A method of manufacture of a photovoltaic solar roof tile assembly can include forming a laminated structure by laminating one or more sheets that include at least one photovoltaic solar cell, and attaching a junction box to the laminated structure to form a photovoltaic solar panel. The junction box can include a first DC connector and a second DC connector. Attaching the junction box to the laminated structure can include sealing the first DC connector to the laminated structure. The method of manufacture can include forming a roof tile with a hole that extends from a front side of the roof tile to a rear side of the roof tile, and locating the junction box in the hole by inserting the first DC connector from a front side of the roof tile and attaching the second DC connector from the rear side.

The invention relates to a fastening structure for being able to fit a coupling profile, in particular for fastening solar panels, to a pitched roof covered with bituminous shingles. The invention also relates to an assembly which includes a fastening structure according to the invention. The invention further relates to a kit of components which includes a fastening structure according to the invention. The invention further relates to a method for fitting a coupling profile, in particular for fastening solar panels, to a pitched roof covered with bituminous shingles, by using a fastening structure according to the invention.

Building integrated photovoltaic (BIPV) systems provide for solar panel arrays that can be aesthetically pleasing and appear seamless to an observer. BIPV systems can be incorporated as part of roof surfaces as built into the structure of the roof, flush or forming a substantively uniform plane with roof panels or other panels mimicking a solar panel appearance. Pans supporting BIPV solar panels can be coupled by standing seams, in both lateral and longitudinal directions, to other photovoltaic-supporting pans or pans supporting non-photovoltaic structures, having both functional and aesthetic advantages. In some configurations, adjacent photovoltaic modules may be oriented so that a boundary between an up-roof photovoltaic module and a down-roof photovoltaic module is not noticeable by observers positioned at typical viewing angles of the roof.

A solar assembly includes a single-slope crossbeam, a plurality of clip angle brackets, and a plurality of photovoltaic (PV) modules. Each PV module is supported by at least two of the plurality of clip angle brackets, and a height of the plurality of angle brackets differ from each other in order to allow the PV modules to be shingled.

A roof integrated solar power system includes a plurality of solar modules. Each solar module carries a photovoltaic or solar panel with solar cells. Edge regions of the solar module are disposed to the sides of the solar panel and are devoid of solar cells. An electrical component such as a junction box or micro-inverter, or DC optimizer is mounted on top of the solar module within at least one of the edge regions. Cabling for interconnecting the electrical component to electrical components of others of the plurality of solar modules also is located within the side regions. In one embodiment, the electrical component and cabling is disposed within a recess within a side region and covered by a flat access panel. In another embodiment, the electrical component and cabling is located atop the side region and is covered by an access panel in the form of a protective cover strip. The solar modules are installable on a roof in aligned or staggered courses to form the solar power system, and with the installed courses of modules together forming a water barrier protecting the roof.

Building integrated photovoltaic (BIPV) systems provide for solar panel arrays that can be aesthetically pleasing and appear seamless to an observer. BIPV systems can be on-roof systems, elevated from the surface of a roof, being flush or forming a substantively uniform plane with roof panels or other panels mimicking a solar panel appearance. Pans supporting BIPV solar panels can be coupled by standing seams to other photovoltaic-supporting pans or pans supporting non-photovoltaic structures, having both functional and aesthetic advantages. In some configurations, inverted seams can couple photovoltaic-supporting pans and non-photovoltaic structures, forming a substantively planar surface. In some configurations, the appearance of BIPV systems can be particularly aesthetically pleasing and generally seamless to an observer.

A roof integrated solar power system includes a plurality of solar modules. Each solar module carries a photovoltaic or solar panel with solar cells. Edge regions of the solar module are disposed to the sides of the solar panel and are devoid of solar cells. An electrical component such as a junction box or micro-inverter, or DC optimizer is mounted on top of the solar module within at least one of the edge regions. Cabling for interconnecting the electrical component to electrical components of others of the plurality of solar modules also is located within the side regions. In one embodiment, the electrical component and cabling is disposed within a recess within a side region and covered by a flat access panel. In another embodiment, the electrical component and cabling is located atop the side region and is covered by an access panel in the form of a protective cover strip. The solar modules are installable on a roof in aligned or staggered courses to form the solar power system, and with the installed courses of modules together forming a water barrier protecting the roof.

A system including a plurality of photovoltaic modules and a plurality of roofing shingles installed on a roof deck. Each of the photovoltaic modules includes a plurality of solar cells. Each of the plurality of roofing shingles includes a core layer and a cap layer composed of a first polymer material and having a first surface and a pattern printed on the first surface. The pattern includes a depiction of a plurality of solar cells that extends between the first end and the second end.

Provided is a solar battery module easy to assemble. A solar battery module includes a connecting member, the connecting member includes a conductor disposed along an end of a first solar battery string and connected to the first solar battery string and a conductor disposed along an end of a second solar battery string and connected to the second solar battery string, and the first solar battery string and the second solar battery string are electrically connected.

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 photovoltaic tiles. Each photovoltaic module may comprise a photovoltaic laminate, a support arm and a mounting bracket. When installed an assembly of the photovoltaic laminate and support arm are rotatably attached to the mounting bracket allowing access under the array of photovoltaic modules.