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 first and second gas permeable panes defining an evacuated gap in communication with a vacuum source; a first exterior pane spaced from the first gas permeable pane defining a first pressurized gap in communication with a source of pressurized gas; and a second exterior pane spaced from the second gas permeable pane defining a second pressurized gap in communication with the source of pressurized gas.

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 first and second gas permeable panes defining an evacuated gap in communication with a vacuum source; a first exterior pane spaced from the first gas permeable pane defining a first pressurized gap in communication with a source of pressurized gas; and a second exterior pane spaced from the second gas permeable pane defining a second pressurized gap in communication with the source of pressurized gas.

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 first and second gas permeable panes defining an evacuated gap in communication with a vacuum source; a first exterior pane spaced from the first gas permeable pane defining a first pressurized gap in communication with a source of pressurized gas; and a second exterior pane spaced from the second gas permeable pane defining a second pressurized gap in communication with the source of pressurized gas.

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 first and second gas permeable panes defining an evacuated gap in communication with a vacuum source; a first exterior pane spaced from the first gas permeable pane defining a first pressurized gap in communication with a source of pressurized gas; and a second exterior pane spaced from the second gas permeable pane defining a second pressurized gap in communication with the source of pressurized gas.

The present application provides a mechanical connector adapted for coupling to a mating element, as part of muntin clip or a two part connector. The mechanical connector includes a body having at least one surface adapted for engaging a reciprocal surface of the mating element, wherein the at least one surface of the body of the mechanical connector slides across and frictionally engages the reciprocal surface of the mating element across a predefined distance during the coupling and decoupling of the mechanical connector relative to the mating element. The mechanical connector further includes one or more protruding elements, coupled to the at least one surface of the body of the mechanical connector, which extend in a direction toward the reciprocal surface of the mating element during engagement of the at least one surface of the mechanical connector with the reciprocal surface of the mating element, where the protruding elements is attached to the at least one surface at a first end of the protruding element and being free at the second end of the protruding element, and where the protruding element can separately flex along the length of the protruding element toward each of multiple directions including opposite directions. When the mechanical connector engages and slides relative to the mating element, the one or more protrusions are caused to flex in a direction that is substantially opposite a direction of the movement of the mechanical connector relative to the mating element along at least a portion of the predefined distance.

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.

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.

An insulating glazing includes a first a second pane, a spacer between the first and second pane that is fixedly connected to the first and second pane in a water-vapor-tight manner in each case, which spacer has two parallel pane contact walls, an outer wall, and a glazing interior wall and an interior, and a water-tight sealant strip running around the outer wall between the first and second pane. A pressure-equalizing element is inserted into the sealant strip and the spacer, which pressure-equalizing element is open to the surrounding atmosphere and to the interior of the spacer or to the glazing interior between the first and the second pane and is implemented such that it provides a gas connection having a pressure-equalizing function between the atmosphere and the interior of the spacer or the glazing interior which gas connection is temporally limited due to aging and/or atmospheric influences.

A system including an electrical spacer bar transfer device (E-SBTD) and an electrical spacer bar receiving device (E-SBRD), wherein the electrical spacer bar transfer device (E-SBTD) is configured to be electrically connected to the electrical spacer bar receiving device (E-SBRD).

A system including an electrical spacer bar transfer device (E-SBTD) and an electrical spacer bar receiving device (E-SBRD), wherein the electrical spacer bar transfer device (E-SBTD) is configured to be electrically connected to the electrical spacer bar receiving device (E-SBRD).