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.

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.

Aspects of the present disclosure relate to modular wall systems and methods of installing modular wall systems in hygienic environments. In one aspect, gap cover apparatus are disclosed. In one aspect, backplate arrangements are disclosed. In one aspect, non-progressive installation methods are disclosed. The modular wall systems can eliminate protruding ledges while maintaining structural integrity and hygienic properties.

Aspects of the present disclosure relate to modular wall systems and methods of installing modular wall systems in hygienic environments. In one aspect, gap cover apparatus are disclosed. In one aspect, backplate arrangements are disclosed. In one aspect, non-progressive installation methods are disclosed. The modular wall systems can eliminate protruding ledges while maintaining structural integrity and hygienic properties.

A board and batten siding panel is provided with the ability to hide the securing flange under siding panels installed on a building wall. The siding panel can be customized to have the look of a wooden panel, while retaining the benefits and durability of a non-wooden material, such as metal.

A board and batten siding panel is provided with the ability to hide the securing flange under siding panels installed on a building wall. The siding panel can be customized to have the look of a wooden panel, while retaining the benefits and durability of a non-wooden material, such as metal.

A system, device and method for reducing wind-induced vibration using cladding includes one or more movable panels attached to an outer façade of a high-rise building, skyscraper or any other structure subject to wind-induced vibration.

Fire resistant lightweight cladding 10 comprising thin sheet material having an outer layer which is predominantly steel and a thicker inner layer which is predominantly aluminium, the inner layer being a supporting layer and the sheet material being formed into a panel of predetermined outline and used in a fire-resistant wall panel assembly comprising a substrate supporting outer cladding sheets in side by side relation, each cladding sheet being a composite of a relatively thin steel layer and a relatively thick aluminium layer, the sheets described herein have a steel outer layer which is about 4 mm thick and an aluminium layer is about 2 mm thick and panel density from 6 kg/m2 to 9 kg/m2. The panels were tested according to British Standard BS 8414-22015 (amdt 1) as modified by Australian 5113-2016 (amdt 1) and the specimen passes the classification criteria 5.4.4(b) which concerns the temperature differential from outer fireside and inside and 5.4.5(g) which concerns debris.

Fire resistant lightweight cladding 10 comprising thin sheet material having an outer layer which is predominantly steel and a thicker inner layer which is predominantly aluminium, the inner layer being a supporting layer and the sheet material being formed into a panel of predetermined outline and used in a fire-resistant wall panel assembly comprising a substrate supporting outer cladding sheets in side by side relation, each cladding sheet being a composite of a relatively thin steel layer and a relatively thick aluminium layer, the sheets described herein have a steel outer layer which is about 4 mm thick and an aluminium layer is about 2 mm thick and panel density from 6 kg/m2 to 9 kg/m2. The panels were tested according to British Standard BS 8414-22015 (amdt 1) as modified by Australian 5113-2016 (amdt 1) and the specimen passes the classification criteria 5.4.4(b) which concerns the temperature differential from outer fireside and inside and 5.4.5(g) which concerns debris.

A kinetic façade system visible at night which includes a plurality of flapping panels which move in response to wind, thereby providing an aesthetic, architectural exterior. The flappers are hung on rung subassemblies. The rungs overhang each other in a stacked vertical fashion about the face of a building, each rung including a housing. An LED is disposed within the rung housing positioned near the top thereof situated on a seat to direct light upward. As such, when the flapper elements situated above the light move, the flappers swing through the light at random intervals and at varying degrees in response to the environmental conditions, thereby creating an effect at night along the façade of the building.