The invention provides a fire-stopping product, an insulated building façade comprising a fire-stopping product, and a method of making a fire-stopping product. The fire-stopping product comprises a resilient, porous material at least partially impregnated with an intumescent agent and held in compression by a releasable restraint. When exposed to hot gases from a fire, the restraint yields to release the resilient, porous material in an initial expansion, thereby exposing the intumescent agent to the hot gases and allowing rapid intumescence to occur. When implemented in a ventilated building façade, the fire-stopping product is able to close an air gap in a short amount of time.

A panel can have a face surface having a length and a width. The panel can include a first tongue that extends along the length and a second tongue that extends along the width. The panel can further include first front and back legs that extend along the length of the panel and define a first groove therebetween and second front and back legs that extends along the width of the panel and define a second groove. At least one of the first tongue or the first back leg has a longitudinal dimension that is greater than the length of the face surface; or at least one of the second tongue or the second back leg can have a longitudinal dimension that is greater than the width of the face surface.

A plurality of ventilation elements, vents, slots, or gap elements or similar features that are applied to, or machined into, one or more sides or faces of exterior siding products, such as lap siding, panel siding, vertical siding, horizontal siding, flat (or non-overlapping) siding, flap siding, decorative trim, trim system components or other forms of panels or cladding materials. When the exterior siding product is installed, the ventilation elements, vents, slots, or gap elements or similar features provide a built-in air and water gap to facilitate and increase water drainage and air circulation behind the siding or panel, thereby minimizing water storage in the space behind the product and lowering the equilibrium moisture content of the siding itself. The ventilation features are incorporated into the corresponding product in-line or during the manufacturing process, and do not require any further work during assembly or construction on-site (e.g., furring strips or other similar drainage mechanisms are not needed). Some or all of the ventilation features or elements are located to improve the product's ability to equilibrate (moisture-wise) in a product stack before installation as well as after installation.

A fabric housing, a method of installing a fabric housing, and a method of manufacturing a fabric housing are provided. The fabric housing for stretching fabric on walls or ceilings includes a first exterior wall. The fabric housing also includes a second exterior wall. The fabric housing further includes a tensioning leg configured to tightly abut one of the first exterior wall or second exterior wall. The tensioning leg is configured to grip a fabric between the tensioning leg and the one of the first exterior wall or second exterior wall. The fabric housing still further includes a pair of opposing jaws configured to secure the fabric. The pair of opposing jaws are disposed along one of the first exterior wall or the second exterior wall. A corresponding method of manufacturing a fabric housing and installing a fabric housing are provided herein.

A panel is configured for attachment to a mounting surface of a building structure. The panel includes a first end surface and a second end surface, spaced from each other along a longitudinal axis; a top edge surface and a bottom edge surface, spaced from each other and offset from the longitudinal axis; and an inner surface and an outer surface, opposed to each other and extending from the first end surface and the second end surface. The inner surface includes a contact portion and a contour portion. The contact portion is disposed on a reference plane. The contour portion is contoured toward the outer surface, away from the reference plane, such that the contour portion defines a channel. The channel extends along at least a portion of a length of the panel, between the first end surface and the second end surface.

A vented and water control paneling has improved drainage and integrated ventilation air space. The water control paneling may be fabricated with an omnidirectional relief pattern formed on its back surface. The relief pattern spaces the vented and water control paneling away from a structure to which it is secured, thereby providing an omnidirectional drainage plane between the back surface of the paneling and the structure. The omnidirectional drainage plane provides an unimpeded ventilation and drainage path of water and/or water vapor.

A method and a structure are described that allow covers to be simply and quickly applied to building walls and façades, regardless of whether the walls are inside or outside, flat or curved, ventilated or not. First, the method provides for making a bearing surface, parallel to the wall, by using flexible panels, then constraining the bearing surface to the wall by fastening elements whose orientation can be adjusted, next precisely adjusting the orientation of the bearing surface from the wall by acting selectively on the single fastening elements, and finally fastening the cover, for example marble slabs, to the bearing surface. The support structure includes the just described elements.

A system for supporting exterior panels on a substrate of a building structure. The system has a plurality of polymeric bracket members, and each of the bracket members have at least one anchor section, at least one web section and at least one support section. The polymeric bracket members provide a thermal break from the exterior panel to the substrate of the building structure. A plurality of exterior cladding units are held in place by the bracket members. A plurality of vents are disposed between the panels and the exterior panels, and a plurality of vents are also disposed between the panels and the substrate, thereby forming a ventilation system.

A method of constructing a building comprising the steps of attaching a first panel to a second panel. The first panel is one of a single plenum panel and a multi-plenum panel and the second panel is one of a single plenum panel and a multi-plenum panel.

Systems and methods for a pressure equalized rainscreen (PER) and for mounting the same to a building. A PER system includes a panel disposed over an exterior wall that defines a cavity adjacent to the building for pressure equalization. Moisture is drained out of the cavity via a first opening(s), and air flows into and out of the cavity for pressure equalization via a second opening(s). The panel is configured to hinder flowing air via the first opening(s) and hinder draining moisture via the second opening(s). The PER system is mounted using a plurality of mounting strips that demarcate wall portions corresponding to panels for covering those wall portions. Each panel is movably engaged with a mounting strip for support and to allow deformation of the panel once fastened to the exterior wall.