An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus for holding glassware during processing includes a plurality of ware keepers, each ware keeper configured to receive a piece of glassware during the processing. Each ware keeper comprises a glass contact surface comprising a silicate material having a Knoop hardness less than or equal to 400 HK.sub.200 and a specific gravity greater than or equal to 1.5 and less than or equal to 6.

A glass tube element having hollow cylindrical section that has a shell enclosing a lumen and extends along a main extension and an optical delay of a light ray. The shell has a surface facing away from the lumen. The optical delay has values that all fall within a range having a size of between 3 and 30 nm. The optical delay being an optical measurement of the glass tube element by the light ray extending along a measurement path in a direction of perpendicular to the main extension and tangent to a surface of the shell. The measurement path touches the surface for different measurements at different positions each having a different azimuth angle within a cylindrical coordinate system fixedly attached to the glass tube element and having an origin on a center axis of the glass tube element.

A tempering furnace for tempering a glass object may include a housing, a heating device for heating the glass object, and a cooling device for cooling the glass object. Additionally, the tempering furnace may further include a turning device provided for turning the glass object inside the housing. The turning device is configured to counteract an effect of gravitational forces on the glass object when the glass object is heated to its softening phase.

The invention relates to a method for measuring the wall thickness of hollow glass articles (2) in a hollow glass production system, wherein the IR radiation emitted by each hollow glass article (2) exiting the hot end of a glass forming machine is detected at least in areas mapped by a function (10), the same hollow glass article (2), after having passed through an annealing lehr, being measured in the circumferential direction with respect to a wall thickness distribution, and the detected wall thickness distribution being mapped by a function (18). Using correlation methods, it is checked whether the progression of the function (10) is contained in the function (18), wherein if so, measured values of the wall thickness can be associated with the measured values of the IR radiation at the hot end, so that the wall thickness distribution of the hollow glass article is already known at the hot end and implementable for monitoring purposes.

The present disclosure provides a tube catcher for a hot forming machine comprising a foot for mounting the tube catcher in the hot forming machine, an upper contact surface for catching a glass tube as it falls into the hot forming machine, and a damping element, which is arranged below the upper contact surface in such a way that it allows the upper contact surface to elastically recede in the direction of the falling direction of the glass tube. This minimizes damage to glass tubes on impact and permits a high production speed. For this purpose, the damping element includes a compressible chamber that can be filled with a gas.

The present disclosure provides a tube catcher for a hot forming machine comprising a foot for mounting the tube catcher in the hot forming machine, an upper contact surface for catching a glass tube as it falls into the hot forming machine, and a damping element, which is arranged below the upper contact surface in such a way that it allows the upper contact surface to elastically recede in the direction of the falling direction of the glass tube. This minimizes damage to glass tubes on impact and permits a high production speed. For this purpose, the damping element includes a compressible chamber that can be filled with a gas.