Building integrated photovoltaic (BIPV) systems provide for solar panel arrays that can be aesthetically pleasing to an observer. BIPV systems can be incorporated as part of roof surfaces as built into the structure of the roof, particularly as multi-region roofing modules that have photovoltaic elements embedded or incorporated into the body of the module, in distinct tiles-sized regions. Such multi-region photovoltaic modules can replicate the look of individual roofing tiles or shingles. Further, multi-region photovoltaic modules can include support structures between the distinct regions having a degree of flexibility, allowing for a more efficient installation process.

Provided are a cascaded photovoltaic grid-connected inverter, a control method and a control device for the same. The method includes: determining whether at least one of inverter units of the cascaded photovoltaic grid-connected inverter is over-modulated; injecting a reactive current to a power grid to make a grid-connected current effective value greater than or equal to √{square root over (2)}*i.sub.dcmin, in a case that at least one of the inverter units is over-modulated; determining a voltage U.sub.0 required for grid connection for the cascaded photovoltaic grid-connected inverter corresponding to a current grid-connected current effective value; and adjusting an output active voltage of each of the inverter units according to U.sub.jd=P.sub.j/P.sub.0*U.sub.0d, and adjusting an output reactive voltage of each of the inverter units in a case that none of the inverter units is over-modulated.

A plurality of solar cells are sealed by an encapsulant between a first protective member and a second protective member. A fixing member fixes, among the plurality of solar cells, a first solar cell and a second solar cell that are adjacent to each other. The fixing member includes a release surface and a non-release surface that are oriented in opposite directions. The non-release surface has disposed thereon a first bonding region and a second bonding region that have adhesive strength, and a non-bonding region different from the first bonding region and the second bonding region.

A photovoltaic module has a flexible backing substrate, a plurality of photovoltaic cells, and an electrical conduit. The photovoltaic cells are mounted on the backing substrate. Each photovoltaic cell has a metallic article, the metallic article including a plurality of electroformed elements comprising a cell interconnection element integral with a continuous grid having a plurality of first elements intersecting a plurality of second elements. The electroformed elements are interconnected and integral, with the continuous grid in contact with the light-incident surface of the photovoltaic cell. The cell interconnection element extends beyond the light-incident surface and couples the continuous grid to a neighboring photovoltaic cell. The electrical conduit has a flexible strip of electrically conductive material. The electrical conduit electrically couples the cell interconnection element of a first photovoltaic cell in the plurality of photovoltaic cells to a neighboring second photovoltaic cell in the plurality of photovoltaic cells.

The present disclosure provides a solar cell module, comprising (a) a laminate substrate having a first surface and a second surface opposite the first surface, (b) a solar cell positioned on the first surface of the laminate substrate, (c) a first contact pad positioned on the first surface of the laminate substrate adjacent to the solar cell, (d) a second contact pad positioned on the second surface of the laminate substrate, (e) one or more vias positioned through the laminate substrate to electrically connect the first contact pad to the second contact pad, and (f) one or more interconnects extending from the solar cell and electrically coupling the solar cell to the first contact pad.

A high efficiency configuration for a solar cell module comprises solar cells arranged in a shingled manner to form super cells, which may be arranged to efficiently use the area of the solar module, reduce series resistance, and increase module efficiency. The solar cell module may comprise for example a series connected string of N greater than or equal to 25 rectangular or substantially rectangular solar cells having on average a breakdown voltage greater than about 10 volts, with the solar cells grouped into one or more super cells each of which comprises two or more of the solar cells arranged in line with long sides of adjacent solar cells overlapping and conductively bonded to each other, and with no single solar cell or group of <N solar cells in the string of solar cells individually electrically connected in parallel with a bypass diode.

A photovoltaic array includes a two-dimensional array of photovoltaic cells having a plurality of rows, each row having a pivot axis parallel to the row. Each cell has a lens which has a front surface configured to concentrate light normal to the front surface onto the photovoltaic element. The photovoltaic array further includes a rotational actuator, coupled to the array of photovoltaic cells configured to rotate the array of photovoltaic cells about an axis perpendicular to a plane defined by the array of photovoltaic elements and a tilt actuator, coupled to each of the rows of photovoltaic elements configured to pivot the rows of photovoltaic elements about their pivot axes.

In a solar cell module, a plurality of solar cells are provided between a front surface protection member and a back surface protection member and bus bar electrodes 20 of the plurality of solar cells are electrically connected to each other by wiring members. The solar cell module includes an adhesive layer made of a resin 60 containing a plurality of conductive particles 70, the adhesive layer provided between each of the bus bar electrodes 20 and the wiring member 40. Each of the bus bar electrodes 20 and the corresponding wiring member 40 are electrically connected by the plurality of conductive particles 70. The resin 60 covers side surface of each of the bus bar electrodes 20 and configured to bond the wiring member 40 with the surface of a photoelectric conversion body 10.

The present disclosure provides methods of fabricating a multijunction solar cell panel in which one or more of the steps are performed using an automated process. In some embodiments, the automated process uses machine vision.

A plurality of solar cells are arranged in a first direction and each provided with first and second electrodes on a one main surface side thereof. A wiring member includes a conductive layer and a resin sheet supporting the conductive layer, the conductive layer electrically connecting the first electrode of one of the solar cells adjacent to each other in the first direction to the second electrode of another one of the solar cells. An adhesive layer bonds the wiring member to each of the solar cells. The wiring member includes a first bonded portion bonded to the one solar cell via the adhesive layer, a second bonded portion bonded to the other solar cell via the adhesive layer, and a connection portion connecting the first bonded portion and the second bonded portion together, and an opening is provided in the conductive layer in the connection portion.