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 system, process and related sintered article are provided. The process includes supporting a piece of inorganic material with a pressurized gas and sintering the piece of inorganic material while supported by the pressurized gas by heating the piece of inorganic material to a temperature at or above a sintering temperature of the inorganic material such that the inorganic material is at least partially sintered forming the sintered article. The inorganic material is not in contact with a solid support during sintering. The sintered article, such as a ceramic article, is thin, has high surface quality, and/or has large surface areas.

A method for finishing a glass or ceramic article includes applying a force to the glass or ceramic article. The force is applied to the glass or ceramic article at least when the glass or ceramic article is at a temperature that is greater than or equal to a creep temperature of the glass or ceramic article. Holding the force to the glass or ceramic article as the glass or ceramic article is cooled to a temperature that is less than the creep temperature of the glass or ceramic article.

The invention discloses a method and an apparatus for drying and cooling a glass substrate. The method comprises the steps described below. The method delivers the glass substrate cleaned by a cleaner into a baking oven by a first roller device. It dries the glass substrate using an infrared heating plate installed in the baking oven. It delivers the dried glass substrate into a cooling chamber by a second roller device. It cools the dried glass substrate using a cooling plate installed in the cooling chamber. And it delivers the cooled glass substrate onto a platform of an air floating type coater, and coating the glass substrate. This invention also discloses an apparatus corresponding to the method. According to the embodiments of the present invention, it is possible to reduce the number of foreign particles on the glass substrate before coating, and the drying effect is excellent.

The invention discloses a method and an apparatus for drying and cooling a glass substrate. The method comprises the steps described below. The method delivers the glass substrate cleaned by a cleaner into a baking oven by a first roller device. It dries the glass substrate using an infrared heating plate installed in the baking oven. It delivers the dried glass substrate into a cooling chamber by a second roller device. It cools the dried glass substrate using a cooling plate installed in the cooling chamber. And it delivers the cooled glass substrate onto a platform of an air floating type coater, and coating the glass substrate. This invention also discloses an apparatus corresponding to the method. According to the embodiments of the present invention, it is possible to reduce the number of foreign particles on the glass substrate before coating, and the drying effect is excellent.

Systems, apparatuses and methods for processing a glass ribbon (22). A glass ribbon is supplied to an upstream side of a conveying apparatus (32). A pulling force is applied on the glass ribbon (22) at a downstream side of the conveying apparatus (32). The glass ribbon (22) is supported at first and second support devices along a travel path of the conveying apparatus (32). Each of the first and second support devices (72) establishes a non-rolling, line-type interface with the glass ribbon (22). Further, the first support device (72a) is spaced from the second support device (72c) along the travel path. In some embodiments, the line-type interface comprises a sliding interface or a gas bearing interface.

Thermally treating a glass sheet by holding the glass sheet between first and second gas bearings, the glass sheet having first and second major surfaces on opposite sides thereof and an edge surface surrounding the sheet and connecting the first and second major surfaces, the glass sheet being held with the first major surface adjacent to the first gas bearing and the second major surface adjacent to the second gas bearing, a glass of the glass sheet having a glass softening temperature, and, while holding the glass sheet between the first and second gas bearings, maintaining the glass sheet at a viscosity (t) for a time t such that the value of the expression (30 MPa times the integral from 0 to t of t/(t) with respect to t) is within the range of from 10 to 10.sup.6.

Thermally treating a glass sheet by holding the glass sheet between first and second gas bearings, the glass sheet having first and second major surfaces on opposite sides thereof and an edge surface surrounding the sheet and connecting the first and second major surfaces, the glass sheet being held with the first major surface adjacent to the first gas bearing and the second major surface adjacent to the second gas bearing, a glass of the glass sheet having a glass softening temperature, and, while holding the glass sheet between the first and second gas bearings, maintaining the glass sheet at a viscosity (t) for a time t such that the value of the expression (30 MPa times the integral from 0 to t of t/(t) with respect to t) is within the range of from 10 to 10.sup.6.

A glass processing apparatus to convey a glass sheet along a conveyance path can include a plurality of air bars spaced apart from each other along a first direction extending perpendicular to a central axis. Each air bar can include a surface with a plurality of fluid outlet ports. The glass processing apparatus can include a plurality of plates, and at least one of the plurality of plates can be positioned between ones of the plurality of air bars. Each plate can include a surface with a plurality of fluid inlet ports. The plurality of air bars and the plurality of plates can be symmetrically arranged relative to the central axis. Methods of processing a glass sheet can include emitting fluid from the plurality of fluid outlet ports of each of the plurality of air bars, thereby providing a cushion of fluid.

A glass processing apparatus to convey a glass sheet along a conveyance path can include a plurality of air bars spaced apart from each other along a first direction extending perpendicular to a central axis. Each air bar can include a surface with a plurality of fluid outlet ports. The glass processing apparatus can include a plurality of plates, and at least one of the plurality of plates can be positioned between ones of the plurality of air bars. Each plate can include a surface with a plurality of fluid inlet ports. The plurality of air bars and the plurality of plates can be symmetrically arranged relative to the central axis. Methods of processing a glass sheet can include emitting fluid from the plurality of fluid outlet ports of each of the plurality of air bars, thereby providing a cushion of fluid.