A stile and rail ballistic security door containing bullet proof materials within a metal or synthetic material frame including a plurality of window panes and thermal break means to eliminate condensation problems therein. The door contains a multi-layer exterior core providing extra strength and rigidity.

Protective glazing systems, apparatus, and associated methods for the protection of structural openings against impacts from projectiles from any cause, including nature or man. In some embodiments, the system may comprise a substantially unbreakable and clear or opaque panel, which may be at least substantially the same size (length and width) as the visible glass being protected, and may be anchored to the original glazing via standoff and/or anchor elements. Another embodiment may comprise a substantially unbreakable, ballistic-tolerant panel cut slightly larger than the visible original glazing being protected, said panel being attached to the structural opening via standoff and/or anchor means.

A stile and rail ballistic security door containing bullet proof materials within a metal or synthetic material frame including a plurality of window panes and thermal break means to eliminate condensation problems therein. The door contains a multi-layer exterior core providing extra strength and rigidity.

An impact-resistant window may include features that reduce the forces exerted on the edges of related panes, thereby preventing breakage due to impacts. In a described embodiment, the in pact-resistant window comprises at least one pane made of a transparent material and a frame including a first frame portion, a second frame portion, and a third frame portion. In this embodiment, the connection between the first frame portion and the third frame portion may be configured to allow movement between the first frame portion and the third frame portion.

A frame system for securing a glazing unit to a window portal includes an elongated primary mount extrusion, an elongated mount stop extrusion, an elongated first gasket, an elongated second gasket and a structural sealant. The primary mount extrusion is secured to the window portal. A mount stop extrusion engages the primary mount extrusion with a pair of ratcheting members. The first gasket and the second gasket define a passage therebetween and the passage has a width so that the glazing unit fits therein. A structural sealant is disposed so as to affix the glazing unit to an inner upper surface of the primary mount extrusion.

The application describes a frame assembly. The frame assembly comprises: first and second glass panels substantially parallel to each other; and an intermediate ballistic panel positioned between the first and second glass panels. A spacer element is positioned between the first and second glass panels and adapted to receive the intermediate ballistic panel. The spacer element comprises a recess adapted to receive the intermediate ballistic panel therein. The recess is larger than the intermediate ballistic panel in at least one dimension by a tolerance value to accommodate thermal expansion of the intermediate ballistic 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 stand-alone, single-layer, auxiliary ballistic security barrier system configured to be installed over existing doors. The ballistic security barrier system provides protection against an active shooter with weapons, including handguns and high-powered rifles. The ballistic security barrier system includes a frame fixed to a wall with an anchor system and having structural tubing, mounting angle, and a locking system located inside the structural tubing. Further, the system includes a barrier pivotably attached to the frame and made out of material suitable to withstand impact from a high velocity rifle. The barrier is held in a first stowed position by a release apparatus, and in a second closed position by a lock.

Blast, ballistic, and entry resistant compression frame systems include a plurality of bolts, an exterior frame assembly having a peripheral flange and a plurality of sleeves that receive the bolts, an interior frame assembly having a peripheral flange and a plurality of apertures that receive the bolts therethrough, an exterior gasket between the peripheral flange of the exterior frame assembly and an exterior surface of the wall of the building, and an interior gasket between the peripheral flange of the interior frame assembly and an interior surface of the wall of the building. The exterior frame assembly peripheral flange and the interior frame assembly peripheral flange apply a compression force to the wall when the bolts are torque tightened into the threaded sleeves. Methods of installation in a wall of a building are also provided.

A compression framing system configured to engage with opposing mounting surfaces, the compression framing system having a compression frame, the compression frame having: a first compression arm and a second compression arm, each compression arm having: a hollow pipe body; and a friction shoe associated with the hollow pipe body, said friction shoe being configured to engage directly with the mounting surface; an inner support beam configured to secure the first compression arm to the second compression arm; and an expansion controller associated with the hollow pipe body of the first compression arm; wherein the expansion controller is configured to selectively adjust a separation distance between the friction shoe of the first compression arm and the friction shoe of the second compression arm. The compression framing system is configured to provide a mounting structure frictionally engaged with opposing mounting surfaces for non-destructive attachment of a protective structure.