Provided is a method that can manufacture a glass plate having a curved surface shape with high surface accuracy even without polishing the surface after forming and a glass plate manufactured by the method. The method of manufacturing a glass plate having a curved surface shape includes the steps of: preparing an original glass plate, a forming die (10) including a recess (11) corresponding to the curved surface shape, and a forming tool (20) operable to press the original glass plate (2); placing the original glass plate (2) on the recess (11) in the forming die (10); heating the original glass plate (2) and the forming die (10); maintaining a temperature of a surface of the recess (11) in the forming die at a temperature lower than a temperature of the original glass plate (2); and giving the original glass plate (2) the curved surface shape by pressing the heated original glass plate (2) with the forming tool (20) to deform the original glass plate (2) while bringing the original glass plate (2) into contact with the surface of the recess (11).

The present disclosure relates to a method for manufacturing a hollow glass item and, specifically, to a method for manufacturing an item made of hollow pressed glass. The method includes a step of depositing at least one drop of molten glass into a mold intended for modelling a predetermined outer shape of the glass item to be manufactured; a step of pressing the molten glass into the mold by a shaping punch in order to shape the hollow glass item by hollowing out an inside space; a step of marking the glass item with a marking tool which is independent from the shaping punch, in order to imprint at least one raised and/or recessed pattern in the inside space of the glass item; a step of cooling the marked, pressed glass item; and a step of removing the glass item from the mold.

A multi-layer glass enamel is disclosed. The various layers of the enamel are included to provide certain performance characteristics to the enamel. The components of each layer can be individually adjusted to tailor the performance characteristics influenced by that layer without changing the influence of the remaining layers.

In some examples, a feedthrough assembly for a medical device may include a ferrule. The ferrule defines an aperture extending through the ferrule from an outer end surface defined by the ferrule to an end inner end surface defined by the ferrule. The aperture includes a first portion having a first diameter and a second portion having a second diameter less than the first diameter. The aperture defines a longitudinal axis extending therethrough and the ferrule defines a ledge between the first and second portions of the aperture that extends radially inward toward the longitudinal axis. The feedthrough assembly further may include a conductive pin within the aperture and an insulating member surrounding at least a portion of the pin. The insulating member may electrically insulate the conductive pin from the ferrule, and the ledge and a surface of the insulating member adjacent the ledge may define a space therebetween.

A method for producing long-term bendable glass material includes: bending a glass material in a bending radius in a range of 1 mm to 10.sup.7 mm; storing the bent glass material for a time period of at least 1 day; inspecting at least a portion of the bent glass material for damage after the storing; and classifying the inspected bent glass material as a reject if damage is detected or as a long-term bendable glass material if no damage is detected.

A method for producing, without a mold, a shaped glass article having a predefined geometry is provided. The method includes providing a starting glass, supporting the starting glass, heating a portion of the starting glass so that in the portion a predetermined spatial viscosity distribution of the starting glass is obtained from 10.sup.9 to 10.sup.4 dPa.Math.s and so that at points where the starting glass is supported a predetermined spatial viscosity distribution of the starting glass does not fall below 10.sup.13 dPa.Math.s, and deforming the heated starting glass by action of an external force until the predefined geometry of the glass article is obtained.

A method of preparing a glass medical container is provided including the steps of providing a glass blank and forming a channel through a part of the glass blank, the channel being substantially free of tungsten or derivatives thereof. In a further aspect of the subject invention, a glass medical container is provided including a glass body having a channel extending through a part of the glass body, the channel being substantially free of tungsten or derivatives thereof. With the subject invention, tungsten or derivatives thereof can be generally or altogether completely avoided in glass medical containers.

A device for the gravity-bending of a glass sheet, includes a longitudinal roughing mold including two longitudinal roughing supports, and a finishing frame including two lateral finishing supports and two longitudinal finishing supports, the supports forming shaping rails. The distance between middles of the longitudinal finishing supports is shorter than that between middles of the lateral finishing supports. The roughing mold and finishing frame are movable vertically relative to each other during bending to switch from a rough-bending to a final-bending configuration. In the rough-bending configuration, the shaping rails of the longitudinal roughing supports are higher up than those of the longitudinal finishing support. In the final-bending configuration, the shaping rails of the longitudinal finishing supports are higher up than those of the longitudinal roughing supports. The shaping rails of the lateral finishing supports are the only ones under lateral edges of the glass in the roughing and final-bending configurations.

A method for shaping an optical component so that it has an aspherical optical surface. In the method: the optical component is heated and mechanical stresses are applied thereto; heating and applying the mechanical stresses are stopped; an optical surface of the component is polished into a planar or spherical shape; and viscous elastic deformation of the optical component is relaxed. The method for example has applications in manufacturing aspheric mirrors having great dimensions.

A method for manufacturing a mirror blank comprises: providing a primary piece of glass comprising a primary planar surface and a backing piece of glass comprising a backing planar surface; assembling a mirror blank assembly, wherein assembling the mirror blank assembly comprises interposing a plurality of glass splines between the primary glass and the backing glass. Interposing the plurality of glass splines comprises: for each glass spline, respectively abutting first and second opposed surfaces of the glass spline against the primary planar surface of the primary glass and against the backing planar surface of the backing glass. The mirror blank assembly is then heated to fuse the interposed glass splines to the primary glass and the backing glass while the primary glass and the secondary glass remain spaced apart from one another by the interposed glass splines to thereby provide the mirror blank.