A device and a process for manufacturing a bent individual glass sheet including a peripheral compression belt, wherein the process includes the heating thereof to its bending temperature in a furnace, the individual bending thereof, and the general cooling thereof. One zone of the sheet at least partially inside the peripheral compression belt, referred to as locally cooled zone, undergoes, after the heating of the sheet, a local cooling faster than the general cooling, when the sheet is at a temperature of at least 530? C. The cutting of the sheet on the locally cooled zone creates edges having edge compressive stresses.

A sheet of glass can be formed in a batch process by introducing molten glass onto a layer of molten tin within a tank. The tank may be outfitted with infrared emitters to control the amount of heat delivered to the tank while the sheet of glass is formed. A lower surface of the tank can have a three-dimensional shape, and the molten tin may be removed from the tank while the sheet of glass is ductile so that the sheet of glass is molded by the three-dimensional shape, thereby producing a shaped sheet of glass. The delivery of infrared energy to the tank may be facilitated by one or more ceramic glass surface.

A sheet of glass can be formed in a batch process by introducing molten glass onto a layer of molten tin within a tank. The tank may be outfitted with infrared emitters to control the amount of heat delivered to the tank while the sheet of glass is formed. A lower surface of the tank can have a three-dimensional shape, and the molten tin may be removed from the tank while the sheet of glass is ductile so that the sheet of glass is molded by the three-dimensional shape, thereby producing a shaped sheet of glass. The delivery of infrared energy to the tank may be facilitated by one or more ceramic glass surface.

A strengthened cover glass or glass-ceramic sheet or article as well as processes and systems for making the strengthened glass or glass-ceramic sheet or article is provided for use in consumer electronic devices. The process comprises cooling the cover glass sheet by non-contact thermal conduction for sufficiently long to fix a surface compression and central tension of the sheet. The process results in thermally strengthened cover glass sheets for use in or on consumer electronic products.

A strengthened cover glass or glass-ceramic sheet or article as well as processes and systems for making the strengthened glass or glass-ceramic sheet or article is provided for use in consumer electronic devices. The process comprises cooling the cover glass sheet by non-contact thermal conduction for sufficiently long to fix a surface compression and central tension of the sheet. The process results in thermally strengthened cover glass sheets for use in or on consumer electronic products.

A method and/or system for reducing glass failures following tempering from inclusions, such as nickel sulfide based inclusions. During at least part of a cooling down period of a thermal tempering process, additional energy is directed at inclusion(s), such as nickel sulfide based inclusion(s), in the glass. The glass may be soda-lime-silica based float glass. The additional energy may be in the form of, for example, visible and/or infrared (IR) light from at least one light source that is directed toward the nickel sulfide based inclusion(s).

A method and/or system for reducing glass failures following tempering from inclusions, such as nickel sulfide based inclusions. During at least part of a cooling down period of a thermal tempering process, additional energy is directed at inclusion(s), such as nickel sulfide based inclusion(s), in the glass. The glass may be soda-lime-silica based float glass. The additional energy may be in the form of, for example, visible and/or infrared (IR) light from at least one light source that is directed toward the nickel sulfide based inclusion(s).

A glass substrate comprises: a first position, wherein a tensile stress of the glass substrate is insufficient to cause fragmentation of the glass substrate into small pieces upon fracture of the glass substrate; and a second position, wherein the glass substrate is bent relative to the first position, and wherein the tensile stress of the glass substrate is sufficient to cause fragmentation of the glass substrate into small pieces upon fracture of the glass substrate. The glass substrate can include a first surface and a second surface. In the first position, the first surface and the second surface of the glass substrate can be planar. In the second position, the first surface and the second surface of the glass substrate can be planar. The small pieces can be generally cubic. In the second position, the glass substrate can be bent uniaxially along a bend axis of the glass substrate.

A glass substrate comprises: a first position, wherein a tensile stress of the glass substrate is insufficient to cause fragmentation of the glass substrate into small pieces upon fracture of the glass substrate; and a second position, wherein the glass substrate is bent relative to the first position, and wherein the tensile stress of the glass substrate is sufficient to cause fragmentation of the glass substrate into small pieces upon fracture of the glass substrate. The glass substrate can include a first surface and a second surface. In the first position, the first surface and the second surface of the glass substrate can be planar. In the second position, the first surface and the second surface of the glass substrate can be planar. The small pieces can be generally cubic. In the second position, the glass substrate can be bent uniaxially along a bend axis of the glass substrate.

A quench arrangement for quenching glass sheets includes a main quench station having upper and lower main quench heads for performing a primary quench operation on a glass sheet, a first lower secondary quench head located downstream of the main quench station, and a second lower secondary quench head located downstream of the first lower secondary quench head. The arrangement further includes an upper secondary quench system positioned above the first and second lower secondary quench heads, and the upper secondary quench system is cooperable with the lower secondary quench heads to perform further cooling of the glass sheet. The arrangement further includes a conveyor located above the second lower secondary quench head for moving the glass sheet away from the second lower secondary quench head.