Abstract: A compressible pillar for the preparation of a vacuum insulated glazing (VIG) unit, having a longitudinal extent in the pre-compressed state and including a deformable part having an open structure, which open structure will at least partially collapse when the pillar is subject to a compression force acting in the longitudinal direction of the pillar, the compression force being of at least one value selected within the range of 60 N to 320 N, the pillar will exhibit a partly irreversible deformation causing a reduction in the longitudinal extent of the pillar when the pillar is subjected to the compression force, so that when the compression force is fully released the pillar will exhibit an expansion in the longitudinal direction of the pillar which is less that the reduction in the longitudinal extent of the pillar. Further is shown a process for manufacturing of a compressible pillar, a method of producing a VIG unit as well as a VIG unit.

Abstract: The present disclosure relates to a building aperture cover (1) such as a window or a door. The building aperture cover comprises a frame arrangement (2) and a vacuum insulated glass unit (3), wherein the vacuum insulated glass unit (3) comprises an evacuated gap (4) placed between a first and a second glass sheet (3a, 3b), and wherein a plurality of support structures (5) are arranged in the evacuated gap (4). The vacuum insulated glass unit (3) is arranged in the frame arrangement (2, 6). The building aperture cover (1) comprises one or more elongated flexible sealing gaskets (21, 22) arranged between an outer major surface (S1, S2) of the vacuum insulated glass unit (3) and a frame part (13a, 13c, 23a, 23c) of the frame arrangement (2, 6). The one or more elongated flexible sealing gaskets (21, 22) is arranged to extend substantially parallel to an edge (7, 50a-50d) of the vacuum insulated glass unit (3).

Abstract: The present disclosure relates to a method of providing an edge sealing in the process of providing a vacuum insulated glass (VIG) unit. A first glass sheet (1a) and a second glass sheet (1b) is provided. A glass frit powder material (5) is heated to a softening temperature (Tfrit-powder) to soften the glass frit powder material, and the heated, softened glass frit powder material (5) is applied at the first glass sheet (1a) and/or the second glass sheet (1b). The first glass sheet (1a) and the second glass sheet (1b) are paired before or after applying the heated, softened glass frit powder material. The applied glass frit powder material is re-heated by use of at least one heat source (28, 26), the gap between the paired glass sheets is evacuated in a vacuum chamber (22) and the gap between the paired glass sheets is sealed to provide the VIG unit.

Abstract: A method of manufacturing a glass sheet assembly for a vacuum insulated glass unit includes applying an edge seal made of a first material to a perimeter of a first surface of a first glass sheet. The edge seal defining a discontinuity. The method also includes disposing a first surface of a second glass sheet on the edge seal such that a gap is defined between the first surface of the first glass sheet and the first surface of the second glass sheet. The method further includes evacuating the gap through the discontinuity and locally heating the edge seal to at least partially seal the discontinuity.

Abstract: The present disclosure relates to a method of applying a seal material in manufacturing a vacuum insulated glazing (VIG) unit, wherein the VIG unit comprises a first glass sheet, having a first interior major surface and a first exterior major surface, a second glass sheet having a second interior major surface and second exterior major surface, the glass sheets are placed in parallel with said interior major surfaces facing each other and providing a gap therein between, and a seal material for providing a seal of said gap, wherein the method comprises the steps of providing a glass sheet, and arranging said seal material on a major surface of at least one of said glass sheets by means of a nozzle having a nozzle opening of elongated shape, such as a rectangular or oval shape, providing a plurality of support structures on the major surface of at least one of the glass sheets, pairing said first glass sheet and said second glass sheet so that the surface of the at least one of said glass sheets comprising th

Abstract: The present disclosure relates to a method of applying a seal material on a glass sheet surface of one or more tempered glass sheets for a vacuum insulated glass unit. The method comprises the steps of: obtaining by means of a sensor system (4) surface variation data of at least one tempered glass sheet (3, 30) for said a vacuum insulated glass (VIG) unit, and applying seal material (2) for an edge seal at a surface (3a, 30a) of said one or more tempered glass sheet (3, 30) by means of one or more nozzles (5) having a nozzle opening (6) for dispensing said seal material. The method further comprises by means of a control system (7) controlling one or more adjustment systems (9, 10, 11) influencing on the applying of said seal material by said one or more nozzles (5) based on said obtained surface variation data.

Abstract: A compressible pillar for the preparation of a vacuum insulated glazing (VIG) unit, having a longitudinal extent in the pre-compressed state and including a deformable part having an open structure, which open structure will at least partially collapse when the pillar is subject to a compression force acting in the longitudinal direction of the pillar, the compression force being of at least one value selected within the range of 60 N to 320 N, the pillar will exhibit a partly irreversible deformation causing a reduction in the longitudinal extent of the pillar when the pillar is subjected to the compression force, so that when the compression force is fully released the pillar will exhibit an expansion in the longitudinal direction of the pillar which is less that the reduction in the longitudinal extent of the pillar. Further is shown a process for manufacturing of a compressible pillar, a method of producing a VIG unit as well as a VIG unit.

Abstract: The present disclosure relates to methods of providing an edge sealing (2) for a vacuum insulated glass (VIG) unit. The methods may comprise providing one or more glass sheets (1a, 1b). A glass material (5) such as a solder glass material is heated to soften the glass material (5), and the heated glass material is then applied along edges of the one or more glass sheets (1a, 1b) to provide an edge sealing (2) for sealing a gap (13) between paired glass sheets (1a, 1b). The heated glass material (5) may be applied by means of a dispensing nozzle (6). The disclosure moreover relates to a VIG unit and a system.

Abstract: A method of manufacturing a vacuum insulated glazing (VIG) unit comprising depositing a coating material on at least a portion of a pillar core under conditions effective to provide a deposited coating material; annealing the deposited coating material at a reduced pressure and in an inert atmosphere to form a coating layer on the pillar core, thereby providing a coated pillar; disposing at least one of the coated pillar between first and second substantially parallel glass panes; disposing a peripheral seal material around a periphery of the first and the second glass panes to form a pre-sealed VIG unit; and heating the pre-sealed VIG unit under reduced pressure to form the peripheral seal and a sealed cavity between the first and second glass panes.

Abstract: A compressible pillar for the preparation of a vacuum insulated glazing (VIG) unit, having a longitudinal extent in the pre-compressed state and including a deformable part having an open structure, which open structure will at least partially collapse when the pillar is subject to a compression force acting in the longitudinal direction of the pillar, the compression force being of at least one value selected within the range of 60 N to 320 N, the pillar will exhibit a partly irreversible deformation causing a reduction in the longitudinal extent of the pillar when the pillar is subjected to the compression force, so that when the compression force is fully released the pillar will exhibit an expansion in the longitudinal direction of the pillar which is less that the reduction in the longitudinal extent of the pillar. Further is shown a process for manufacturing of a compressible pillar, a method of producing a VIG unit as well as a VIG unit.

Abstract: A compressible pillar for the preparation of a vacuum insulated glazing (VIG) unit, having a longitudinal extent in the pre-compressed state and including a deformable part having an open structure, which open structure will at least partially collapse when the pillar is subject to a compression force acting in the longitudinal direction of the pillar, the compression force being of at least one value selected within the range of 60 N to 320 N, the pillar will exhibit a partly irreversible deformation causing a reduction in the longitudinal extent of the pillar when the pillar is subjected to the compression force, so that when the compression force is fully released the pillar will exhibit an expansion in the longitudinal direction of the pillar which is less that the reduction in the longitudinal extent of the pillar. Further is shown a process for manufacturing of a compressible pillar, a method of producing a VIG unit as well as a VIG unit.

Abstract: A vacuum insulated glazing unit comprising a first glass pane and a second glass pane arranged in parallel, the second glass pane spaced apart from the first glass pane, wherein each glass pane comprises inner and outer surfaces, wherein the inner surfaces define a gap therebetween; a plurality of spacers arranged in the gap between of the inner surface of the first glass pane and the inner surface of the second glass pane; and a side seal material attached around a periphery of the first glass pane and the second glass pane, thereby forming a sealed cavity between the glass panes, wherein at least a portion of the inner surface of the first glass pane comprises a strengthened portion that comprises a plurality of implanted ions, wherein the plurality of implanted ions are nitrogen ions, carbon ions, argon ions, or a combination comprising at least one of the foregoing.

Abstract: An arrangement for producing vacuum insulated glazing (VIG) unit and an evacuation cup suitable for such use as well as a method therefore is presented so as to provide a more uniform or homogeneous heating of the part of the glass pane containing the evacuation hole and possibly a soldering material arranged around the evacuation hole, in particular for the reason of preventing larger temperature gradients in the glass pane between the part covered by the evacuation cup and the remaining part and for avoiding excessive locale temperatures of the glass pane under the evacuation cup, which may be harmful the durability of the glass pane, in particular when the glass pane is made from tempered glass, where the tempering of the glass may be influenced by excessive temperatures.

Abstract: A compressible pillar is disclosed for the preparation of a vacuum insulated glazing (VIG) unit, having a longitudinal extent in a longitudinal direction when in an uncompressed state, and comprising: a deformable part comprising an open structure, wherein the open structure at least partially collapses under a compression force acting in the longitudinal direction of the compressible pillar, the compression force being of at least one value selected within the range of 60 N to 320 N such as a value of the compression force being selected from the range of 60 N to 140 N, from the range of 140 N to 230 N, or from the range of 230 N to 320 N, wherein the longitudinal extent of the compressible pillar decreases to a compressed longitudinal extent when the compressible pillar is subjected to the compression force, and wherein the compressed longitudinal extent of the compressible pillar increases to an expanded longitudinal extent when the compression force is released, wherein the increase in the longitudinal

Abstract: A compressible pillar is disclosed for the preparation of a vacuum insulated glazing (VIG) unit, having a longitudinal extent in a longitudinal direction when in an uncompressed state, and comprising: a deformable part comprising an open structure, wherein the open structure at least partially collapses under a compression force acting in the longitudinal direction of the compressible pillar, the compression force being of at least one value selected within the range of 60 N to 320 N such as a value of the compression force being selected from the range of 60 N to 140 N, from the range of 140 N to 230 N, or from the range of 230 N to 320 N, wherein the longitudinal extent of the compressible pillar decreases to a compressed longitudinal extent when the compressible pillar is subjected to the compression force, and wherein the compressed longitudinal extent of the compressible pillar increases to an expanded longitudinal extent when the compression force is released, wherein the increase in the longitudinal ex

Abstract: A vacuum insulated glazing unit comprising a first glass pane and a second glass pane arranged in parallel, the second glass pane spaced apart from the first glass pane, wherein each glass pane comprises inner and outer surfaces, wherein the inner surfaces define a gap therebetween; a plurality of spacers arranged in the gap between of the inner surface of the first glass pane and the inner surface of the second glass pane; and a side seal material attached around a periphery of the first glass pane and the second glass pane, thereby forming a sealed cavity between the glass panes, wherein at least a portion of the inner surface of the first glass pane comprises a strengthened portion that comprises a plurality of implanted ions, wherein the plurality of implanted ions are nitrogen ions, carbon ions, argon ions, or a combination comprising at least one of the foregoing.

Abstract: An arrangement for producing vacuum insulated glazing (VIG) unit and an evacuation cup suitable for such use as well as a method therefore is presented so as to provide a more uniform or homogeneous heating of the part of the glass pane containing the evacuation hole and possibly a soldering material arranged around the evacuation hole, in particular for the reason of preventing larger temperature gradients in the glass pane between the part covered by the evacuation cup and the remaining part and for avoiding excessive locale temperatures of the glass pane under the evacuation cup, which may be harmful the durability of the glass pane, in particular when the glass pane is made from tempered glass, where the tempering of the glass may be influenced by excessive temperatures.

Abstract: Disclosed is a coated article having a substrate with an adherent, abrasion resistant alkene-silane plasma reaction product coating. In a preferred exemplification the coating is substantially transparent to visible light and partially absorbing to ultraviolet light. The coating is a plasma assisted chemical vapor deposition deposited coating.

Abstract: An improved p-type semiconductor alloy film, an improved substantially intrinsic amorphous semiconductor alloy film, improved photovoltaic and photoresponsive devices incorporating such films and r.f. and microwave glow discharge methods for fabricating same. The improved semiconductor alloy films preferably include at least silicon deposited by the glow discharge of a compound containing at least silicon and a boron species that remains substantially monoatomic as it is incorporated into the silicon matrix. The p-type film is particularly stable, is characterized by a non-narrowed band gap, reduced bulk stress, improved morphology, growth and adhesion and reduced peeling and cracking. The substantially intrinsic film is characterized by substantially reduced Staebler-Wronski degradation. The method includes the novel step of introducing a boron species that does not form higher order boron hydrides or other boron polymers or oligomers in the glow discharge plasma.

Abstract: A microwave glow discharge method for the deposition of p-doped semiconductor alloy material, which material is characterized by mono-atomic and tetrahedral incorporation of boron species into the semiconductor host matrix, thereby providing a p-doped semiconductor alloy material characterized by reduced bulk strain, reduced nucleation of undesirable morphological growth, improved adhesion to a substrate and reduced peeling and cracking.