Abstract: A visibility controlling device with switchable transparency. This design of visibility controlling device is economical and can be operated manually or under electric power. The time for switching from translucent to transparent state requires about 5-30 seconds.

Abstract: A controllable privacy structure, such as a window or door, may include an electrically controllable optically active material connected to a driver. The driver can control the application and/or removal of electrical energy to the optically active material to transition from a scattering state in which visibility through the structure is inhibited to a transparent state in which visibility through the structure is comparatively clear. The driver may need to be located in relatively close physical proximity to the privacy structure the driver is intended to control. Devices, systems, and techniques are described for discretely positioning a driver relative to a privacy structure to be controlled.

Abstract: Examples disclosed herein relate to an Insulated Glass Unit (“IGU”) to enhance wireless communications in a wireless network. The IGU has a first and a second glass layers, a first and a second spacers, and a first and a second ground planes, the first ground plane in contact with the first glass layer and the second ground plane in contact with the second glass layer. The IGU also includes a gas layer in between the first and the second ground planes, a reflectarray comprising a metastructure array of reflector elements, and a third glass layer on top of the metastructure reflectarray.

Abstract: The present invention relates to a double-pane window insulating system. The double-pane window insulating system according to the present invention comprises: a double-pane window having a chamber formed between a pair of windowpanes, a bead inlet via which a plurality of beads and air flow into the chamber, a bead outlet via which the plurality of beads and the air accommodated in the chamber are discharged, and an air entrance/exit opening via which air enters and exits the chamber; and a bead discharge means for discharging the plurality of beads, accommodated in the chamber, to the bead outlet.

Abstract: A portal can include at least one rail and at least one stile, each end of each rail connected to an end of each stile such that the portal defines a frame, wherein at least one stile can include a first stile and a second stile; a thermal strut arranged between the first stile and the second stile, the thermal strut being of an insulating material; and an insulative bar arranged between the first stile and the second stile, the insulative bar being of an insulating material.

Abstract: An insulating glass unit (10) is formed from a plurality of transparent layers (16, 18, 20), in which at least one illuminable panel (20) is arranged between at least two mineral glass panels (16, 18). The mineral glass panels (16, 18) are held at a defined distance from one another by at least one spacer element (14). The illuminable panel (20) is held at least on one longitudinal marginal edge (24) by the spacer element (14). The spacer element (14) is formed by at least one hollow profile (15), which preferably comprises a plurality of adjoining hollow chambers (26, 28). The outer mineral glass panels (16, 18) each adjoins at least two lateral surfaces of the hollow profile (15). The illuminable panel (20) rests on or against the intermediate hollow chamber (28). An illumination element (32) is arranged within the intermediate hollow chamber (28).

Abstract: A window assembly heat transfer system is disclosed in which a window member has a selected transparency to monitored or sensed light wavelengths. One or more passages are provided in the window member for flowing a single-phase or two-phase heat transfer fluid, the passages being optically non-transparent to the monitored or sensed light wavelengths. A mechanism allows either evaporation or condensation of the fluid and/or balancing of a flow of the fluid within the passages. In one embodiment, the window assembly can be made by producing passages in a top surface of a first single plate, optionally producing passages in a bottom surface of a second single plate and bonding the top surface of the first plate to a bottom surface of a second single plate to form the window member with the passage or passages. In another embodiment, the window assembly can be made by providing a core around which the window member material is grown and thereafter removing the core to produce the passage or passages.

Abstract: Embodiments of the present invention provide a vehicle privacy system (700), comprising audio input means (130, 190, 720) for receiving an external audio signal (725) indicative of audio from within a vehicle (900), audio source means (710, 910) for receiving the external audio signal (725) and determining an output audio signal (735) in dependence thereon for reducing an external intelligibility of speech within the vehicle (900), and audio output means (145, 146, 147, 730, 920) for receiving the output audio signal (735) and outputting audio (925) corresponding thereto to be at least partly audible external to the vehicle (900).

Abstract: A glass panel unit includes a first pane of glass, and a second pane of glass facing the first pane of glass with both of them spaced a predetermined interval apart. It is provided with a sealant between the panes of glass, joined to them in an airtight manner, and an interior space sealed with them and the sealant. It is provided with a first spacer in the interior space so as to be in contact with the panes of glass, and a second spacer disposed in the interior space so as to be in contact with only one of the panes of glass and out of contact with another thereof.

Abstract: A plug-in connector (1), for warm edge hollow profiles (2) of spacers of insulating glazing, has a base with side walls (6) at the edges. A plurality of retaining elements (15) formed as spring lugs are arranged on the outer side of the base (bottom) (5) in a single central row on each of both sides of the center (3) of the plug-in connector (1). Starting from the base (5), the retaining elements are directed obliquely outwards towards the adjacent hollow profile base (28) and towards the connector center (3). The retaining elements (15) are in each case arranged in a sunken base region (13) on the outer side of the base (5) that adjoins a raised, plate-like base region (11) arranged in the region of the center (3). Laterally obliquely outwardly directed resilient retaining elements (18,19) are arranged at the free edge region (7) of the side walls (6).

Abstract: A refrigeration appliance and a heat insulation door thereof are provided. The heat insulation door includes a heat insulation vacuum glass module formed with a first glass plate and the second glass plate that are overlapped and that have a first interval; a third glass plate overlapped on the vacuum glass module and having a second interval with the vacuum glass module; and the second interval is filled with inert gas. The novel door improves the heat insulation of the refrigeration appliance.

Abstract: The glass panel unit is a predetermined part separated from a completed assembly obtained by subjecting a temporary assembly to a predetermined process. In the temporary assembly, the inside space (500) enclosed by the first and second glass substrates and the frame is divided into the first space and the second space with the partition and the gas adsorbent is inside the first space. The predetermined process includes: converting the first space into the evacuated space by evacuating the first space through the gas passage, the second space, and the outlet; and changing a shape of the partition to close the gas passage to form the seal enclosing the evacuated space. The predetermined part includes: a first and second glass panels being parts of the first and second glass substrates; the seal; the evacuated space; and the gas adsorbent.

Abstract: In a method of supplying an element for covering a non-vision area in a curtain wall on an architectural structure, a plurality of shadow boxes is prefabricated at a location remote from both a unitized curtain wall assembly shop and the architectural structure. The shadow boxes are prefabricated by sealing an interior spacer between a vision glass panel and a back structure. The back structure includes an insulating material surrounded by a rigid envelope. The vision glass panel, the back structure and the interior spacer define a hermetically sealed void therein. A structural seal is applied about the interior spacer and is affixed to the peripheral edge of the vision glass, the interior spacer and the back structure. The plurality of shadow boxes is then delivered to a selected one of the unitized curtain wall assembly shop and the architectural site.

Abstract: In a method of supplying an element for covering a non-vision area in a curtain wall on an architectural structure, a plurality of shadow boxes is prefabricated at a location remote from both a unitized curtain wall assembly shop and the architectural structure. The shadow boxes are prefabricated by sealing an interior spacer between a vision glass panel and a back structure. The back structure includes an insulating material surrounded by a rigid envelope. The vision glass panel, the back structure and the interior spacer define a hermetically sealed void therein. A structural seal is applied about the interior spacer and is affixed to the peripheral edge of the vision glass, the interior spacer and the back structure. The plurality of shadow boxes is then delivered to a selected one of the unitized curtain wall assembly shop and the architectural site.

Abstract: A system to detect a pressure difference between the interior of a cabin of an aircraft and the exterior of the aircraft. The system includes a window arrangement having a first windowpane with a first surface and an opposite second surface and is adapted to be mounted in an aircraft such that the first surface of the first windowpane faces the exterior of the aircraft and is subjected to ambient outside atmospheric pressure and the second surface faces the cabin interior, and a pressure sensor including a first pressure port. The first windowpane includes a first air passage opening extending between the first and second surfaces of the first windowpane, and the pressure sensor is sealingly connected to the first air passage opening such that the first pressure port of the pressure sensor is subjected to pressure acting on the first surface of the first windowpane.

Abstract: A double glazing unit is constituted by exterior-side laminated glass interior-side laminated glass. The exterior-side laminated glass is configured as laminated glass including a first chemically tempered glass plate, a first interlayer and a second chemically tempered glass plate. The interior-side laminated glass is configured as laminated glass including a glass plate, a second interlayer, a light-modulating sheet, a third interlayer, and a fourth interlayer and a tempered glass.

Abstract: A fire door utilizing a pair of frame members each having cases forming opposing open chambers. The open chambers are filled with fire resistant material and include structural plates that do not contact the cases. Holders attach to the cases support a fire resistant glazing unit.

Abstract: A refrigerator includes a first storage chamber, a second storage chamber spatially-separated from the first storage chamber, a first refrigeration cycle system to cool the first storage chamber using a first refrigeration cycle, and a second refrigeration cycle system installed to be separated from the first refrigeration cycle system to cool the second storage chamber using a second refrigeration cycle in an independent manner from the first refrigeration cycle. The first and second storage chambers maintain first and second target temperatures, respectively. The first and second refrigeration cycle systems circulate different kinds of refrigerants to cool the first and second storage chambers, respectively.

Abstract: A spacer for insulated glazing units having at least one polymeric main body with a wall thickness d having a first pane contact surface and a second pane contact surface running parallel thereto, one first glazing interior surface, one second glazing interior surface, one outer surface, one first hollow chamber, and one second hollow chamber. A groove for receiving a pane runs parallel to the first pane contact surface and the second pane contact surface between the first glazing interior surface and the second glazing interior surface. The first hollow chamber adjoins the first glazing interior surface and the second hollow chamber adjoins the second glazing interior surface. The lateral flanks of the groove are formed by the walls of the first hollow chamber and the second hollow chamber, and the wall thickness d? in the region of the lateral flanks is less than the wall thickness d of the polymeric main body.

Abstract: An insulated glass unit (IGU) comprises a first pane of a transparent material and a second pane of a transparent material. The second pane is spaced apart from the first pane to define a cavity therebetween. At least one of a spacer and an array of stand-off members is disposed between the first and second panes to maintain separation therebetween. A first adhesive layer forms at least a portion of a gas-tight connection between the first pane and the second pane. A highly gas-restrictive coating is disposed over the adhesive layer, where the coating is an inorganic layer.

Abstract: A sealed translucent glass glazing unit includes two lites of spaced translucent glass to define a gap which contains an absorptive filler. A spacer around the perimeter of the unit seals the unit and maintains the gap. A vent tube is mounted within the spacer with one end open to the filler and one end open to the exterior.

Abstract: Specific fluid, which is a site of energy conversion, characterized in that it comprises water, strongly scattering mineral powder, in general calcium carbonate, antifreeze and/or a colorant, a surfactant and an antifoam, the powder having a concentration by mass of between 1% and 3% and a median particle size of between 0.8 and 10 ?m.

Abstract: Window pane systems which offer improved protection against blast and impact hazards, including contact blast caused by a bomb or a shell, with or without hollow charge and bullets. A window pane system of the present invention includes multiple glass layers, to absorb the ballistic impact of the explosion; a thick polymer such as polycarbonate, to absorb the kinetic energy of the blast including contact blast; and multiple elastic thin layers of polymer such as polycarbonate, to absorb the blast impact such as the shock wave and shrapnel. Optionally, the last layer is extended such that the last layer is covering up to the full width of the window pane system, preferably in all four sides of the window pane system.

Abstract: A light control process, a light control system and a building, which are capable of increasing, in a short period of time, the amount of light passing through a multiple sheet including a plurality of transparent sheet layers are provided.

Abstract: An improved vibration damping apparatus is provided for use with window structures, including windows used in vehicles, aircraft, and spacecraft. The vibration damping system includes at least two separate layers of solid material that are typically substantially clear at visible wavelengths, in which the two layers are spaced-apart by a predetermined distance to form a space or gap therebetween. This gap will be of a size and shape to enhance vibration damping when it is filled with a gaseous compound, such as air. The air-film vibration damping system created by the above structure can be applied to an external pane of a window structure, or to the interior pane of a window structure, or perhaps to both an exterior pane and an interior pane of the same window structure, if desired.

Abstract: An insulated glass unit includes a first outer glass pane having a first thickness and a second outer glass pane having a second thickness. One or more inner glass panes can include one or more glass ribbons that are interposed between the outer glass panes. At least one of the inner glass panes can have a thickness that is less than the first and second thicknesses. An edge assembly is coupled between the outer glass panes. The edge assembly can be configured to receive an edge portion of the one or more inner glass panes, such as to retain the one or more inner glass panes at respective positions that are spaced apart from, and generally parallel to, the first and second outer glass panes. In an example, side edges of the one or more inner glass panes are recessed from corresponding side edges of the outer glass panes.

Abstract: The thermally switched absorptive optical shutter may be a self-regulating “switchable absorber” device that may absorb approximately 100% of incoming light above a threshold temperature, and may absorb approximately 50% of incoming light below a threshold temperature. The shutter may be formed by placing a thermotropic depolarizes between two absorptive polarizers. This control over the flow of radiant energy may occur independently of the thermal conductivity or insulation of the shutter device and may or may not preserve the image and color properties of incoming visible light. This has energy-efficiency implications as it can be used to regulate the internal temperature and illumination of buildings, vehicles, and other structures without the need for an external power supply or operator signals. The shutter device has unique optical properties that are not found in traditional windows, skylights, stained glass, light fixtures, glass blocks, bricks, or other building materials.

Abstract: The thermally switched reflective optical shutter is a self-regulating “switchable mirror” device that reflects up to 100% of incident radiant energy above a threshold temperature, and reflects up to 50% of incident radiant energy below a threshold temperature. Control over the flow of radiant energy occurs independently of the thermal conductivity or insulating value of the device, and may or may not preserve the image and color properties of incoming visible light. The device can be used as a construction material to efficiently regulate the internal temperature and illumination of buildings, vehicles, and other structures without the need for an external power supply or operator signals. The device can be tailored to transmit sufficient visible light to see through in both the transparent and reflective states, while still providing significant control over the total energy transmission across the device.

Abstract: The invention relates to a glazing panel (100), particularly an insulated glazing panel, comprising at least a first (10) and a second (11) sheet of glass which are joined together by an intercalated surround (12) which holds them a certain distance apart, and between said at least two sheets of glass at least one internal space (15) closed by the intercalated surround positioned around said internal space. According to the invention, the intercalated surround (12) comprises an opening (122) causing the internal space (15) to communicate with the outside of the panel, the panel comprises at least one electrically conducting element (14) inserted into the opening, a first end (141) of the conducting element being situated inside the internal space and a second end (142) of the conducting element being situated outside the internal space, and the panel also comprises a first plug (17) of thermoplastic elastomer material closing the opening (122) around the electric conducting element.

Abstract: A bio-inspired window can be created by applying one or more heat exchange layers to one or more surfaces of a window of a building, boat, vehicle or any other structure. The heat exchange layer can include an interconnected network or array of channels or microchannels that can be used to flow a fluid over the surface of the window. The fluid can be used to heat or cool the surface of the window panel to control the flow of heat across the window and reduce the heating or cooling energy load of building. The fluid can be heated or cooled using the ambient air in the building. The refractive index of the fluid can be adjusted to change of optical transparency properties of the window. In some embodiments, the window can appear nearly as clear as an ordinary panel of glass. In other embodiments, the window can color, block or scatter the incoming light.

Abstract: The specification discloses a window or door, and glazing assemblies therefor, wherein the glazing assemblies include a first pane of glass with an exterior surface coated with a smooth, hardened silica-containing coating, and an opposite surface coated with at least one layer of a low emissivity coating. In one embodiment, a second pane of glass is joined to and spaced from the first pane of glass by a polymeric spacer. In a second embodiment, a third pane of glass is laminated to the second pane, and in a third embodiment, a third pane of glass coated on its interior surface with a low emissivity coating is joined to and spaced from the second pane by a polymeric spacer.

Abstract: An insulating glass unit may include at least three panes of transparent material and at least two spacers positioned between different panes of the unit. For example, a first spacer may hold a first pane of transparent material a first separation distance from a second pane of transparent material and a second spacer may hold the second pane of transparent material a second separation distance from a third pane of transparent material. In some examples, the insulating glass unit is configured so that the first separation distance is greater than the second separation distance. In such examples, the insulating glass unit may have a comparatively larger first between-pane space and a comparatively smaller second between-pane space. In some applications, the insulating glass unit may exhibit thermal and sound insulating properties approximately equal to a triple-pane insulating glass unit while having size characteristics approximately equal to a double-pane insulating glass unit.

Abstract: A vacuum insulated glass (VIG) window unit installation configuration and method for installing a VIG window unit in a window frame that was designed to accommodate at least a thicker IG (insulating glass/integrated glass) window unit(s). The VIG window unit may be supported on a first side by a first stop portion of the frame and on a second side by a second stop portion of the frame. A spacer structure is provided along at least one side of the VIG window unit between the VIG window unit and at least one of the first and second stop portions, the spacer structure including at least one hollow area surrounded by a solid portion when viewed cross sectionally.

Abstract: A window with modifiable transparency, the window including window panes that define at least one cavity in between the panes. The window also including one or more mechanisms for introducing and removing a transparency modifying fluid into and from said one or more cavity.

Abstract: Ligand exchange thermochromic systems comprising a. a transition metal ion, iodide; and at least one material capable of minimizing or eliminating yellow color formation in the system, wherein at 25° C. the color coordinate b* value of the system is less than 30.

Abstract: The energy-free refrigeration door of the present application provides a way to control condensation when the door of a refrigeration unit is opened by providing thermal insulation to the door with glass panels which have a low emissivity coating. The door includes a door frame housing and an insulating glass unit comprising inner, middle and outer sheets of glass. A first sealant assembly disposed around the periphery of the inner and middle sheets of glass forms a first chamber between the inner and middle sheets of glass. A second sealant assembly disposed around the periphery of the middle and outer sheets of glass forms a second chamber between the middle and outer sheets of glass. A gas, such as krypton, air, or argon is held in the first and second chambers. The outer sheet of glass and inner sheet of glass each have an unexposed surface that faces the middle sheet of glass.

Abstract: An insulating glass unit may include at least three panes of transparent material and at least two spacers positioned between different panes of the unit. For example, a first spacer may hold a first pane of transparent material a first separation distance from a second pane of transparent material and a second spacer may hold the second pane of transparent material a second separation distance from a third pane of transparent material. In some examples, the insulating glass unit is configured so that the first separation distance is greater than the second separation distance. In such examples, the insulating glass unit may have a comparatively larger first between-pane space and a comparatively smaller second between-pane space. In some applications, the insulating glass unit may exhibit thermal and sound insulating properties approximately equal to a triple-pane insulating glass unit while having size characteristics approximately equal to a double-pane insulating glass unit.

Abstract: An insulating glass unit may include at least three panes of transparent material and at least two spacers positioned between different panes of the unit. For example, a first spacer may hold a first pane of transparent material a first separation distance from a second pane of transparent material and a second spacer may hold the second pane of transparent material a second separation distance from a third pane of transparent material. In some examples, the insulating glass unit is configured so that the first separation distance is greater than the second separation distance. In such examples, the insulating glass unit may have a comparatively larger first between-pane space and a comparatively smaller second between-pane space. In some applications, the insulating glass unit may exhibit thermal and sound insulating properties approximately equal to a triple-pane insulating glass unit while having size characteristics approximately equal to a double-pane insulating glass unit.

Abstract: The invention relates to glazing (1) comprising a first glazing sheet (10; 10A, 10B) forming a substrate on which at least one film of an electrochemical system (12) is formed, said system having optical and/or energy-related properties that are electrically controllable, a second glazing sheet (14) forming a counter-substrate, and a third glazing sheet (18). The substrate has characteristics that allow it to be obtained by being cut from a motherboard on which motherboard at least one film of the electrochemical system (12) is formed. The substrate is located between the counter-substrate (14) and the third glazing sheet (18) and is set back relative to the counter-substrate (14) and relative to the third glazing sheet (18) over the entire circumference of the substrate (10; 10A, 10B).

Abstract: The present invention provides a process for absorbing solar energy and, simultaneously having a continuous control of the light admission making it possible to install the device in external openings of buildings and equipment, such as windows, shutters or skylights. The system comprises two frames which support plates of transparent material, between which it is possible to introduce a colourful solution coming from an external reservoir. Both frames are interconnected through a flexible membrane which allows the plates to be pushed against each other, making the window transparent, or pushed away interposing the colourful solution, which will make the window uniform and gradually translucent or opaque. The said liquid comes from a reservoir and the access to the gap between the plates through is obtained by means of a channel that separates the two frames, allowing the liquid to flow evenly into the whole surface, thus being a homogenous and adjustable darkening obtainable.

Abstract: A variety of refrigerators and merchandisers having glass or plastic substrates that are substantially fog-resistant are provided. For example, refrigerator doors having a substantially transparent substrate including an anti-fog coating on at least a portion thereof are provided. The portion of the substrate may substantially not fog when the portion has an initial surface temperature and is then exposed to a moist air ambient with a dewpoint temperature equal to or greater than the surface temperature for a period of time. The surface temperature may be less than about 0° C. and the period of time may be greater than about 6 seconds.

Abstract: The invention relates to a transparent wall, comprising at least one transparent wall substrate having a light-guiding structure, wherein the light-guiding structure is imprinted directly or indirectly on the wall substrate.

Abstract: Certain example embodiments of this invention relate to articles including anticondensation coatings that are exposed to an external environment, and/or methods of making the same. In certain example embodiments, the anticondensation coatings may be survivable in an outside environment. The coatings also may have a sufficiently low sheet resistance and hemispherical emissivity such that the glass surface is more likely to retain heat from the interior area, thereby reducing (and sometimes completely eliminating) the presence condensation thereon. The articles of certain example embodiments may be, for example, skylights, vehicle windows or windshields, IG units, VIG units, refrigerator/freezer doors, and/or the like.

Abstract: An enclosure is made out of transparent or translucent panes which form a chamber (1) through which a liquid flows in closed circuit and which interchanges energy with the inner and outer environments, a heat exchanger (2) in contact with the liquid, a circulation pump (3), and a hydrostatic pressure reducer device (4). The hydrostatic pressure reducer device allows the reduction of the thicknesses of the transparent panes which hold the liquid inside. The active character of the enclosure is due to its capacity of controlling the solar heat load and the illumination. The solar heat load is regulated through the heat exchanger. The illumination of the building is controlled through the adjustable transparency of the liquid. The described enclosure allows the creation of an isothermal envelope which allows the climatization of the building. The system can be used for active outer enclosures or for interior partitions for the climatization and luminic control, as well as for glass roofs or false ceilings.

Abstract: Device intended for a double glazing including at least one outer glazing and one inner glazing separated by an intermediary space filled with a gas, used to isolate an inside environment from an outside environment, a pressure variation being liable to occur between these environments, for example in the case of an aircraft in flight, includes means for conserving the outer glazing and the inner glazing of this double glazing mainly parallel, independently of this pressure variation. The invention also concerns a double glazing including this device, the process for maintaining parallelism and software using the process.

Abstract: A window includes first and second panes and a frame coupled to the first and second panes to form an air gap there between. The window further includes an electrical generator disposed in the air gap configured to convert electromagnetic radiation to electricity. The window further includes a venting system configured to vent heat from the air gap away from the first pane or the second pane. The window further includes first and second reflective coatings respectively disposed on first surfaces of the panes. The first surfaces face the air gap, and the reflective coatings are configured to reflect infrared radiation into the air gap. The window further includes first and second antireflective coatings respectively disposed on second surfaces of the panes. The second surfaces face away from the air gap, and the antireflective coatings are configured to transmit visible light and infrared radiation into the air gap.

Abstract: Certain example embodiments of this invention relate to articles including anticondensation coatings that are exposed to an external environment, and/or methods of making the same. In certain example embodiments, the anticondensation coatings may be survivable in an outside environment. The coatings also may have a sufficiently low sheet resistance and hemispherical emissivity such that the glass surface is more likely to retain heat from the interior area, thereby reducing (and sometimes completely eliminating) the presence condensation thereon. The articles of certain example embodiments may be, for example, skylights, vehicle windows or windshields, IG units, VIG units, refrigerator/freezer doors, and/or the like.

Abstract: A construction panel includes a pane, a construction substrate, and a frame that form an air gap there between. An electrical generator, a water circulator, and an air venting system are in the air gap. First and second reflective coatings are respectively on first surfaces of the pane and the construction substrate. The first surfaces face the air gap. The reflective coatings reflect IR to heat water in the water circulator and heat air in the air gap. First and second antireflective coatings are respectively on a second surface of the pane and on the first reflective coating. The second surface faces away from the air gap. The antireflective coatings transmit electromagnetic radiation to the electrical generator for electricity generation. The heated water, heated air, and electricity may be used in a building to which the construction panel is attached. The solar-construction panel includes a multiple-pane window integrally formed therein.

Abstract: The gas fill device for multiple pane windows includes a tube installed through the peripheral spacer bar between two glass panes in an insulated glass assembly for a window, door glass, skylight, or the like. An elbow is pivotally attached to the external end of the tube. A supply of an inert, insulating gas may be attached to the elbow to refill the space between the two panes with the insulating gas, as needed. Two such tubes may be installed in each multiple pane window assembly, one to refill the space with insulating gas and the other to vent air from the space to the atmosphere as the space is refilled with the insulating gas. When the multiple pane window has more than two panes, the tube may be branched and supplied through a common elbow.

Abstract: Vacuum insulating glass (VIG) units, edge seals for VIG units and methods for forming the edge seals are provided. The VIG units include an edge seal that includes a viscous material, which serves to restrict the rate at which gas permeates into a vacuum space defined between the glass sheets of the VIG unit. The edge seals are configured to allow the glass sheets to move laterally relative to one another when the glass sheets experience differential thermal strain and further configured such that viscous shear occurs within at least a portion of the viscous material when there is relative lateral movement between the glass sheets.