Novel rigid tile, rigid tile apparatus, methods of making and use are disclosed. One embodiment includes a method of mounting rigid tile with a nail gun providing a protruding nail tip used as a nail passage or depression finder in the rigid tile. Another embodiment includes a metal roof tile having at least one fastener passage having pre-formed spacer section extending from the upper surface of the metal roof tile to space a fastener head or end from the upper surface of the metal roof tile. Yet another embodiment provides interconnectable rigid rooftiles, with the interconnection provided by upwardly extending channel structure that can allow adjacent rigid rooftiles to positionally adjusted on a roof laterally across the roof with respect to each other. A tile bottom-side covering sealing bent T-trim can be utilized to cover open underside areas of a right roof tile. A novel installation method and rigid rooftile installation kit can utilize embodiments of the structures and methods stated above and, as desired, yet additional structure such as differently structured rigid rooftile components and trim components of differing shapes and sizes as desired.

A tile replacement flashing is used with a tile hook. A bottom tile replacement flashing is shaped for placement on a lower portion of a location where a tile is removed from a roof. A top tile replacement flashing is shaped for placement on an upper portion of a location where the tile is removed from the roof. The top tile replacement flashing includes an elevated region at a lower portion of the top tile replacement flashing, the elevated region. The bottom tile replacement flashing is shaped so that after attachment of the bottom tile replacement flashing on the roof, the tile hook can be attached to a rafter of the roof, the attached tile hook extending over an upper portion of the bottom tile replacement flashing and having a portion that, past the upper portion of the bottom tile replacement flashing, extends upwards. The top tile replacement flashing is shaped so that after attachment of the top tile replacement flashing on the roof, at least part of the elevated region of the top tile replacement flashing extends over the bottom tile replacement flashing. A height of the elevated region is sufficient to allow room for the tile hook to extend over the bottom tile replacement flashing and under the elevated region of top tile replacement flashing.

A tile replacement flashing is used with a tile hook. A bottom tile replacement flashing is shaped for placement on a lower portion of a location where a tile is removed from a roof. A top tile replacement flashing is shaped for placement on an upper portion of a location where the tile is removed from the roof. The top tile replacement flashing includes an elevated region at a lower portion of the top tile replacement flashing, the elevated region. The bottom tile replacement flashing is shaped so that after attachment of the bottom tile replacement flashing on the roof, the tile hook can be attached to a rafter of the roof, the attached tile hook extending over an upper portion of the bottom tile replacement flashing and having a portion that, past the upper portion of the bottom tile replacement flashing, extends upwards. The top tile replacement flashing is shaped so that after attachment of the top tile replacement flashing on the roof, at least part of the elevated region of the top tile replacement flashing extends over the bottom tile replacement flashing. A height of the elevated region is sufficient to allow room for the tile hook to extend over the bottom tile replacement flashing and under the elevated region of top tile replacement flashing.

Load support structures for mounting a load atop a raised rib metal panel roof make use of relatively small, inexpensive, and easy-to-make adapter plugs as interfaces between the raised ribs and one or more component pieces or members of the load support structure, such as an upper diverter or a lower closure member. The adapter plug has an inner surface and an outer surface, the inner surface having an inner profile substantially matching or conforming to some or all of the profile of a particular style of rib profile. The outer surface of the adapter plug has a standardized shape, some or all of which is made to conform to an upper diverter, lower closure, and/or other component member of the load support structure.

Load support structures for mounting a load atop a raised rib metal panel roof make use of relatively small, inexpensive, and easy-to-make adapter plugs as interfaces between the raised ribs and one or more component pieces or members of the load support structure, such as an upper diverter or a lower closure member. The adapter plug has an inner surface and an outer surface, the inner surface having an inner profile substantially matching or conforming to some or all of the profile of a particular style of rib profile. The outer surface of the adapter plug has a standardized shape, some or all of which is made to conform to an upper diverter, lower closure, and/or other component member of the load support structure.

A solar power system for a metal shingled roof, including: a plurality of metal roofing shingles; and a plurality of solar module mounting assemblies, wherein each of the solar module mounting assemblies has upper and lower module cleats that support upper and lower solar module frames thereon such that the upper and lower module frames are both spaced apart in a direction parallel to the roof, and spaced apart in a direction perpendicular to the roof.

A solar power system for a metal shingled roof, including: a plurality of metal roofing shingles; and a plurality of solar module mounting assemblies, wherein each of the solar module mounting assemblies has upper and lower module cleats that support upper and lower solar module frames thereon such that the upper and lower module frames are both spaced apart in a direction parallel to the roof, and spaced apart in a direction perpendicular to the roof.

A roof assembly, having: a roof deck; an insulation board assembly mounted onto the roof deck; and a roofing membrane adhered onto the insulation board assembly, wherein the insulation board assembly comprises: a foam insulation board, a woven top facer on a top side of the foam insulation board, and a woven bottom facer on a bottom side of the foam insulation board.

A roof assembly, having: a roof deck; an insulation board assembly mounted onto the roof deck; and a roofing membrane adhered onto the insulation board assembly, wherein the insulation board assembly comprises: a foam insulation board, a woven top facer on a top side of the foam insulation board, and a woven bottom facer on a bottom side of the foam insulation board.

A unique method and apparatus for metal valley installation that waterproofs shingled roof applications in valley (e.g., such as “V” or “W” metal valley angled roof) applications. Applicant's invention provides a membrane situated between the metal valley and the shingles with a portion of the membrane being situated and secured to the roof deck between the ice and water shield and the shingles. The membrane creates a dead zone that collects or prevents ice and water from backing up from the roof valley over the metal valley, over the edge of the metal valley, and in between the ice and water shield and the shingles.