A frame assembly, for use in window and door applications configured to retain a panel, comprising a frame with a cover assembly and a support assembly having a track assembly, and a sill assembly and a header assembly both interconnected to a securing surface. The cover assembly is interconnected to the support assembly. The sill assembly comprises a roller member disposed in supporting relation to the track assembly, and the header assembly is disposed in supporting relation to the support assembly so that the frame is movable relative to both the header assembly and the sill assembly. At least a portion of the frame comprises a predetermined thickness and a predetermined width. The predetermined thickness is substantially less than the predetermined width so that both cooperatively and concurrently enhance viewing through the panel and the frame's stability.

Provided is a curtain wall assembly including a first panel, and a second panel that is adjacent to the first panel. The curtain wall assembly includes a first attachment member attached to the first panel, and a second attachment member attached to the second panel. Each of the first attachment member and the second attachment member include at least one fin, and the first attachment member is secured to the second attachment member at the fin.

An improved base shoe for use with panel installation and removal systems. The improved base shoe includes dovetail grooves for use with a safety-seal and a weather seal, wherein the safety-seal and weather seal must be installed prior to installing a glass panel. The improved base shoe features a recess for use with taper plates having a continuous projection along an upper surface. The base shoe and taper plates are configured so as to provide a prying surface between the projection on the taper plates and a wall of the base shoe.

A security panel mounting system having: a mounting unit configured to attach to a mounting surface; a securing unit configured to attach to the mounting unit to form a base fixture; a shock gasket configured to nest within the base fixture, wherein the shock gasket is configured to secure a security panel within the base fixture; and a cover configured to engage with the base fixture. A center mullion may be implemented to allow multiple security panels to be mounted within the mounting surface. One advantage is that the security panel mounting system may allow for the utilization of security panels within any window or door to enhance security. Another advantage is that the shock gasket may allow for the expansion and contraction of the security panels, as a result of changes in ambient conditions, to occur without resulting in bowing or deformation of the security panel.

A security panel mounting system having: a mounting unit configured to attach to a mounting surface; a securing unit configured to attach to the mounting unit to form a base fixture; a shock gasket configured to nest within the base fixture, wherein the shock gasket is configured to secure a security panel within the base fixture; and a cover configured to engage with the base fixture. A center mullion may be implemented to allow multiple security panels to be mounted within the mounting surface. One advantage is that the security panel mounting system may allow for the utilization of security panels within any window or door to enhance security. Another advantage is that the shock gasket may allow for the expansion and contraction of the security panels, as a result of changes in ambient conditions, to occur without resulting in bowing or deformation of the security panel.

Blast, ballistic, and entry resistant operable window systems include a sliding exterior glazing panel assembly, a sliding interior glazing panel assembly, an exterior frame assembly that receives the sliding exterior glazing panel assembly, an interior frame assembly that receives the sliding interior glazing panel assembly, an exterior gasket for placement between the exterior frame assembly and the wall of the building, a central gasket for placement between the exterior frame assembly and the interior frame assembly, and an interior gasket for placement between the interior frame assembly and the wall of the building. Methods of installation in a wall of a building are also provided.

A window insert assembly is disclosed for reducing window energy loss and for damping sound. Also disclosed are parts in a window insert kit to build a window insert and methods for installing the window insert into a window well. In one embodiment, the window insert comprises an outer frame assembly with a gasket frame seated in a gasket channel of the outer frame and planks of an inner frame seated in an inner channel of the outer frame assembly. The inner frame suspends layers of plastic wrap. In an alternative embodiment, the outer frame is in the form of a U-channel or adhesive foil with the gaskets adhered to its outer perimeter. In another embodiment, the outer perimeter of the inner frame comprises a stiffener groove. Here, the outer frame is in the form of a T-shaped stiffener with gasket adhered to its top.

A vacuum insulated glass (VIG) unit frame assembly (10) is disclosed, comprising: a rectangular vacuum insulated glass unit (1) comprising two glass sheets (2a, 2b) separated by a sealed gap (11), wherein a plurality of support structures (12) are distributed in said gap (11), and a frame (20) comprising elongated frame profile arrangements (20a-20d) which frames said vacuum insulated glass unit (1) in a frame opening (21), and wherein said frame (20) comprises a fixation system (45a, 45b, 28a, 28b, 80, 22, 23) fixating the vacuum insulated glass unit (1) at the frame (20), wherein said fixation system (45a, 45b, 28a, 28b, 80, 22, 23) is arranged so as to allow edges (8a-8d) of said vacuum insulated glass unit (1) to thermally deflect (DIS4) in a deflection direction (D1, D2) perpendicular to said frame opening due to a temperature difference (ΔT=T1−T2) between the two glass sheets (2a, 2b), wherein said fixation system (45a, 45b, 28a, 28b, 80, 22, 23) is configured to allow the magnitude of said thermal deflection (DIS4) to vary along the edge (8a-8d) between the corners (9) where the respective edge (8a-8d) terminates, wherein said fixation system (45a, 45b, 28a, 28b, 80, 22, 23) is arranged to provide a resistance against said thermal deflection (DIS4) of at least two opposing edges (8a-8d) of said vacuum insulated glass unit (1), said resistance being substantially lower at corner parts of the edges (8a-8d) than at centre parts of the edges (8a-8d), and wherein said centre parts of said at least two opposing, parallel edges (8a-8d) constitute at least a third, such as half of the extend of the edge (8a-8d) between said corners (9).

A fenestration opening is provided with opposing receptors on opposite sides of the fenestration opening. Each of the receptors is configured to capture and opposing end of a glazed panel with a capture feature or features on each receptor that hold the respective end of the glazed panel from moving laterally, in or out of the fenestration opening. The glazed panel is installed by angling the glazed panel with respect to the fenestration opening and inserting one end of the glazed panel into engagement with one of the receptors, then moving the opposite end of the glazed panel so that the panel is aligned between the receptors, and then moving the panel so that the opposite end of the receptor is captured by the opposite receptor.

An insulating glazing unit, includes at least two glass panes and a circumferential spacer profile between them near their edges, for use in a window, a door, or a façade glazing, which has in each case an electrically conductive frame surrounding the edges of the insulating glazing, wherein at least one RFID transponder is attached to the insulating glazing unit as an identification element, wherein the at least one transponder is arranged at a corner of the insulating glazing unit.