A vent assisted system for reroofing a built up roof surface or a single ply membrane roof covering including an augmented design incorporating mechanical fasteners and an adhesive for attaching strips of single ply membrane or fleece backed single ply membrane in the turbulent vortex areas along the perimeter of a deck. Coupled with roof vents for equalizing the pressure under loose laid sheets of single ply membrane or fleece backed single ply membrane in the field-of-roof area bordering the turbulent wind vortex areas to reduce membrane stress and resist wind uplift pressures during high wind events.

Ridge vents and deck covers are disclosed that have a fibrous mesh mat and a moisture barrier. The mesh mat may be contoured to define a variety of structures and may have regions of relatively higher fiber density and regions of relatively lower fiber density. Solar cells may be exposed on the ridge vents to collect solar energy when the vents are exposed to sunlight.

A converted reverse ballasted roof system is provided including a structural roof beam. Insulation is positioned upwardly adjacent the structural roof beam, and a first waterproofing membrane is arranged upwardly adjacent the first waterproofing membrane. A weighted cover board is disposed upwardly adjacent the first waterproofing membrane and a second waterproofing membrane is installed upwardly adjacent the weighted cover board. The first water proofing membrane and the second waterproofing membrane substantially seal the weighted cover board.

Ridge vents and deck covers are disclosed that have a fibrous mesh mat and a moisture barrier. The mesh mat may be contoured to define a variety of structures and may have regions of relatively higher fiber density and regions of relatively lower fiber density. Solar cells may be exposed on the ridge vents to collect solar energy when the vents are exposed to sunlight.

A roof construction method using expanded metal lath laid on top of corrugated metal roof deck for the purpose of creating ventilation ducts in the valleys of the corrugated metal deck. The ventilation ducts created are vented to the building space below through vent slots in the valleys of the metal roof deck. A concrete slab with finished rubber roof poured in top of this roof deck with ventilation ducts will have enhanced ability to release moisture trapped from the concrete curing process.

A barrier material has an upper, radiant barrier layer and a lower, corrugated surface layer. The radiant barrier layer is preferably a metalized film or an aluminum sheet with an emissivity rating 0.1 or less. The metalized film is laminated to one side of a middle layer using a high, heat-resistant adhesive. The corrugated surface layer, which can receive an insulating material, is preferably a corrugated medium. The corrugated medium is laminated to the other side of the middle layer with a water-resistant adhesive. The middle layer is preferably a fire-resistant, kraft linerboard. The barrier creates an air space or plenum between an external structure and the insulating material designed to prevent heat transfer between an insulated space and the external structure.

A vent assisted system for reroofing a built up roof surface or a single ply membrane roof covering including an augmented design incorporating mechanical fasteners and an adhesive for attaching strips of single ply membrane or fleece backed single ply membrane in the turbulent vortex areas along the perimeter of a deck. Coupled with roof vents for equalizing the pressure under loose laid sheets of single ply membrane or fleece backed single ply membrane in the field-of-roof area bordering the turbulent wind vortex areas to reduce membrane stress and resist wind uplift pressures during high wind events.

A venting method and arrangement for a roof includes a plurality of venting stacks each having a first open base end open to an area on top of the roof insulation layer and below the roof outer membrane, the venting stacks arranged spaced apart around a perimeter of the roof. A venting path grid of air permeable material is arranged between the roof membrane and the insulation layer. The grid is in air flow communication with the first open base ends. Centrally located wind-driven turbine ventilators can also be in air flow communication to the grid.

A roof system includes a roof deck and a plurality of roof rafters supporting the roof deck. A thermal break is located between the deck and a first rafter of the plurality of rafters. The thermal break includes a break inner member contacting a first rafter exterior surface of the first rafter and a break outer member contacting a deck inner surface of the roof deck. The break inner member and the break outer member bound a thermal air break therebetween.

The subject of the present application is an arrangement of sandwich panels already used in buildings in a way that makes them capable of collecting solar radiation and ambient heat and transferring the energy out of the roof. The structural elements of the present invention consist of a heat insulating core sandwiched between external and internal sheets with load-bearing capacity, similar to the make-up of the known load-bearing sandwich panels. Whether the sheet profiles are placed in the direction of the ridge beam or of the rafters, with the appropriate set of them, hollow structure is created on the surface and in the core of the panel in the direction of the rafters, in the entire length of the roof, functioning as pathways for gaseous materials (air ducts (1, 4)). If these air ducts, both external and in the core, are connected at the end facing each other, i.e. at the upper air turn chamber (8), the substance in them will start to flow on its own using solely gravitational forces in reaction to heat reaching the panel's external surface, i.e. the external profiled metal sheet (2). If a given point of the panel is cooled by heat exchanger (6), the spontaneous flow will remain continuous. Cooling transports the heat collected in the air ducts (hot air duct (1) and cold air duct (4)) out of the system, and this heat is utilized to provide for our energy needs. The subject of the application is, therefore a sandwich panel which functions as a thermal collector, hereinafter heat collector sandwich panel (3), which serves as the roof structure of a building, or is an integral part of the roof structure and meets without fail all protection requirements set for roof constructions. Due to its special design it is capable of collecting ambient heat, and transferring this heat to heat storage by the use of compatible, known auxiliary appliances.