This wiring module includes: a wiring substrate; a base portion at which the wiring substrate is placed; and an adhesive layer configured to adhere the wiring substrate to the base portion, wherein the wiring substrate includes: a land portion configured to have a power generating element mounted thereto; and a wire portion configured to be electrically connected to the power generating element, the adhesive layer has: a land adhesion region configured to adhere the land portion to the base portion; and a wire adhesion region configured to adhere the wire portion to the base portion, and a width of the wire adhesion region is smaller than a width of the land adhesion region.

A wiring substrate is configured to have a power generating portion mounted thereto. The wiring substrate includes a land portion and a wire portion. The width of the wire portion is smaller than the width of the land portion.

A solar collection assembly for collection of incident solar energy and generation of electricity includes a central vertically oriented support column carrying a solar collection assembly of one or more dual faced solar receptor assemblies. Each solar receptor assembly has an upper solar receptor surface and a lower solar receptor surface. A rotatable solar collector reflective assembly surrounds the central vertically oriented support column and is oriented to reflect incident solar energy onto the solar collection assembly. Sails are attached to the outside of the rotatable solar collector reflective assembly for additional generation of electricity by rotation of the rotatable solar collector reflective assembly from wind energy.

A high power solar cell module including a cover plate, a back plate, a first encapsulation, a second encapsulation, a plurality of N type hetero-junction solar cells, and a plurality of reflective connection ribbons is provided. The back plate is opposite to the cover plate. The first encapsulation is located between the cover plate and the back plate. The second encapsulation is located between the first encapsulation and the back plate. The N type hetero-junction solar cells and the reflective connection ribbons are located between the first encapsulation and the second encapsulation, and any two adjacent N type hetero junction solar cells are connected in series along a first direction by at least one of the reflective connection ribbons, wherein each of the reflective connection ribbons has a plurality of triangle columnar structures. Each of the triangle columnar structures points to the cover plate and extends along the first direction.

An optoelectronic device including at least one of a solar device, a semiconductor device, and an electronic device. The device includes a semiconductor unit. A plurality of metal fingers is disposed on a surface of the semiconductor unit for electrical conduction. Each of the metal fingers corresponds to a section of the optoelectronic device. A plurality of pad areas is available for connection to a bus bar, wherein each of the metal fingers is connected to a corresponding pad area for forming an electrical contact. The optoelectronic device includes a bad section, wherein the bad section is associated with a compromised metal finger and a compromised pad area. A dielectric spot coating is disposed above the compromised pad area to electrically isolate the bad section.

In various embodiments, a tabbing ribbon for connecting at least one solar cell is provided, wherein the tabbing ribbon at least partially extends in a non-planar manner and includes a non-planar section.

A solar cell panel and a method for manufacturing the same are discussed. The solar cell panel includes a plurality of solar cells each including a substrate and a plurality of electrode parts positioned on a surface of the substrate, an interconnector electrically connecting the electrode parts of adjacent ones of the plurality of solar cells to one another, and conductive adhesive films including a resin and a plurality of conductive particles dispersed in the resin. The conductive adhesive films is pressed between the electrode parts and the interconnector to electrically connect the electrode parts to the interconnector. A plurality of uneven portions are positioned on at least one of an upper surface and a lower surface of the interconnector.

A solar cell module having an interconnector and a method of fabricating the same are disclosed. The solar cell module includes a plurality of solar cells and an interconnector including a first area electrically connected to one of two adjacent solar cells of the plurality of solar cells, a second area electrically connected to the other of the two adjacent solar cells, and a third area connecting the first area to the second area. At least one of the first area and the second area of the interconnector has at least one uneven surface, and the third area of the interconnector has a substantially planarized surface.

Back side connection layer for a photo-voltaic module with a plurality of PV-cells (1, 2). The PV-cells (1, 2) are of a type having a plurality of back side contacts (11, 12). A by-pass diode connection path (6) is formed in the back side connection layer (3) along an edge direction of two adjacent cells (1, 2) with a straight or meandering pattern around outer contacts (4, 5) of the plurality of back side contacts (11, 12) of the two adjacent cells (1, 2).

A solar battery module is provided that includes plural solar battery cells, plural interconnectors each having a shock absorber, a sealing layer, a back face layer, and a front face layer having optical transparency. The plural solar battery cells each include an electrode on a peripheral edge portion at a back face that does not receive sunlight. The plural interconnectors extend along the peripheral edge portions, and connect the electrodes of the plural solar battery cells to each other. The sealing layer seals each of the solar battery cells and each of the interconnectors. The shock absorber is disposed in a region between corner portions of adjacent or diagonally opposing solar battery cells, and permits movement of the solar battery cells accompanying expansion or contraction of at least one out of the back face layer or the front face layer.