Abstract: An apparatus for forming laminated sheet glass, including: a lower pipe and a first upper pipe separated by a first gap on one side and second gap on the other side, the apparatus being configured so that the position of the lower pipe relative to the first upper pipe are each independently adjustable to control the dimensions of the first gap, the second gap, or both, as defined herein. Also disclosed is a method for forming laminated sheet glass or articles thereof using the aforementioned glass laminating apparatus, as defined herein.

Abstract: A laminated glass article includes a core layer and a clad layer directly adjacent to the core layer. The core layer is formed from a core glass composition. The clad layer is formed from a clad glass composition. An average clad coefficient of thermal expansion (CTE) is less than an average core CTE such that the clad layer is in compression and the core layer is in tension. A compressive stress of the clad layer decreases with increasing distance from an outer surface of the clad layer within an outer portion of the clad layer and remains substantially constant with increasing distance from the outer surface of the clad layer within an intermediate portion of the clad layer disposed between the outer portion and the core layer.

Abstract: An apparatus for making a laminate glass ribbon, the glass ribbon having: a center laminate region, a first edge, a second edge, and first, second, third, and fourth, beads portions as defined herein, the apparatus includes: a bead thermal conditioning region including: a fluid source for selectively applying a fluid to one or more of the first, second, third, and fourth bead portions. Also disclosed is a method for bead thermal conditioning in the disclosed laminate fusion apparatus.

Abstract: Shaped glass structures, in particular to curved glass structures, having optically improved transmittance are provided along with methods of making such glass structures. Articles and methods described herein mask tube or reforming defects with help of refractive index-matching substances (e.g. optically clear adhesives) and/or additional glass layers. The articles and methods are applicable to any shaped glass, and is particularly useful for 3D-shaped parts for use in portable electronic devices.

Abstract: A flexible seal positioned between two muffles of a glass laminate fusion draw machine comprises, in order from the interior to the exterior of the muffles, a radiation shield comprising overlapping rows of refractory material, a thermal seal comprising a blanket of temperature resistance material, and an air seal comprising a sheet of high temperature elastomeric material. The seal may further comprising a secondary radiation shield positioned between the thermal seal and the air seal.

Abstract: An apparatus for forming laminated sheet glass comprises a first upper pipe and a lower pipe and an adjustment mechanism comprising first and second first-upper-pipe suspension rods supported by a first horizontally extending support member, third and fourth first-upper-pipe suspension rods supported by a second horizontally extending support member the first upper pipe supported, directly or indirectly, by the first, second, third, and fourth first-upper-pipe suspension rods, a first and second lower-pipe suspension rod supported by the first horizontally extending support member and a third and fourth lower-pipe suspension rod and supported by the second horizontally extending support member, lower pipe supported, directly or indirectly, by the first, second, third, and fourth lower-pipe suspension rods, each respective rod suspended so as to be horizontally adjustable and independently vertically adjustable.

Abstract: An apparatus for making a laminate glass ribbon, the glass ribbon having: a center laminate region, a first edge, a second edge, and first, second, third, and fourth, beads portions as defined herein, the apparatus includes: a bead thermal conditioning region including: a fluid source for selectively applying a fluid to one or more of the first, second, third, and fourth bead portions. Also disclosed is a method for bead thermal conditioning in the disclosed laminate fusion apparatus.

Abstract: Repositionable heater assemblies and methods of controlling temperature of glass in production lines using the repositionable heater assemblies are disclosed. The repositionable heater assembly includes a support frame, a first sled and a second sled each coupled to the support frame with bearing members that allow the first sled and the second sled to translate in a longitudinal direction. Each of the first sled and the second sled include at least one heating element, where the heating elements are spaced apart from the glass ribbon a spacing distance. The first and second sleds are movable in the longitudinal direction to controlling the spacing distance between the heating elements of the first sled and the second sled and the glass ribbon to manage temperature of the glass ribbon.

Abstract: A glass forming apparatus and method include a weir on at least a first side of a molten core glass reservoir. The weir includes an inclined surface that, in the intended direction of molten glass flow, slopes downward in the vertical direction while extending away from the molten core glass reservoir in the horizontal direction. A source of molten clad glass is configured above the glass forming apparatus such that when molten clad glass is flowing down and molten core glass is flowing over the weir, the molten clad glass drops onto the molten core glass at a highest upstream contact point that is located directly above the inclined surface of the weir.

Abstract: An apparatus for forming laminated sheet glass, including: a lower pipe and a first upper pipe separated by a first gap on one side and second gap on the other side, the apparatus being configured so that the position of the lower pipe relative to the first upper pipe are each independently adjustable to control the dimensions of the first gap, the second gap, or both, as defined herein. Also disclosed is a method for forming laminated sheet glass or articles thereof using the aforementioned glass laminating apparatus, as defined herein.

Abstract: Repositionable heater assemblies and methods of controlling temperature of glass in production lines using the repositionable heater assemblies are disclosed. The repositionable heater assembly includes a support frame, a first sled and a second sled each coupled to the support frame with bearing members that allow the first sled and the second sled to translate in a longitudinal direction. Each of the first sled and the second sled include at least one heating element, where the heating elements are spaced apart from the glass ribbon a spacing distance. The first and second sleds are movable in the longitudinal direction to controlling the spacing distance between the heating elements of the first sled and the second sled and the glass ribbon to manage temperature of the glass ribbon.

Abstract: Repositionable heater assemblies and methods of controlling temperature of glass in production lines using the repositionable heater assemblies are disclosed. The repositionable heater assembly includes a support frame, a first sled and a second sled each coupled to the support frame with bearing members that allow the first sled and the second sled to translate in a longitudinal direction. Each of the first sled and the second sled include at least one heating element, where the heating elements are spaced apart from the glass ribbon a spacing distance. The first and second sleds are movable in the longitudinal direction to controlling the spacing distance between the heating elements of the first sled and the second sled and the glass ribbon to manage temperature of the glass ribbon.

Abstract: An apparatus for fusion draw glass manufacture, including at least one isopipe (110) having at least one weir (114); and a fluid discharge member in proximity to the at least one weir (114) of the at least one isopipe (110), the fluid discharge member is in fluid communication with a remote fluid source. The fluid source can be a source of a gas, liquid, solid or radiation. The fluid can be heated or cooled. At least one of the temperature properties, flow properties and thickness properties of the molten glass can be locally changed with the discharged fluid. A method of forming a glass-glass laminate sheet and uses of the laminate sheet are disclosed.

Abstract: Method and apparatus for making a glass tube 205 comprising the step of flowing molten glass 121 into a trough 201 such that the molten glass includes a free surface 614 within the trough, wherein a portion of the molten glass with a corresponding portion of the free surface overflows an endless weir 613 to form a molten glass tube 205 flowing down a cylindrical surface 603. The glass tube making apparatus comprises an endless weir 613 configured such that a free surface 614 of molten glass 121 within a trough 201 may overflow the endless weir 613 to form a molten glass tube 205 flowing down a cylindrical surface 603.

Abstract: A flexible seal positioned between two muffles of a glass laminate fusion draw machine comprises, in order from the interior to the exterior of the muffles, a radiation shield comprising overlapping rows of refractory material, a thermal seal comprising a blanket of temperature resistance material, and an air seal comprising a sheet of high temperature elastomeric material. The seal may further comprising a secondary radiation shield positioned between the thermal seal and the air seal.

Abstract: A glass fusion draw apparatus for molten glass stream thermal profile control, including: a first enclosure; and a first isopipe situated within the first enclosure, the first enclosure can include at least one first heating element assembly integral with the wall of the first enclosure, and the at least one first heating element is in proximity to a portion of molten glass stream over-flowing the first isopipe within the enclosure. The apparatus can also include a proximity or temperature sensing system associated with the first enclosure that senses and controls the thermal gradient properties of the molten glass stream or streams in the first enclosure. Also disclosed are methods of making and using the fusion apparatus.

Abstract: Repositionable heater assemblies and methods of controlling temperature of glass in production lines using the repositionable heater assemblies are disclosed. The repositionable heater assembly includes a support frame, a first sled and a second sled each coupled to the support frame with bearing members that allow the first sled and the second sled to translate in a longitudinal direction. Each of the first sled and the second sled include at least one heating element, where the heating elements are spaced apart from the glass ribbon a spacing distance. The first and second sleds are movable in the longitudinal direction to controlling the spacing distance between the heating elements of the first sled and the second sled and the glass ribbon to manage temperature of the glass ribbon.

Abstract: A glass forming apparatus and method include a weir on at least a first side of a molten core glass reservoir. The weir includes an inclined surface that, in the intended direction of molten glass flow, slopes downward in the vertical direction while extending away from the molten core glass reservoir in the horizontal direction. A source of molten clad glass is configured above the glass forming apparatus such that when molten clad glass is flowing down and molten core glass is flowing over the weir, the molten clad glass drops onto the molten core glass at a highest upstream contact point that is located directly above the inclined surface of the weir.