A Wind uplift strap for securing a coverage structure. The Wind uplift strap including one or more metal strips having a thickness between 0.50 mm and 1.1 mm, substantially equal to that of the coverage structure, and a width between approximately 15 mm and 50 mm, depending on the load to be supported. The Wind uplift strap having a slightly angled fold in more than 90, forming a flap at one of its ends. The Wind uplift strap further comprising a main body, a flap, a hole for fixing the flap, a fold line of the flap, and a hole at an end of the main body that is opposite the flap.

A Wind uplift strap for securing a coverage structure. The Wind uplift strap including one or more metal strips having a thickness between 0.50 mm and 1.1 mm, substantially equal to that of the coverage structure, and a width between approximately 15 mm and 50 mm, depending on the load to be supported. The Wind uplift strap having a slightly angled fold in more than 90, forming a flap at one of its ends. The Wind uplift strap further comprising a main body, a flap, a hole for fixing the flap, a fold line of the flap, and a hole at an end of the main body that is opposite the flap.

A metal roof panel includes a rib with a unique shape. The rib is bilateral with upwardly angled sides that each transition into an indentation, with both indentations transitioning into a central flat apex. Between each rib is a channel, preferably including at least one raised surface. The lower surface of the channel between the raised surfaces, and the top of the raised surfaces, are substantially planar and parallel to the flat surface of the apex of the panel. A unique method of manufacturing the roof panel employs a roll machine configured to shape a piece of sheet metal into the roof panel by modifying the shape in many small increments, which allows the final product to have a fairly intricate bend pattern.

A metal roof panel includes a rib with a unique shape. The rib is bilateral with upwardly angled sides that each transition into an indentation, with both indentations transitioning into a central flat apex. Between each rib is a channel, preferably including at least one raised surface. The lower surface of the channel between the raised surfaces, and the top of the raised surfaces, are substantially planar and parallel to the flat surface of the apex of the panel. A unique method of manufacturing the roof panel employs a roll machine configured to shape a piece of sheet metal into the roof panel by modifying the shape in many small increments, which allows the final product to have a fairly intricate bend pattern.

An apparatus is contemplated for creating a structure which simultaneously serves as both a building element and a photovoltaic power source. Components of the invention interface with modules which comprise photovoltaic solar panels. When used collectively, these modules are contemplated as comprising a replacement for a roof or other building component. When the present invention is used, a roof or other building component can be created without the need for a separate underlayment, and without the need for tiles or another outer waterproofing layer. This setup results in power generation, cost savings, and environmental advantages. Additionally, embodiments of the invention comprise fixed stop elements which ensure correct placement of modules on a frame assembly. The invention could also include other elements, including water gutters, grab steps which facilitate access, and specially positioned border covers to protect and aesthetically cover wired regions of solar modules.

An apparatus is contemplated for creating a structure which simultaneously serves as both a building element and a photovoltaic power source. Components of the invention interface with modules which comprise photovoltaic solar panels. When used collectively, these modules are contemplated as comprising a replacement for a roof or other building component. When the present invention is used, a roof or other building component can be created without the need for a separate underlayment, and without the need for tiles or another outer waterproofing layer. This setup results in power generation, cost savings, and environmental advantages. Additionally, embodiments of the invention comprise fixed stop elements which ensure correct placement of modules on a frame assembly. The invention could also include other elements, including water gutters, grab steps which facilitate access, and specially positioned border covers to protect and aesthetically cover wired regions of solar modules.

A metal roof panel includes a rib with a unique shape. The rib is bilateral with upwardly angled sides that each transition into an indentation, with both indentations transitioning into a central flat apex. Between each rib is a channel, preferably including at least one raised surface. The lower surface of the channel between the raised surfaces, and the top of the raised surfaces, are substantially planar and parallel to the flat surface of the apex of the panel. A unique method of manufacturing the roof panel employs a roll machine configured to shape a piece of sheet metal into the roof panel by modifying the shape in many small increments, which allows the final product to have a fairly intricate bend pattern.

A metal roof panel includes a rib with a unique shape. The rib is bilateral with upwardly angled sides that each transition into an indentation, with both indentations transitioning into a central flat apex. Between each rib is a channel, preferably including at least one raised surface. The lower surface of the channel between the raised surfaces, and the top of the raised surfaces, are substantially planar and parallel to the flat surface of the apex of the panel. A unique method of manufacturing the roof panel employs a roll machine configured to shape a piece of sheet metal into the roof panel by modifying the shape in many small increments, which allows the final product to have a fairly intricate bend pattern.

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.

Present invention relates to the field of Building Integrated Solar systems that help in generating electricity. It is a solar board that can be used as a roof, faade or other building applications. It also relates to a method of preparing, designing and producing the Solar Cement Boards by integrating the Cement boards with that of solar panels to form an envisaged single entity. The Solar Cement Board SCB comprises a plurality of Solar energy capturing components like Photo Voltaic (PV) cells or the like, sandwiched over specially treated Fiber cement board or the likes. The SCB comprises of a toughened glass and/or a thin film on top, ethylene vinyl acetate film as an encapsulate in the middle, and polyvinyl fluoride film as a back sheet. The SCB with top, middle and a back sheet is laminated together with Fiber cement board or the like providing a water-resistant enclosure. This is ultimately a unique integrated solar product.