Provided is an apparatus for manufacturing a multi-pane glass unit. The apparatus includes: a first plate configured to hold a first glass pane; a second plate configured to hold a second glass pane such that the second glass pane faces the first glass pane; and a conveyer including a first portion configured to convey the first glass pane onto the first plate and a second portion configured to convey the second glass onto the second plate.

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.

An insulated glazing unit includes a first laminated pane including two glass sheets, each no more than 2 mm thick, that are bonded to one another by an intermediate adhesive layer, a second structural laminated pane providing the mechanical strength required for the flight conditions of an airplane, in particular resistance to bird strike and control of glazing unit deformation under pressure difference conditions during a flight on either side of the insulated glazing unit, and a gas gap between the first and second laminated panes, the first laminated pane being provided with a heating system.

An insulating glazing unit, includes at least two glass panes and a circumferential spacer profile between the at least two glass panes near edges of the at least two glass panes, 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, and wherein the at least one RFID transponder is arranged at a corner of the insulating glazing unit, and wherein an end of the at least one RFID transponder pointing toward the nearest corner of the insulating glazing unit is not more than 30 cm from the nearest corner of the insulating glazing unit.

This disclosure provides connectors for smart windows. A smart window may incorporate an optically switchable pane. In one aspect, a window unit includes an insulated glass unit including an optically switchable pane. A wire assembly may be attached to the edge of the insulated glass unit and may include wires in electrical communication with electrodes of the optically switchable pane. A floating connector may be attached to a distal end of the wire assembly. The floating connector may include a flange and a nose, with two holes in the flange for affixing the floating connector to a first frame. The nose may include a terminal face that present two exposed contacts of opposite polarity. Pre-wired spacers improve fabrication efficiency and seal integrity of insulated glass units. Electrical connection systems include those embedded in the secondary seal of the insulated glass unit.

An insulating glazing unit, includes at least two glass panes and a circumferential spacer profile between the at least two glass panes near edges of the at least two glass panes, 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, and wherein the at least one RFID transponder is arranged at a corner of the insulating glazing unit, and wherein an end of the at least one RFID transponder pointing toward the nearest corner of the insulating glazing unit is not more than 30 cm from the nearest corner of the insulating glazing unit.

Systems and methods for transparent organic photovoltaic devices are provided. In one embodiment, an organic semiconductor device comprises: a first glass sheet comprising a first ultra-thin flexible glass material; at least one transparent organic photovoltaic cell bound to the first glass sheet; and a second glass sheet applied to the at least one organic photovoltaic cell, wherein the at least one transparent organic photovoltaic cell is positioned between the first glass sheet and the second glass sheet.

A dynamic multi-pane insulating assembly and system including methods for dynamically maintaining the thermal resistance value of the assembly and system. The dynamic multi-pane insulating assembly and system includes an interior pane and first and second exterior panes. The first exterior pane and a first side of the interior pane defines an evacuated gap in communication with a vacuum source and a second side of the interior pane and the second exterior pane defines a pressurized gap in communication with the source of pressurized gas.

A spacer frame assembly and method of manufacturing that includes a substantially linear channel comprising two lateral walls connected by a base wall, the channel having first and second ends that when assembled, includes at least three sides and corresponding corners between each of the sides; the linear channel further includes a nose portion of the first end and a receiving portion of the second end having a channel for receiving the nose portion; and the nose portion comprising a first undulation in the first end and the receiving portion comprising a second undulation in the second end. The first and second undulations nest when the ends are in an assembled position.

A driver for an electrically dynamic structure may store and release energy during polarity cycling to improve the energy efficiency of operation. In some examples, the driver includes an energy storage element. In operation, the driver can charge an electrically controllable optically active material to a first operating voltage at a first polarity and subsequently discharge the optically active material during polarity reversal. The driver may store energy released from the optically active material during discharging and subsequently release the energy to charge the optically active material to a second operating voltage at a second polarity different than the first polarity.