Abstract: A glass ribbon coated with a flexible material, the flexible coating forming a flexible web portion that extends from an edge of the glass ribbon at least one millimeter. The flexible web portion can be used to facilitate handling of the glass ribbon in a manufacturing process, and may include registration markings, or perforations, that further facilitate precise positioning of the ribbon.

Abstract: A glass ribbon coated with a flexible material, the flexible coating forming a flexible web portion that extends from an edge of the glass ribbon at least one millimeter. The flexible web portion can be used to facilitate handling of the glass ribbon in a manufacturing process, and may include registration markings, or perforations, that further facilitate precise positioning of the ribbon.

Abstract: An apparatus for redirecting a glass ribbon assembly from a first glass conveyance path to a second glass conveyance path. The apparatus includes a glass ribbon assembly source for providing the glass ribbon assembly including a flexible glass substrate that includes a first surface and a second surface that extend between a first edge and a second edge, first and second handling tabs affixed to the flexible glass substrate edges, and a primary roll member located downstream of the glass ribbon assembly source. The first glass conveyance path extends from the glass ribbon assembly source to the primary roll member, and the second glass conveyance path extends from the primary roll member in a downstream direction. Contact surfaces of the primary roll member are tangential to the first and second glass conveyance paths, and the second glass conveyance path is non-planar with the first glass conveyance path.

Abstract: A flexible substrate are disclosed comprising an amorphous inorganic composition, wherein the substrate has a thickness of less than about 250 ?m and has at least one of: a) a brittleness ratio less than about 9.5 (?m)?1/2, or b) a fracture toughness of at least about 0.75 MPa·(m)1/2. Electronic devices comprising such flexible devices are also disclosed. Also disclosed is a method for making a flexible substrate comprising selecting an amorphous inorganic material capable of forming a substrate having a thickness of less than about 250 ?m and having at least one of: a) a brittleness ratio of less than about 9.5 (?m)?1/2, or b) a fracture toughness of at least about 0.75 MPa·(m)1/2; and then forming a substrate from the selected inorganic material.

Abstract: A flexible substrate are disclosed comprising an amorphous inorganic composition, wherein the substrate has a thickness of less than about 250 ?m and has at least one of: a) a brittleness ratio less than about 9.5 (?m)?1/2, or b) a fracture toughness of at least about 0.75 MPa·(m)1/2. Electronic devices comprising such flexible devices are also disclosed. Also disclosed is a method for making a flexible substrate comprising selecting an amorphous inorganic material capable of forming a substrate having a thickness of less than about 250 ?m and having at least one of: a) a brittleness ratio of less than about 9.5 (?m)?1/2, or b) a fracture toughness of at least about 0.75 MPa·(m)1/2; and then forming a substrate from the selected inorganic material.

Abstract: A substrate (100) comprising a sheet of either a glass, a glass ceramic, or a ceramic and having increased edge strength. A polymeric edge coating (120) prevents creation of strength limiting defects along the edges of the substrate and protects the bend strength of the edges. The substrate may also have at least two parallel high strength edges (110, 112) and an edge coating (120) of a polymeric material covering at least a portion of each of the high strength edges to preserve the high strength edges from the introduction of defects and damage to the edges. Each of the two parallel high strength edges has a bend strength that is capable of less than about 2% failure probability at a stress level of 200 MPa over a test length of 50 mm. A method of making the substrate is also provided.

Abstract: An optical waveguide device includes a flexible glass optical waveguide structure including a flexible glass substrate having a thickness of no greater than about 0.3 mm The flexible glass substrate has at least one waveguide feature that transmits optical signals through the flexible glass substrate. The at least one waveguide feature is formed of glass material that forms the flexible glass substrate. An electrical device is located on a surface of the flexible glass substrate.

Abstract: A method of performing ion exchange of a thin, flexible glass substrate having an average thickness equal to or less than about 0.3 mm to chemically strengthen the glass substrate is disclosed. The chemically strengthened glass substrate comprises a first compressive stress layer having a first depth of layer, and a second compressive stress layer having a second depth of layer, the first and second stress layers being separated by a layer of tensile stress. A laminated article comprising the chemically strengthened glass substrate is also described.

Abstract: Packages and methods of packaging a plurality of glass sheets provide a stack of glass sheets with an interleaf protective sheet positioned between each adjacent pair of glass sheets. An outer portion of each interleaf protective sheet is bent over a portion of the peripheral edge of one of a corresponding adjacent pair of glass sheets to discourage relative shifting of the glass sheets with respect to one another. The stack of glass sheets are sandwiched between pressure members of an outer housing such that the pressure members each apply a support pressure that is distributed over an outer surface of a corresponding one of the pair of outermost glass sheets of the stack of glass sheets.

Abstract: An apparatus for redirecting a glass ribbon assembly from a first glass conveyance path to a second glass conveyance path. The apparatus includes a glass ribbon assembly source for providing the glass ribbon assembly including a flexible glass substrate that includes a first surface and a second surface that extend between a first edge and a second edge, first and second handling tabs affixed to the flexible glass substrate edges, and a primary roll member located downstream of the glass ribbon assembly source. The first glass conveyance path extends from the glass ribbon assembly source to the primary roll member, and the second glass conveyance path extends from the primary roll member in a downstream direction. Contact surfaces of the primary roll member are tangential to the first and second glass conveyance paths, and the second glass conveyance path is non-planar with the first glass conveyance path.

Abstract: Disclosed are controlled chemical etching processes used to modify the geometry of surface flaws in thin glass substrates and glass substrate assemblies formed therefrom, and in particular glass substrates suitable for the manufacture of active matrix displays that are essentially free of alkali metal oxides such as Na2O, K2O and Li2O.

Abstract: Packages and methods of packaging a plurality of glass sheets provide a stack of glass sheets with an interleaf protective sheet positioned between each adjacent pair of glass sheets. An outer portion of each interleaf protective sheet is bent over a portion of the peripheral edge of one of a corresponding adjacent pair of glass sheets to discourage relative shifting of the glass sheets with respect to one another. The stack of glass sheets are sandwiched between pressure members of an outer housing such that the pressure members each apply a support pressure that is distributed over an outer surface of a corresponding one of the pair of outermost glass sheets of the stack of glass sheets.

Abstract: Disclosed are controlled chemical etching processes used to modify the geometry of surface flaws in thin glass substrates and glass substrate assemblies formed therefrom, and in particular glass substrates suitable for the manufacture of active matrix displays that are essentially free of alkali metal oxides such as Na2O, K2O and Li2O.

Abstract: A flexible glass structure includes a flexible glass substrate having a thickness of no more than about 0.3 mm. A stiffening layer is coupled to a surface of the flexible glass substrate. The stiffening layer includes at least one stiffening element extending along the surface of the flexible glass substrate in a running direction having a Young's modulus selected to provide a preferred bending axis of the flexible glass substrate in a direction substantially parallel to the running direction of the stiffening element.

Abstract: A method of forming a flexible glass-polymer laminate structure includes heating a polymer layer to an elevated temperature of greater than 20° C. and below a working temperature of a flexible glass substrate adjacent the polymer layer. The flexible glass substrate has a thickness of no more than about 0.3 mm. The flexible glass substrate is shaped with the polymer layer at the elevated temperature. The polymer layer is cooled below the elevated temperature such that the flexible glass-polymer laminate structure maintains a non-planar formation.

Abstract: A strengthened layered glass structure includes a first substrate layer comprising a flexible glass sheet having a thickness of less than or equal to 300 ?m, a second substrate layer, and a sintered glass frit material layer coupled to a first surface of the first substrate layer and a second surface of the second substrate layer, the sintered glass frit material layer comprising a sintered glass frit coupled to the first and second surfaces providing the flexible glass sheet with a compressive stress of at least about 100 MPa across a thickness of the flexible glass sheet.

Abstract: A first glass-ribbon portion (12) and a second portion (22) of a glass ribbon (10) are separated from one another by a gap (40), and a splice joint (30) coupling the first glass-ribbon portion to the second portion. A splice member (31) of the splice joint has a Young's modulus and cross sectional area such that, when subject to a force of 20 kg, the splice member undergoes an elongation of ?20%. A filler material (80) may be disposed in the gap. Also, there are disclosed methods of splicing a glass ribbon, and preparing a coated glass ribbon for splicing. Tape (70) is applied to glass ribbon in one embodiment of a method of splicing the glass ribbon. In this embodiment, the glass ribbon is cut together with the tape so as to create a free end in the glass ribbon.

Abstract: Methods and apparatus for guiding flexible glass ribbons (13) without mechanically contacting the central portion (4) of the ribbon are provided in which two curved sections are formed in the ribbon which stiffen the ribbon so that lateral forces can be applied to the ribbon without causing it to buckle. The curvatures of the curved sections are along the direction of motion (15) of the ribbon and can be produced using curved air-bars (12,14) and/or pairs of cylindrical rollers (5a,5b,16a,16b). The lateral forces can be applied by pairs of guide rollers (7a,7b,9a,9b) which can be mounted on spring-loaded pivot arms (6,19,29) and can have a complaint outer coating or sleeve (35). The guiding system can be used in the winding of the glass ribbon onto a cylindrical core (11).

Abstract: Pads, for cutting thin glass on machines designed for thicker glass, are provided with variable viscoelasticity. In further examples, methods of cutting a thin sheet of glass on a machine designed for thicker glass include the step of placing a pad between a working surface and the sheet of glass. In still further examples, methods of forming a scribing mark on a sheet of glass include the step of placing a compressible pad between a sheet of glass and a working surface.

Abstract: Glass web including a first glass-web portion (30), a second portion (40), and a splice joint (50) coupling the first glass-web portion to the second portion, wherein the slice joint includes a splice member (60) with at least one gas-permeable attachment portion. In further examples, methods of splicing a first glass-web portion to a second portion include the step of splicing the first glass-web portion to the second portion with a splice member, wherein the step of splicing includes attaching a gas-permeable attachment portion of the splice member to the first glass-web portion.