Disclosed is a roofing underlayment providing mechanical and electrical connection for solar shingles that includes a water-impervious membrane adapted to be attached to a roof. The underlayment also includes a mechanical attachment member configured to mechanically attach a solar shingle to the roof, as well as an electrical conductor having an electrical first portion of which is embedded within the membrane, having an electrical second portion which is configured to electrically connect to a solar shingle, and having an electrical third portion which is configured to electrically connect to an electrical circuit. An air gap is provided that allows for air flow below the solar shingles. The air gap comprises a space between a bottom surface of the solar shingles and a bottom surface of the membrane.

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.

A roofing system features a plurality of roofing sheets each having an outer perimeter of which two opposing perimeter edges respectively define a fastening edge and a hooking edge. One or more fastening holes penetrate the sheet near the fastening edge. At the hooking edge, the sheet is bent under itself to form a hooking portion reaching back toward the fastening edge. A plurality of hold-downs are placed atop a first row of roofing sheets near the fastening edges thereof, and have apertures aligned with the fastening holes of the roofing sheets, through which the hold-downs are fastened to the a roof deck. The hooking edges of a next row of roofing sheets hook to the affixed hold-downs of the first row, thus coupling the two rows of sheets together and concealing the first row's fastened connection to the roof deck beneath the second row.

Tile fixing devices, tile mounting methods, and roofs, such as those associated with solar tiles, are provided. For example, tile fixing devices related to the technical field of photovoltaic power generation are provided. In one illustrative implementation, a tile fixing device may include: a tile hook which is provided thereon with a fixing piece configured to cooperate with the mounting hole of the tile, as well as a positioning structure configured to limit the tile batten. Various tile mounting methods and roofs are also disclosed.

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 modules having the appearance of a plurality of roofing tiles that each have photovoltaic cells. Each photovoltaic module may include a metal backer, photovoltaic cells, and light transmissive top sheets adhered to both the metal backer and the photovoltaic cells. BIPV systems can also include non-photovoltaic modules that appear similar to photovoltaic modules, but do not collect solar energy.

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.

A roof panel includes a planar body having top and bottom edges, with a downturn edge extending therebetween, and an opposing channel edge. The downturn edge overlays a channel edge of an adjacent panel. The bottom edge overlays a top edge of another adjacent panel. A plurality of courses extends between the channel and downturn edges. Each course includes a nesting ridge to receive the downturn edge of an adjacent panel and to position a top surface of the panel flush with adjacent panels. Surface channels and contoured ridges are defined within each course. A drain aperture of the drip edge aligns with an adjacent channel edge to direct material through the drain aperture and onto adjacent panels. A gable member engages an edge when the panel has one or fewer laterally adjacent panels, wherein the gable member is flush with the adjacent planar body.

A roof panel includes a planar body having top and bottom edges, with a downturn edge extending therebetween, and an opposing channel edge. The downturn edge overlays a channel edge of an adjacent panel. The bottom edge overlays a top edge of another adjacent panel. A plurality of courses extends between the channel and downturn edges. Each course includes a nesting ridge to receive the downturn edge of an adjacent panel and to position a top surface of the panel flush with adjacent panels. Surface channels and contoured ridges are defined within each course. A drain aperture of the drip edge aligns with an adjacent channel edge to direct material through the drain aperture and onto adjacent panels. A gable member engages an edge when the panel has one or fewer laterally adjacent panels, wherein the gable member is flush with the adjacent planar body.

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 modules having the appearance of a plurality of roofing tiles that each have photovoltaic cells. Each photovoltaic module may include a metal backer, photovoltaic cells, and light transmissive top sheets adhered to both the metal backer and the photovoltaic cells. BIPV systems can also include non-photovoltaic modules that appear similar to photovoltaic modules, but do not collect solar energy.