Disclosed is an inkjet ink that is jettable through standard inkjet nozzles, yet creates a non-abrasive non-porous three-dimensional glass structure on a 1-100 micron-scale without the need for additional processes beyond those normally used for the inkjet decoration of glass substrates. Such an inkjet ink can avoid the drawbacks noted above and is described herein.

Coated glass panes having a glass pane and a coating in at least one region of at least one side of the glass pane. The glass pane is composed of glass with SiO.sub.2 and B.sub.2O.sub.3. The coating includes first coating applied in at least one region of the at least one side. The first coating has a binder with SiO.sub.2 and a pigment. The glass pane, in the at least one region, has a flexural strength between at least 5 and at most 170 MPa.

Coated glass panes having a glass pane and a coating in at least one region of at least one side of the glass pane. The glass pane is composed of glass with SiO.sub.2 and B.sub.2O.sub.3. The coating includes first coating applied in at least one region of the at least one side. The first coating has a binder with SiO.sub.2 and a pigment. The glass pane, in the at least one region, has a flexural strength between at least 5 and at most 170 MPa.

Strengthened glass substrates with glass fits and methods for forming the same are disclosed. According to one embodiment, the present invention provides a glass frit with a coefficient of thermal expansion less than or equal to the coefficient of thermal expansion of the glass substrate where it is going to be painted. The glass frit of the present invention has similar ion exchange properties to the glass substrate that is going to be used to paint with the glass frit allowing the glass substrate to be ion-exchanged. The glass frit of the present invention is mixed with an organic carrier.

A robust coated core comprising a composite with a fused or sintered coating

A bent laminated glazing, in particular for a motor vehicle windscreen, includes a first glass sheet adhesively bonded to a second glass sheet by a lamination interlayer, the first glass sheet including a face, referred to as face 2, facing the lamination interlayer, and the second glass sheet including a face, referred to as face 4, opposite the lamination interlayer, wherein the face 2 includes a region, referred to as first region, coated with a layer of opaque mineral paint obtained from an aqueous paint composition including pigments and an aqueous solution of alkali metal silicate, and the face 4 includes a region, referred to as second region, coated with an enamel coating.

Embodiments of methods for forming strengthened glass articles comprise providing an exchangeable glass substrate having a coefficient of thermal expansion (CTE) between about 60×10-7/° C. to about 110×10-7/° C., depositing at least one decorative porous inorganic layer onto at least a portion of the surface of the glass substrate, wherein the decorative porous inorganic layer comprises a glass transition temperature (Tg)≥450° C., a glass softening temperature (Ts)≤650° C., wherein the difference in CTE values between the glass substrate and the decorative porous inorganic layer is within 10×10-7/° C.; and curing the glass substrate and the deposited decorative porous inorganic layer at a temperature greater than the Ts of the decorative porous inorganic layer; and chemically strengthening the cured glass substrate and the decorative porous inorganic layer thereon via ion exchange at a temperature below the Tg of the decorative porous inorganic layer.

Embodiments of methods for forming strengthened glass articles comprise providing an exchangeable glass substrate having a coefficient of thermal expansion (CTE) between about 60×10-7/° C. to about 110×10-7/° C., depositing at least one decorative porous inorganic layer onto at least a portion of the surface of the glass substrate, wherein the decorative porous inorganic layer comprises a glass transition temperature (Tg)≥450° C., a glass softening temperature (Ts)≤650° C., wherein the difference in CTE values between the glass substrate and the decorative porous inorganic layer is within 10×10-7/° C.; and curing the glass substrate and the deposited decorative porous inorganic layer at a temperature greater than the Ts of the decorative porous inorganic layer; and chemically strengthening the cured glass substrate and the decorative porous inorganic layer thereon via ion exchange at a temperature below the Tg of the decorative porous inorganic layer.

A windshield the invention is a windshield on which an information acquisition device that emits and/or receives light to acquire information from an outside of a vehicle can be arranged, and the windshield includes a glass sheet in which at least a portion is curved and on which a mask layer that blocks a field of vision from the outside of the vehicle is laminated, at least one opening being formed in the mask layer, an attachment member in which at least a portion is fixed at a position corresponding to the mask layer on the glass sheet and to which the information acquisition device can be attached, and a path member having a recessed portion for forming a path through which the information acquisition device emits and/or receives light between the path member and the glass sheet when the attachment member is fixed to the mask layer.

A windshield the invention is a windshield on which an information acquisition device that emits and/or receives light to acquire information from an outside of a vehicle can be arranged, and the windshield includes a glass sheet in which at least a portion is curved and on which a mask layer that blocks a field of vision from the outside of the vehicle is laminated, at least one opening being formed in the mask layer, an attachment member in which at least a portion is fixed at a position corresponding to the mask layer on the glass sheet and to which the information acquisition device can be attached, and a path member having a recessed portion for forming a path through which the information acquisition device emits and/or receives light between the path member and the glass sheet when the attachment member is fixed to the mask layer.