A building facade system includes framework having shelf members secured to the floor stabs The top terminal ends of vertical mullions are fastened to the shelf members, thereby hanging the mullions therefrom. Horizontal support members fastened to the mullions support infill panels and are coupled to shelf members which are on the below floor slab. Intermediate support members fastened to the mullions support slab edge cover panels. Posts are fastened to the shelf members and are secured to the floor slabs within troughs formed with embedded channels. The posts are horizontally and vertically adjustably fastenable to the shelf members. The shelf members are thereby also horizontally and vertically adjustable relative to the floor slabs. Terminal edges of the floor slabs can project into mullion cutouts.

A building facade system includes framework having shelf members secured to the floor slabs. The top terminal ends of vertical mullions are fastened to the shelf members, thereby hanging the mullions therefrom. Horizontal support members fastened to the mullions support infill panels and are coupled to shelf members which are on the below floor slab. Intermediate support members fastened to the mullions support slab edge cover panels. Posts are fastened to the shelf members and are secured to the floor slabs within troughs formed with embedded channels. The posts are horizontally and vertically adjustably fastenable to the shelf members. The shelf members are thereby also horizontally and vertically adjustable relative to the floor slabs. Terminal edges of the floor slabs can project into mullion cutouts.

Window or curtain wall assemblies and concealed window fastening assemblies are disclosed. Each window panel includes two layers of glass or other material separated by a spacing mullion, which lines the perimeter of the window panel to create a sealed chamber. The depth of the sealed chamber between the two layers is variable to accommodate either thermal requirements, vertical and horizontal structural loads, or both. The chamber reduces heat loss due to convection allowing it to outperform current double or triple glazing window walls. Each chamber can connect through tubes to allow for air or gas transfer to enhance thermal performance and create the potential for other functional and aesthetic effects. When the window panels are assembled, the latching mechanism structurally unifies each panel to become a single monolithic surface that can also account for thermal expansion. Elements of the latching mechanism are arranged to allow the window or curtain wall to be assembled from the interior, leaving only caulking to be performed from the exterior. Concealing all of such elements helps eliminate the exposure of window mullions and minimizes maintenance of the window or curtain wall.

A veneer product and system includes a body having an aesthetic front surface and a back surface for installation adjacent the building. The body has a top side and a bottom side and a bracket attached to body and projecting away from the back surface of the body, the bracket further comprising a first end adjacent the top side for attachment to the building and a first protrusion for positioning the back surface a predetermined distance from the building and a second end having a second protrusion for positioning the bottom of the back surface a predetermined distance from the building and a bottom projection adjacent the bottom side for engagement with a second body to retain the bottom end of the veneer product.

Curtain wall mullion anchoring systems for resisting dead load and negative wind load, and that permit three-way construction tolerance adjustments. The mullion anchoring systems include an anchoring device secured to a building structural element and attached to a mullion connection bridge, which is connected to a mullion connection clip, which is connected to a mullion. Uplifting forces on the anchoring device may be significantly reduced or even eliminated by transmitting dead load under negative wind load conditions from the mullion to the anchoring device at a point over the inside of a concrete floor slab, such that the dead load counteracts any uplifting force generated by the negative wind load.

A front adjustable wall panel mounting device that is adjustable from the front of a wall is disclosed. The front adjustable wall panel mounting device has a fixed channel configured to be coupled with a wall frame and a moving channel configured to be coupled with wall panel mounting hardware. The fixed channel and the moving channel are configured to be nested together. The tilt of the wall panel is adjusted by turning first or second adjustment bolts. The depth of the wall panel can be adjusted by turning both the first and second adjustment bolts in the same direction, by the same amount. The vertical height of the wall panel can be adjusted by turning the third adjustment bolt. A thin wrench can be inserted into the wall panel gap, engage and turn the adjustment bolt.

A curtain wall structure that can provide a continuous sealing plane through the use of a dual density gasket and that offers improved sealing and thermal insulation properties. The curtain wall structure also provides a structural reinforcement element assembly that is integrated into a mullion of the curtain wall structure to provide a better load bearing capacity. A curtain wall water drainage cross element assembly is also provided to prevent water from flowing vertically inside the curtain wall system. An expansion joint assembly is also provided and designed as two movable parts allowing provides a sound free vertical displacement of components by means of no direct metal to metal contact between sliding parts.

The invention relates to a facade construction comprising first thermal barrier elements which are arranged on a supporting framework, in particular of an outer wall of a building, second thermal barrier elements which are arranged on the first thermal barrier elements and a retaining device which is arranged on the supporting framework and holds the first and second thermal barrier elements on the supporting framework. The facade device further comprises an intermediate layer in the form of a multiplicity of mounting plates, which intermediate layer is attached to and supported by the retaining device, wherein the second thermal barrier elements are arranged on the intermediate layer.

A veneer product and system includes a body having an aesthetic front surface and a back surface for installation adjacent the building. The body has a top side and a bottom side and a bracket attached to body and projecting away from the back surface of the body, the bracket further comprising a first end adjacent the top side for attachment to the building and a first protrusion for positioning the back surface a predetermined distance from the building and a second end having a second protrusion for positioning the bottom of the back surface a predetermined distance from the building and a bottom projection adjacent the bottom side for engagement with a second body to retain the bottom end of the veneer product.

A front adjustable wall panel mounting device that is adjustable from the front of a wall is disclosed. The front adjustable wall panel mounting device has a fixed channel configured to be coupled with a wall frame and a moving channel configured to be coupled with wall panel mounting hardware. The fixed channel and the moving channel are configured to be nested together. The tilt of the wall panel is adjusted by turning first or second adjustment bolts. The depth of the wall panel can be adjusted by turning both the first and second adjustment bolts in the same direction, by the same amount. The vertical height of the wall panel can be adjusted by turning the third adjustment bolt. A thin wrench can be inserted into the wall panel gap, engage and turn the adjustment bolt.