A thermal radiant barrier and methods of use are provided. The thermal radiant barrier includes a first elongated planar member and first and second walls projecting from opposite edges of the planar base. When in use, the thermal radiant base is affixed to the underside of roof decking with the first and second walls being affixed to the underside of the decking. An air passageway from the soffit vent along side the underside of the decking is created to permit the air to be channeled from the soffitt vent into the attic area alongside the decking. The temperature of the air is controlled by using material of an R-value recommended by the construction code of the region. The thermal radiant barrier may include a second elongated planar member hingeably connected to the first elongated planar member at an angle equal to the angel between the rafter and joist in a roofing structure. The second elongated member is positioned underlying Batt insulation in proximity to the soffitt vent and soffitt baffle. The second elongated member has an R-value recommended in the geographic location. In use, the R-value at an area of compressed insulation is given by the R-value of the second elongated member.

A collapsible air gap device and assembly. In one embodiment, the device comprises an upper plate, a lower plate, and a rib secured at the upper plate and at the lower plate. The result is a hybrid ventilation device adapted to ventilate an attic space in a variety of configurations.

A soffit panel attachment device includes a central portion, an attachment surface, a plurality of flanges, and a plurality of openings extending through the central portion. The attachment surface extends perpendicularly from the central portion at a first end of the central portion. First and second flanges extend parallel to the central portion to form a U-shaped channel sized and shaped to receive a soffit covering material. Two soffit panel attachment devices may be installed in opposing configurations such that the U-shaped channels are positioned to support opposite ends of a soffit panel material. The plurality of openings may be a grid of hexagonal or circular openings that provide airflow paths across the soffit panel material such as from an exterior space into an attic space above the soffit.

Vents are disclosed for covering openings on roofs. The disclosed vents cover openings on metal roofs and prevent moisture and objects from entering the opening while allowing air to pass therethrough. The vents disclosed herein also prevent moisture from entering the building through openings that can be created when the vents are attached to a roof. The vents include a cap, a collar, and a flashing configured to contact the roof. The vents can also include a screen placed between the cap and the collar. The collar can have arms formed on an upper portion thereof to facilitate connection of the collar to the cap. Feet can be formed on a bottom portion of the collar. Once the vent is fully assembled, the feet can be positioned underneath the flashing and can be the main connection point of the vent to a roof. Due to the design of this assembly, fasteners pass through the feet providing a sound and secure attachment to the roof. The feet are then covered from moisture, rain, and/or snow by a flashing, and the flashing is then secured by screws or other fasteners passing through the reinforcement material and through the flashing itself which provides a weatherproof seal.

A roof vent for ventilating the roof of a building to the atmosphere. The roof vent includes a flange portion to lay against the roof, the flange portion having an opening to let air vent from the interior of the building (e.g. an attic). The roof vent can optionally include a collar portion extending from the flange portion and enclosing, at least in part, about a periphery of the opening and a cap dimensioned and configured to cover over the opening (including the hole in the roof) and optionally over the collar portion. The cap is configured to provide a passage (between the flange portion and the cap) through which air can pass between the atmosphere and the opening. The roof vent also includes a corrugated filter plate, e.g. partially enclosed by the cap, and interposed between the central opening and the passage, the corrugated filter plate having a pore size sufficient to permit air to pass through but inhibit the passage of snow particles, cinder particles and/or water droplets there-through.

Devices and associated methods are provided for improving ventilation of insulation material and building construction and renovation. Specifically, the present disclosure includes devices and system(s) to achieve the ventilation of exterior walls and roofs. Components of the system(s) consider shut-down of the ventilation process when it is not necessary, such as in winter, and in the event of fire, where the prevention of vertical and horizontal fire spread is desired.

A perforated eave trim and system for roofs is described. New shingles are typically installed on wooden strapping attached to an old or existing roof. The cavity between the old roof and the shingles is prone to build up of moisture if the cavity is inadequately ventilated. Moisture build up can lead to mold, ice buildup and damage to the roof and strapping. The perforated eave trim, and embodiments thereof disclosed herein, in conjunction with conventional roof vents provides an improved system for venting roofs.

Vents are disclosed for covering openings on roofs. The disclosed vents cover openings on metal roofs and prevent moisture and objects from entering the opening while allowing air to pass therethrough. The vents disclosed herein also prevent moisture from entering the building through openings that can be created when the vents are attached to a roof. The vents include a cap, a collar, and a flashing configured to contact the roof. The vents can also include a screen placed between the cap and the collar. The collar can have arms formed on an upper portion thereof to facilitate connection of the collar to the cap. Feet can be formed on a bottom portion of the collar. Once the vent is fully assembled, the feet can be positioned underneath the flashing and can be the main connection point of the vent to a roof. Due to the design of this assembly, fasteners pass through the feet providing a sound and secure attachment to the roof. The feet are then covered from moisture, rain, and/or snow by a flashing, and the flashing is then secured by screws or other fasteners passing through the reinforcement material and through the flashing itself which provides a weatherproof seal.

A roof vent for ventilating the roof of a building to the atmosphere. The roof vent includes a flange portion to lay against the roof, the flange portion having an opening to let air vent from the interior of the building (e.g. an attic). The roof vent can optionally include a collar portion extending from the flange portion and enclosing, at least in part, about a periphery of the opening and a cap dimensioned and configured to cover over the opening (including the hole in the roof) and optionally over the collar portion. The cap is configured to provide a passage (between the flange portion and the cap) through which air can pass between the atmosphere and the opening. The roof vent also includes a corrugated filter plate, e.g. partially enclosed by the cap, and interposed between the central opening and the passage, the corrugated filter plate having a pore size sufficient to permit air to pass through but inhibit the passage of snow particles, cinder particles and/or water droplets there-through.

Disclosed is an apparatus for venting buildings, specifically attic spaces, such vents being predominantly shape-conform to the components from which a wall or a roof is built (typically tiles, in the context of roofs), the vent typically being fabricated from a metallic, plastic, or ceramic core as well as one or more layers from other materials or compounds which modify the overall characteristics of the vent, such as the surface characteristics. Furthermore disclosed are methods of manufacturing such ventilation apparatuses.