sub-solar cell and one or more quantum wells. At least some of the quantum wells are disposed in a region of the first sub-solar cell, and have a thickness and a bandgap sized such that a bandgap in selected quantum wells are less than a bandgap of a material of the first sub-solar cell and greater than a bandgap of a material of the second sub-solar cell resulting in radiative coupling between the first sub-solar cell and the second sub-solar cell.

The present invention relates to a method for manufacturing a solar cell, comprising: a seating process of seating, in a processing space for manufacturing a solar cell, a cell in which a plurality of thin film layers are formed; a coating process of spraying a conductive material onto the cell; and a scribing process of irradiating a laser toward the cell to form a cell separation unit for separating the cell into a plurality of unit cells.

A solar cell module includes an upper substrate, a lower substrate opposite the upper substrate, a solar cell panel positioned between the upper substrate and the lower substrate, the solar cell panel including a plurality of solar cells which are arranged in a matrix form and are connected to one another through a wiring member, a passivation layer configured to package the solar cell panel, a frame configured to surround an outer perimeter of the solar cell panel, a connection terminal configured to connect two adjacent strings in the solar cell panel, and a cover member configured to cover the connection terminal.

Photovoltaic module including at least one string including at least one first and one second photovoltaic cell and a connector that electrically couples the first and the second photovoltaic cell. The first and the second photovoltaic cells each comprise: a respective photovoltaic conversion region delimited by a respective main front surface and a respective main rear surface opposite to each other; and a respective first electrode structure and a respective second electrode structure, which are formed of conductive material and extend respectively on the first and on the main rear surface. The photovoltaic module is characterised in that the connector is made of a composite material comprising a support matrix and electrically conductive particles, which are dispersed in the thermoplastic polymer matrix. The connector further includes a respective first end portion and a respective second end portion, which respectively contact the second electrode structure of the first photovoltaic cell and the first electrode structure of the second photovoltaic cell.

A method for fabricating solar cell module, comprising: dividing mother solar cell into solar cells by irradiating laser; the solar cells have long axis and short axis, and include first electrode on front surface and second electrode on back surface, disposing the solar cells along first direction; and connecting wiring members to first electrode of first solar cell and second electrode of second solar cell adjacent to the first solar cell, each of solar cell includes first side surface of one side in the first direction, second side surface having larger surface roughness than the first side surface on the other side, and protrusion formed adjacent to the second side surface on the back surface, and the first solar cell and the second solar cell are disposed with a gap of 0.5 mm to 1.5 mm with first side surface of second solar cell facing second side surface of first solar cell.

The present invention relates to an electrically conductive composition comprising a) from 5 to 25% by weight of the total weight of the composition of a cycloaliphatic epoxide resin; b) from 0.05 to 10% by weight of the total weight of the composition of a vinyl ether; c) from 0.1 to 0.45% by weight of the total weight of the composition of an onium salt; d) from 0.01 to 10% by weight of the total weight of the composition of a radical initiator; e) from 45 to 85% by weight of the total weight of the composition of electrically conductive particles; and f) from 0.1 to 10% by weight of the total weight of the composition of an organic solvent. The composition can be used as an adhesive in the electronic applications, especially as an adhesive in the shingle module photovoltaic applications.

Provided are novel Building Integrable Photovoltaic (BIPV) modules having one or more connectors that are movable between extended and retracted positions. Connector adjustment may be performed in the field, for example, during installation of a module. In certain embodiments, a connector includes a connector body and extension body. The extension body flexibly attaches the connector body to the module and allows the connector body to move with respect to the module edge. In an extended position, the connector body is positioned closer to the edge and is configured to make electrical connections to a joiner connector for interconnecting with an adjacent module. In a retracted positioned, the connector body is positioned further from the edge and is configured to make electrical connections to a jumper for interconnecting the conductive elements of the connector. In certain embodiments, a jumper does not protrude beyond the edge when connected to the connector body.

Provided are novel methods of fabricating photovoltaic modules using thermoplastic materials to support wire networks to surfaces of photovoltaic cells. A thermoplastic material goes through a molten state during module fabrication to distribute the material near the wire-cell surface interface. In certain embodiments, a thermoplastic material is provided as a melt and coated over a cell surface, with a wire network positioned over this surface. In other embodiments, a thermoplastic material is provided as a part of an interconnect assembly together with a wire network and is melted during one of the later operations. In certain embodiments, a thermoplastic material is provided as a shell over individual wires of the wire network. A thermoplastic material is then solidified, at which point it may be relied on to support the interconnect assembly with respect to the cell. Also provided are novel photovoltaic module structures that include thermoplastic materials used for support.