A solar cell module is discussed, which includes a plurality of strings each including a plurality of solar cells, which are connected in series to one another through an interconnector, a front transparent substrate disposed on front surfaces of the plurality of strings, a first encapsulant disposed between the front transparent substrate and the front surfaces of the plurality of strings, a first reflector disposed in a first space between the plurality of solar cells included in each string, which are separated from one another in a first direction corresponding to a longitudinal direction of each string, and a second reflector disposed in a second space between the plurality of strings, which are separated from one another in a second direction crossing the first direction. The first and second reflectors reflect incident light.

A solar power system may comprise a back sheet that comprises an interconnect circuit coupling a plurality of cell tiles. A tiled solar cell, comprising a solar cell and encapsulating and glass layers, is inserted into the cell tiles of the hack sheet. Each solar cell is individually addressable through the use of the interconnect circuit. Moreover, the interconnect circuit of the back sheet is programmable and allows for dynamic interconnect routing between solar cells.

The invention concerns a method for producing a photovoltaic module, comprising:•—providing a plurality of bifacial photovoltaic cells each having a short-circuit current ratio (B),•—asymmetrically cutting each cell into two portions, such that the ratio between the surface areas of said portions is substantially equal to the short-circuit current ratio (B) of said cell or to the average short-circuit ratio of the set of cells,•—juxtapositioning said cell portions in a main plane of the module in order to form pairs of cell portions chosen such that the front face of the first portion has a short-circuit current substantially equal to the short-circuit current of the rear face of the second portion, said portions being arranged such that the front face of the first portion and the rear face of the second portion coincide with the front face of the module,•—creating an electrical connection of the front face of the first portion with the rear face of the second portion.

A solar cell module comprises a solar cell element, first and second connection tabs, and first and second solder portions. The solar cell element includes a semiconductor substrate, a front busbar electrode, and a back busbar electrode. The first solder portion connects the front busbar electrode and the first connection tab. The second solder portion connects the back busbar electrode and the second connection tab. A distance between the first lateral surface and a first bonding surface where the first solder portion is bonded to the front busbar electrode is shorter than a distance between the first lateral surface and a second bonding surface where the second solder portion is bonded to the back busbar electrode. A distance between the second lateral surface and the first bonding surface is shorter than a distance between the second lateral surface and the second bonding surface.

Illumination panel comprises: (1) a receiver substrate assembly including: (a) a rigid sheet of light transmissive material having a first surface, a second surface opposite the first surface, and a conductor pattern attached to the first surface; and (b) at least one receiver assembly affixed to the rigid sheet, each receiver assembly including a light source in electrical communication with the conductor pattern; and (2) at least one light-guide optic attached to and supported by the receiver substrate assembly, each light-guide optic in optical communication with the photovoltaic cell of an associated one of the at least one receiver assembly for guiding light for output via the rigid sheet.

The disclosure provides a flexible solar panel, wherein a plurality of first main grid lines are arranged on a positive electrode surface of a solar cell body and are welded to a first solder strip; a plurality of second main grid lines are arranged on a negative electrode surface of the solar cell body and are welded to a second solder strip; a copper mesh is formed by a plurality of copper wires crossed transversely and vertically, and the copper mesh is composited on the positive electrode surface; a positive electrode EVA film is composited on the copper mesh; the solar cell body, the copper mesh and the positive electrode EVA film form a solar cell; a plurality of solar cells are connected in series and installed on a PCB board; a negative electrode EVA film covers the negative electrode surfaces of the solar cells.

A method for forming a solar cell including steps of (1) providing a semiconductor wafer having an upper surface; (2) applying an electrical contact material to the upper surface, the electrical contact material forming an electrically conductive grid that includes grid lines extending from a bus bar; (3) forming an isolation channel in the semiconductor wafer to define a solar cell portion and a wing portion, wherein the wing portion is electrically isolated from the solar cell portion, and wherein the wing portion is substantially free of the electrical contact material; (4) submerging the semiconductor wafer in a solvent, wherein formation of metal dendrites on the grid lines of the electrically conductive grid is inhibited; and (5) separating the solar cell portion from the wing portion.

The present invention relates to a shingled solar cell panel for producing a string in which a plurality of strips are partially overlapped with each other, and for electrically connecting the string and the string, and a method for producing the same, the method comprises providing a wafer made of a HIT in which a plurality of conductive layers are formed on upper and lower portions thereof, respectively, forming an adhesive layer by applying a conductive adhesive on the upper conductive layer, dividing the wafer on which the adhesive layer is formed into a plurality of strips, forming a string by overlapping a lower conductive layer of another strip on an area where an adhesive layer is provided among the divided strips. Accordingly, the upper conductive layer and the lower conductive layer of each of the plurality of strips can be configured to be electrically bonded via only the adhesive layer to provide a shingled solar cell panel at low cost.

A plurality of solar cell assembly series of a solar cell panel are so arranged that any two adjacent solar cells in the plurality of solar cell assembly series have a potential difference which does not exceed V volts which is a maximum output voltage of the plurality of solar cell assembly series.

A solar cell module and a method for manufacturing the same are disclosed. The method for manufacturing the solar cell module includes applying a low melting point metal on an electrode included in each of a plurality of solar cells, melting the low melting point metal to form a contact layer on the electrode, generating an ultrasonic vibration in the contact layer to remove a surface oxide layer formed on a surface of the electrode, melting a surface metal of the electrode and the contact layer to form a metal connection layer on the surface of the electrode, and connecting the metal connection layer to an interconnector.