A screen installation comprising a screen cloth assembly (22) with a screen cloth (7) and at least one flat strip (21) fastened to the screen cloth, as well as screen sections (8, 18), to opposite edges of the screen cloth, at least one screen section of which has an undercut chamber (20) and a longitudinal opening (23) that opens into this chamber, wherein the strip is accommodated in the chamber of the at least one screen section so that the screen cloth fastened to it can extend outwards from it through the longitudinal opening of the screen section. The strip (21) is fastened at a distance from the adjacent free edge of the screen cloth (7) in the form of a free screen cloth flap (19). The screen cloth flap extends from the strip and via the longitudinal opening (23) of the at least one screen section (8, 18) outwards from it.

A screen installation comprising a screen cloth assembly (22) with a screen cloth (7) and at least one flat strip (21) fastened to the screen cloth, as well as screen sections (8, 18), to opposite edges of the screen cloth, at least one screen section of which has an undercut chamber (20) and a longitudinal opening (23) that opens into this chamber, wherein the strip is accommodated in the chamber of the at least one screen section so that the screen cloth fastened to it can extend outwards from it through the longitudinal opening of the screen section. The strip (21) is fastened at a distance from the adjacent free edge of the screen cloth (7) in the form of a free screen cloth flap (19). The screen cloth flap extends from the strip and via the longitudinal opening (23) of the at least one screen section (8, 18) outwards from it.

A system for harvesting rainwater for use in a skirt building. The skirt building includes a main building and a podium supporting the main building. The system includes: a standpipe; a buffer channel; a filter channel; and a green roof. The green roof includes a vegetation region including a baffled diversion corridor, and a bottom filtering layer including a drainage pipe. The standpipe is arranged on the main building and is connected to the buffer channel where the energy of rainwater flowing out of the standpipe is dissipated. The buffer channel, the filter channel, and the green roof are arranged on the podium, and the buffer channel communicates with the filter channel. The filter channel is connected to the green roof. The filter channel is divided into a plurality of sections respectively filled with different matrix materials.

A Z-closure member for raised seam roofs is formed through bending techniques into a shape having a ventilated central vertical member, an upper mounting flange having a return upper retainer member terminating rearwardly of the central member, and a lower flange extending from said central member and terminating rearwardly thereof to define a cavity for the insertion of a filter against the central member. A plurality of filter retention devices are disclosed for restraining movement of the filter, including adhesive placed on said central opening, an upper tab integrally formed with said upper retainer member and extending downwardly therefrom, a flexible locking tab formed as a return from said lower flange and terminating at said cavity, and a raised retention dimple formed in the lower flange adjacent the cavity. An optional rearwardly and upwardly extending deflector member extends from said lower flange to deflect rain passing through the filter.

A planting baseplate assembly comprises a base, a water storage device, and a diversion element. The base includes a base body; a drain hole penetrating the upper and lower surfaces of the base body, wherein a connection member extends downward from the lower surface of the base body; a plurality of water guiding trenches mutually intersecting on the upper surface of the base body and interconnecting with the drain holes for water drainage; and a plurality of overflow holes disposed in and penetrated the water guiding trenches for water drainage. The water storage device includes a storage body and a connection neck to fix with the connection member. The diversion element is inserted through the drain hole and extended to the water storage device. The planting baseplate assembly is easy to assemble, favorable to environmental protection, and applicable to green roofs and various planting apparatuses.

A radiant barrier system may reduce heat flow into a structure. A radiant barrier system may include at least one internal airspace positioned between at least two radiant barrier layers having a reflectivity rating of at least 90%, the at least two radiant barrier layers comprising a layer positioned on top of the at least one internal airspace that reduces radiant heat flow by emissivity and a layer positioned below the at least one internal airspace that reduces radiant heat flow by reflectivity. A radiant barrier system may be incorporated between roofing products such as flexible roofing underlayments, sheet goods (i.e., plastic, metal or fiberglass), and wood products (i.e., plywood or oriented strand board (OSB)) and combinations thereof A radiant barrier system also may be integrated into wall products.

A green roof modular system includes at least four planter modules each including a planter including a bottom wall and a plurality of sidewalls that cooperate with the bottom wall to form an interior space, and a biodegradable insert including a plurality of sidewalls that cooperate with one another to form an interior space, wherein the insert is adapted to retain a plant matter in the interior space of the insert, the plurality of sidewalls of the insert extending above the plurality of sidewalls of the planter, and wherein the plurality of the sidewalls of the insert are adapted to retain a plant matter that extends above the plurality of sidewalls of the planter, such that one of the planter modules abuts each of the remaining three planter modules and substantially no gap exists between the abutting planter modules in plan view.

In an embodiment, a method includes applying a liquid plural component polymer to a sloped roof to form a protective surface that inhibits moisture seepage to the roof sheathing. In some embodiments, the plural component polymer may be a polyurea compound having a hardening time that is less than approximately 10 minutes. In some embodiments, one or more of the components may be aerated prior to application to the roof substrate. In some embodiments, one or more polystyrene panels may be affixed to the sloped roof prior to application of the liquid plural component polymer. Other embodiments are described and claimed.

A mounting system for supporting a plurality of photovoltaic modules on a sloped support surface, such as a sloped roof, is disclosed herein. The mounting system may include one or more support surface attachment devices, each support surface attachment device configured to attach one or more photovoltaic modules to a support surface; and one or more module coupling devices, each module coupling device configured to couple a plurality of photovoltaic modules to one another.

A mounting system for supporting a plurality of photovoltaic modules on a sloped support surface, such as a sloped roof, is disclosed herein. The mounting system may include one or more support surface attachment devices, each support surface attachment device configured to attach one or more photovoltaic modules to a support surface; and one or more module coupling devices, each module coupling device configured to couple a plurality of photovoltaic modules to one another.