A ventilating and heat dissipating assembly for a roof includes hollow bricks, first corrugated plates and second corrugate plates. Each first corrugated plate spans a gap between two pairs of the hollow bricks that are spaced apart along intersecting first and second directions. Each second corrugated plate spans a gap formed between two of the hollow bricks spaced apart in the first direction and a gap between two of the first corrugated plates spaced apart in the second direction.

A hollow brick includes a bottom wall, two side walls projecting from the bottom wall, a plurality of intermediate walls projecting from the bottom wall between the side walls, and a top wall opposite to the bottom wall and connecting the side walls and the intermediate walls. A plurality of ventilation holes is bounded by the bottom wall, the side walls, the intermediate walls and the top wall. Each ventilation hole has two ventilation open ends opposite to each other along the transverse sides of the bottom wall. Two outer holding ribs projects respectively from outer surfaces of the side walls in opposite outward directions.

A hollow brick includes a bottom wall, two side walls projecting from the bottom wall, a plurality of intermediate walls projecting from the bottom wall between the side walls, a top wall opposite to the bottom wall and connecting the side walls and the intermediate walls, and a plurality of ventilation holes bounded by the bottom wall, the side walls, the intermediate walls and the top wall. The bottom wall has a plurality of foot portions projecting downwardly and spaced apart from each other. A bottom groove is formed between two adjacent ones of the foot portions.

Systems and modular devices for roof or ground-level stormwater management are disclosed. A modular stormwater management device includes a water retention mat structured to absorb stormwater, a rigid frame structured to support the water retention mat, and a perforated surface structured to permit drainage of the stormwater from the water retention mat through the perforated surface. A modular stormwater management system includes a plurality of modular stormwater management devices, each of the modular stormwater management devices including a water retention mat structured to absorb stormwater, a rigid frame structured to support the water retention mat, and a perforated surface structured to permit drainage of the stormwater from the water retention mat through the perforated surface.

The disclosure relates to an outdoor flooring assembly for securing flooring trays to improve stability and wind uplift resistance. The flooring trays each include a plurality of securement mechanisms coupled to a bottom surface thereto, the securement mechanisms designed to interconnect with one another to securely retain adjacent trays together and minimize the risk that any individual tray is dislodged.

A waterproof connecting structure is used in coordination with a solar panel array in order to construct a vertical wall or a rooftop panel of a building. The waterproof connecting structure comprises two half components and a connecting component. The two half components are disposed between the two solar panels. The connecting component covers a joint between the two half components so that rainwater flowed into a conduit passage formed by each of the half components is guided out. Thereby, the rainwater is prevented from infiltrating into a building.

Certain exemplary embodiments can provide a system, device, method, and/or composition of matter configured and/or adapted to manage water received upon a raised pedestal paver system, the raised pedestal paver system comprising an array of elongate pedestals, the raised pedestal paver system further comprising substantially planar array of pavers, each pedestal from the array of elongate pedestals configured to partially vertically support at least two substantially adjacent pavers from the array of pavers.

In one aspect of a bottom indexing tile and support structure, a bottom indexing support structure may be engaged with a top portion of a pedestal. The bottom indexing support structure may be formed with a generally vertical spine having at least one rail extending outward from a distal end thereof and may also include one or more ridges extending upward in a direction parallel to the spine. The spine and rail(s) may be configured to secure one or more bottom indexing tiles, which tiles may be formed with a groove on at least one edge thereof, and wherein one or more rails may be positioned within the groove. The bottom indexing tile may be formed with one or more channels on a bottom surface thereof, wherein each channel may correspond with a ridge of the bottom indexing support structure.

A self supporting panel system used to fabricate ceilings, floors, walls, or roofs. The panel system is assembled from a plurality of panels, each having a core that is sandwiched between opposing plate members. In a preferred embodiment, the core of each panel includes a unifying material to enhance the load bearing capacity of the panel.

A self supporting panel system used to fabricate ceilings, floors, walls, or roofs. The panel system is assembled from a plurality of panels, each having a core that is sandwiched between opposing plate members. In a preferred embodiment, the core of each panel includes a unifying material to enhance the load bearing capacity of the panel.