Disclosed herein are apparatuses for producing a glass ribbon, the apparatuses comprising a forming body comprising an upper trough-shaped portion comprising two trough walls and a trough bottom; a lower wedge-shaped portion; a delivery end comprising a first recess; and a compression end comprising a second recess; and first and second supports coupled to the first and second recesses, wherein at least a portion of the first or second support surfaces are non-planar and in continuous contact with at least a portion of the respective first or second recess surfaces. Also disclosed herein are methods for producing a glass ribbon using such apparatuses.

A thin glass substrate, as well as a method and an apparatus are provided. The glass substrate has a glass having first and second main surfaces and elongated elevations on one of the main surfaces. The elevations rise in a normal direction, have a longitudinal extent that is greater than two times a transverse extent, and have a height, on average, that is less than 100 nm, and with a transverse extent of the elevation smaller than 40 mm. The method includes melting a glass, hot forming the glass, and adjusting a viscosity of the glass so that for the viscosity η1 for a first stretch over a first distance of up to 1.5 m downstream of a flow rate control component and y1 indicating a second distance to a location immediately downstream the flow rate control component the equation lg η1(y1)/dPa.Math.s=(lg η01/dPa.Math.s+a1(y1)) applies.

An apparatus for downwardly drawing a glass ribbon includes a forming vessel including an upper portion including a pair of outside surfaces and a forming wedge portion including a pair of downwardly inclined forming surfaces converging along a downstream direction to form a bottom edge. An edge director is provided that includes a flow blocking portion. In some embodiments, the edge director also includes a flow directing portion.

An apparatus and method for manufacturing a glass sheet are disclosed. The apparatus includes a glass delivery device, a puddle forming device positioned to contact and redirect at least a portion of a stream of molten glass as it falls from the glass delivery device, and a side roller configured to contact the stream falling from the glass delivery device and redirected from the puddle forming device at a target position and lose contact with the stream at a departure position to form a ribbon of glass. The puddle forming device and the side roller can be relatively positioned to form a puddle of molten glass on a surface of the side roller positioned upstream from the target position and a thickness control gap between the puddle forming device and the side roller.

Methods and apparatus provide for sourcing a glass web, the glass web having a length and a width transverse to the length; continuously moving the glass web from the source to a destination in a transport direction along the length of the glass web; and cutting the glass web at a cutting zone into at least first and second glass ribbons as the glass web is moved from the source to the destination, the first glass ribbon having a first width and the second glass ribbon having a second width, where the first and second widths are not equal.

A method for determining a shape of a substantially cylindrical specular reflective surface includes the step of obtaining calibration data and the step of obtaining target data about a target structure. The method further includes the step of defining a target line from the target data, where the target line represents a feature of the target structure and the step of capturing a reflected image of the target structure in the specular reflective surface. The method further includes the step of obtaining reflected data from the reflected image and the step of defining a reflected line from the reflected data, where the reflected line represents a reflection of the feature of the target structure. The method also includes the step of determining a correspondence between the target line and the reflected line and using the correspondence and the calibration data to determine the shape of the specular reflective surface.

A technical object of the present invention is to devise a supporting glass substrate suitable for supporting a substrate to be processed to be subjected to high-density wiring and a method of manufacturing the supporting glass substrate, to thereby contribute to an increase in density of a semiconductor package. The supporting glass substrate of the present invention has a thermal shrinkage ratio of 20 ppm or less when a temperature of the supporting glass substrate is increased from room temperature to 400° C. at a rate of 5° C./minute, kept at 400° C. for 5 hours, and decrease to room temperature at a rate of 5° C./minute.

Methods of producing a glass sheet each comprise the step of creating a vacuum to force the entire lateral portion of the glass ribbon to engage an anvil portion of a breaking device in the elastic zone. The vacuum is provided by a plurality of pressure zones that are operated independent from one another, wherein each pressure zone is provided with a set of suction cups. In further examples, glass ribbon breaking devices each include a plurality of pressure zones that are configured to be operated independent from one another with each pressure zone being provided with set of suction cups.

A technical object of the present invention is to devise a glass sheet that facilitates position alignment with a substrate to be processed and is less liable to be broken during conveyance, or processing treatment of the substrate to be processed, to thereby contribute to an increase in density of a semiconductor package. In order to achieve the technical object, the glass sheet of the present invention includes, in a contour thereof: a contour portion; and a position alignment portion, in which all or part of an end edge region of the position alignment portion where a surface thereof and an end surface thereof intersect is chamfered.

A laminate sheet article including: a core including an electrical semi-conductor or an electrical conductor; and a continuous glass clad layer on at least four of six sides the core of the sheet article. Also disclosed is an apparatus for making a sheet laminate article as defined herein. Also disclosed is a method of making and using the article.