The invention provides an IG unit that includes two glass sheets and an aerogel sheet located between the two glass sheets. The aerogel sheet is adhered to an interior surface of one of the two glass sheets by an adhesive, such that a face of the aerogel sheet is carried alongside the interior surface and has a portion that is devoid of the adhesive. In some cases, the adhesive is outside a vision area of the unit. In some cases, the adhesive securing the aerogel sheet to the interior surface is in contact with the first face of the aerogel sheet, and the adhesive contacts less than 10% of the first face of the aerogel sheet. Furthermore, some embodiments provide a glazing assembly that includes a frame and an IG unit mounted in the frame such that a vision area of the glazing assembly is located inwardly of the frame.

A system and method for reducing bird collisions with glazing utilizes a UV light source and a perforated opaque object. The UV light source is located adjacent an edge of a glass panel and is configured to project UV light rays onto a planar surface of the glass panel. The perforated opaque object is located between the UV light source and the planar surface of the glass panel, such that UV light rays passing through the perforated object cast onto the planar surface of the glass panel a UV shadow visible to birds and substantially invisible to humans.

A thermally insulated door assembly with an operable panel uses a pair of structural panels, a collection of thermally-insulating fasteners, a panel hole and an operable panel. The pair of structural panels are held together by the thermally-insulating fasteners. The thermally-insulating fasteners form a rigid structure that prevents thermal conductivity between the two structural panels that make up the door assembly. This arrangement enables the door assembly to remain a rigid structure while being composed of multiple components. The panel hole traverses through the pair of structural panels to form an opening into which the operable panel is inserted. The operable panel is a panel that replaces a central section of the door assembly. This placement enables the user to remove and replace the operable panel as desired.

A laminated glass pane (1) comprises a first glass pane (10A), a second glass pane (10B) and an optically active film (20) laminated between the glass panes. The optically active film comprises a first conductive layer and a second conductive layer separated by at least one intermediate layer. The first and second conductive layers are contacted by a first (12A) and second (12B) connection wire, respectively. The optically active film is fully covered by both glass panes. Both the first and the second connection wires protrude out from the active film passing a first edge (14A) of the first glass pane in a same direction (18). The second glass pane protrudes outside the first edge of the first glass pane in the direction by an off-set distance (16). The off-set distance is at least equal to a smallest width of the first and second connection wires.

An insulating panel assembly includes an exterior panel that is formed of a metal. The insulating panel assembly also includes an interior panel. A spacer is coupled to the exterior panel and the interior panel. The spacer maintains the exterior panel in a generally parallel, spaced relationship with the interior panel.

A pre-formed glazing unit for installation in an opening defined in a structure such as a shed, greenhouse or other temporary building comprises a face panel having a periphery enclosing the face panel and a mounting flange for attachment to an inward side of the structure around a peripheral edge of the opening in use, the mounting flange being connected to the periphery of the face panel by a connecting wall. The connecting wall is integrally formed with the face panel and the mounting flange and extends away from the mounting flange to space the face panel from the mounting flange in an outward direction. The face panel and/or a top panel of the connecting wall may be inclined and/or a bottom panel of the connecting wall may include a drip-inducing formation to direct water away from the structure in use. A double-glazed variant is also disclosed.

A fire resistant vacuum insulating glazing assembly includes at least one vacuum insulating glazing unit that has a first glass pane, GP1, which includes an inner pane face and an outer pane face and a second glass pane, GP2, which includes an inner pane face and an outer pane face. A set of discrete pillars is positioned between the first and second glass panes and maintains a distance between the first and the second glass panes. A hermetically bonding seal seals the distance between the first and second glass panes over a perimeter. An internal volume, V, is defined by the first and second glass panes and is closed by the hermetically bonding seal. There is a vacuum of absolute pressure of less than 0.1 mbar and the inner pane faces face the internal volume, V.

A glazing unit is disclosed. The glazing unit can include a first pane and an active device. The active device can be coupled to the first pane. The glazing unit can also include a thermoelectric film layer between the active device and the first pane. In one embodiment, the active device is an electrochromic device.

A multi-pane glass unit includes a first outer glass pane and a second outer glass pane facing each other, a first inner glass pane between the first outer glass pane and the second outer glass pane, a first spacer located between the first outer glass pane and the first inner glass pane, and a second spacer located between the second outer glass pane and the first inner glass pane.

An insulated glass unit having: an outer lite, an inner lite, and a shock absorbing spacer bar disposed between perimeter portions of the inner and outer lite, forming a cavity, the spacer bar having: an inner housing with a plurality of desiccant ports disposed between an internal desiccant chamber and the cavity; a desiccant encased within the desiccant chamber; a flexible outer housing in which the inner housing is nested; and a perimeter guard disposed on the outer surface of the spacer bar, said perimeter guard being configured to attach the spacer bar to each lite. The spacer bar is configured to be highly crush resistant, thus preventing the either lite from being dislodged during a forced entry attempt. The desiccant ports expose the desiccant to the cavity for humidity maintenance within said cavity. An additional lite and spacer bar may be implemented to form a three lite IGU.