A pre-fractured glass laminate that includes: a glass substrate comprising a thickness, a pair of opposed primary surfaces, a compressive stress region, a central tension (CT) region and a plurality of cracks; a second phase comprising a polymer or a cured resin within the plurality of cracks; a backing layer; and an interlayer disposed between one of the primary surfaces of the substrate and the backing layer. The compressive stress region extends from each of the primary surfaces to a first selected depth in the substrate. Further, the plurality of cracks is located in the CT region.

Disclosed herein are embodiments of a borosilicate glass composition having a unique fracture behavior. The borosilicate glass composition may be incorporated into a glass laminate including a first glass ply and a second glass ply. The second glass ply may comprise the borosilicate glass composition. The second glass ply may have a coefficient of thermal expansion of less than or equal to 5.1 ppm°/C. A combined thickness of the first glass ply and the second glass ply may be greater than or equal to 3.7 mm and less than or equal to 6.0 mm, and a ratio of the second thickness to the combined thickness is greater than or equal to 0.825. The second glass ply does not fail when the first major surface is impacted by a Vickers diamond impactor at an impact energy of 0.25 Joules.

The present disclosure relates to bullet-resistant laminated glass having at least three sheets of glass. One of the sheets of glass faces the impact side as a cover sheet, and one sheet of glass is formed as a closure sheet facing away from the impact side. Between the cover sheet and the closure sheet, one or more intermediate sheets are disposed, these sheets of glass being connected to each other by composite layers. The composite layers are formed by flexible and dimensionally unstable films and/or cast compounds. The composite layers do not consist of polycarbonate, polyurethane or polymethylmethacrylate. In order to prevent splinter output on the rear side, this glass composite has a closure sheet on the rear side consisting of thermally or chemically prestressed glass.

An insulating glazing unit may be configured to provide both visible transparency and bullet-resistance. The bullet resistant properties of the unit may be achieved through the combination and coordination of different materials forming the panes of the unit. For example, the insulating glazing unit may include multiple laminate panes separated by a spacer. Each laminate pane may include at least two transparent rigid substrates joined by a layer of laminate material. The laminate material used in one laminate pane may be different than the laminate material used in another pane. For example, one pane may utilize a laminate material that is soft and flexible. This may help absorb and dissipate the impact of a projectile. By contrast, another laminate pane may utilize a laminate material that is stiff and rigid. This may help provide a final stopping force to a projectile.

Laminated articles and layered articles, for example, low alkali glass laminated articles and layered articles useful for, for example, electrochromic devices are described.

The present disclosure relates to a method of providing a laminated vacuum insulated glass (VIG) unit (1), wherein the method comprises: providing a lamination assembly (10) comprising a vacuum insulated glass (VIG) unit (11) comprising at least two glass sheets (11a, 11b) separated by a plurality of support structures (12) distributed in a gap (13) between the glass sheets (11a, 11b), and a lamination layer (2) arranged between one of the glass sheets (11a, 11b) of the vacuum insulated glass (VIG) unit (11) and a further sheet (3). The further sheet (3) may be subjected to a first heating temperature (T1) by means of a first heating arrangement (9a), and the glass sheet (11a) of the vacuum insulated glass (VIG) unit (11) facing away from the further sheet (3) may be subjected to a second heating temperature (T2) by means of a second heating arrangement (9b), wherein the first heating temperature (T1) is higher than the second heating temperature (T2). The disclosure additionally relates to a system (100) for providing laminated vacuum insulated glass (VIG) units (1), and use of such a system.

A lateral glazing for a transport vehicle, particularly train glazing, the glazing being fixed multiple glazing, with an openable window, the glazing including at least one substrate intermediate face which includes, in a part of the glazing that is situated under said window, on the one hand, a main sheet of glass and, on the other hand, a main sheet of plastic which is situated in contact between the intermediate face and the main sheet of glass without the main sheet of glass and the main sheet of plastic being in contact with the glazing frame structure.

A thermochromic, near infrared (NIR) absorbing interlayer. The interlayer includes a NIR-absorbing substance dispersed or dissolved in a polymer matrix and a thermochromic material or system. The interlayer has an internal visible light transmission above 50% and an internal solar energy transmission below 55% when the interlayer is at 15° C. and an internal visible light transmission below 20% and an internal solar energy transmission below 20% when the interlayer is at 75° C. The internal haze of the interlayer is below 3.5%.

A laminated glass includes a glass plate including a first plane compressive region having a prescribed width inside an outer peripheral edge of the glass plate in a plan view, a first plane tensile region adjacent to an inner peripheral side of the first plane compressive region and having a prescribed width, a neutral region occupying an inner peripheral side of the first plane tensile region, and a second plane compressive region located on an inner peripheral side of the first plane compressive region in a plan view.

A hurricane-resistant laminated pane comprises a first sheet of thermally strengthened glass having a thickness in the range of from 2 to 24 mm, a second sheet of chemically tempered glass having a thickness in the range of from 0.3 to 1 mm and a surface compression of at least 100 MPa, and a polymer interlayer adhered between the first sheet and the second sheet. A process for making such a pane and a window comprising such a pane are also disclosed.