Reconfigurable PV panels can have features that include cut lines for separating full panels into smaller subpanels, connector ribbons for assembling several reconfigurable PV panels into a one-dimensional or two-dimensional array and can be stacked upon each other and unstacked by rotating them about a shared connection.

Reconfigurable PV panels can have features that include cut lines for separating full panels into smaller subpanels, connector ribbons for assembling several reconfigurable PV panels into a one-dimensional or two-dimensional array and can be stacked upon each other and unstacked by rotating them about a shared connection.

Various processes can apply pressure and/or heat to a photovoltaic (PV) layer, including processes that integrate solar cells into different types of industrial glass such as an autoclave lamination process. The disclosure describes a planarization technique that can be used on the PV layer to eliminate point loads caused by such processes. In an aspect, a method for producing a component is described that includes disposing or placing a planarization material on a PV layer, modifying a physical form of the planarization material to provide a planar surface made of the planarization material on one side of the PV layer having surface irregularities, and forming a stack of layers (e.g., as part of an autoclave lamination process) for the component by disposing a first layer over the planar surface on the one side of the PV layer and a second layer over the other, opposite side of the PV layer.

Various processes can apply pressure and/or heat to a photovoltaic (PV) layer, including processes that integrate solar cells into different types of industrial glass such as an autoclave lamination process. The disclosure describes a planarization technique that can be used on the PV layer to eliminate point loads caused by such processes. In an aspect, a method for producing a component is described that includes disposing or placing a planarization material on a PV layer, modifying a physical form of the planarization material to provide a planar surface made of the planarization material on one side of the PV layer having surface irregularities, and forming a stack of layers (e.g., as part of an autoclave lamination process) for the component by disposing a first layer over the planar surface on the one side of the PV layer and a second layer over the other, opposite side of the PV layer.

A solar cell panel can include a plurality of solar cells; and a diode member connected to the plurality of solar cells, the diode member being formed of a solar cell unit disposed within the solar cell panel under at least a portion of one of the plurality of solar cells at a non-light-incident region.

A solar cell panel can include a plurality of solar cells; and a diode member connected to the plurality of solar cells, the diode member being formed of a solar cell unit disposed within the solar cell panel under at least a portion of one of the plurality of solar cells at a non-light-incident region.

A multijunction solar cell including an upper first solar subcell having a first band gap and positioned for receiving an incoming light beam; a second solar subcell disposed below and adjacent to and lattice matched with said upper first solar subcell, and having a second band gap smaller than said first band gap; wherein the upper first solar subcell covers less than the entire upper surface of the second solar subcell, leaving an exposed portion of the second solar subcell around the periphery of the multijunction solar sell that lies in the path of the incoming light beam.

A multijunction solar cell including an upper first solar subcell having a first band gap and positioned for receiving an incoming light beam; a second solar subcell disposed below and adjacent to and lattice matched with said upper first solar subcell, and having a second band gap smaller than said first band gap; wherein the upper first solar subcell covers less than the entire upper surface of the second solar subcell, leaving an exposed portion of the second solar subcell around the periphery of the multijunction solar sell that lies in the path of the incoming light beam.

An assembly for optical to electrical power conversion including a photodiode assembly having a substrate layer and an internal side, an antireflective layer, a heterojunction buffer layer adjacent the internal side; an active area positioned adjacent the heterojunction buffer layer, a plurality of n+ electrode regions and p+ electrode regions positioned adjacent the active area, and back-contacts configured to align with the n+ and p+ electrode regions. The active area converts photons from incoming light into liberated electron hole pairs. The heterojunction buffer layer prevents electrons and holes of the liberated electron hole pairs from moving toward the substrate layer. The plurality of electrode regions are configured in an alternating pattern with gaps between each n+ and p+ electrode region. The electrode regions receive and generate electrical current from migration of the electrons and the holes, provide electrical pathways for the electrical current, and provide thermal pathways to dissipate heat.

A solar module assembly includes a frame having an upper portion encompassing an area and a mid portion disposed below the upper portion. A plurality of solar panels is arranged in a string, sandwiched between two transparent panes forming a single string panel. The solar panels occupy less than the area of the upper portion. Each of the plurality of solar panels has a pair of opposing edges. A reflector is mounted on the mid portion to reflect light selectively.