A glass cutting line includes automatic remnant storage and retrieval including cutting table with integrated squaring stop and y-break breaking bar facilitating sub-plate cutting. The cutting table is configured for sub-plate cutting mode which provides the ability to cut portions of a stock sheet and release the cut portion in the form of a remnant and or individual workpieces to breakout before the entire sheet is finished scoring without the sub-plate leaving the cutting table.

Methods of processing a glass ribbon are provided. The method includes the step of traversing the glass ribbon through a travel path at a predetermined velocity and severing the glass ribbon to create an upstream web and a downstream web. The method further includes the step of increasing a relative velocity of a downstream edge portion with respect to an upstream edge portion to create a gap between an upstream severed edge and a downstream severed edge. In other example methods, a segment of the glass ribbon is removed to create a gap between an upstream severed edge and a downstream severed edge. In still further example methods, an upstream severed edge is directed along a second travel path to create a gap between the upstream severed edge and a downstream severed edge.

Equipment for the logistics of slab-shaped articles comprises supply line(s) of slab-shaped article(s) and outlet line(s) of the slab-shaped article(s); robotic gripping assembly(s) of the slab-shaped article(s) provided with at least three degrees of freedom and positioned between the supply line(s) and the outlet line(s); first movement device/unit/component/etc. of the gripping assembly(s) along a direction(s) of movement; where the supply line(s) and said outlet line(s) are substantially aligned to each other along the direction(s) of movement. Equipment also comprises temporary storage stations of the slab-shaped article(s) arranged laterally to the gripping assembly and substantially aligned to each other to define at least one row substantially parallel to the direction of movement, wherein the gripping assembly(s) picks the slab-shaped article(s) coining from the supply line(s); positions the slab-shaped article(s) on the storage station(s); and picks the slab-shaped article(s) from the storage station(s) and bring it to the outlet line(s).

A glass processing apparatus and a glass processing method are provided. The glass processing apparatus includes: a glass transportation apparatus comprising a carrier comprising a gripper configured to grip glass articles, and a conveyor configured to convey the carrier, and a cleaning apparatus comprising a cleaning head configured to clean the gripper, which contact the glass articles, and a moving unit configured to move the cleaning head. The glass processing method includes: loading glass articles to a carrier having a gripper by picking up the glass articles with the gripper such that the gripper contact the glass articles, conveying the glass articles by conveying the carrier with a conveyor, unloading the glass articles from the carrier by causing the gripper to be detached from the glass articles, and cleaning the gripper.

In a machine and in a method for processing lateral edges of glass plates, plates of stone material, and plates of synthetic material, there is a group of gripping members of the plate configured to hold a plate in a horizontal position. The plate is caused to advance in a conveying longitudinal direction, in such a way as to bring a lateral edge of the plate to engage in succession an aligned series of grinding tools forming part of a stationary machining unit. In one example, the group of gripping members of the plate is rotatably carried around a vertical axis by a carriage, which is movable in the conveying longitudinal direction and in a transverse direction orthogonal to the longitudinal direction. The gripping members are carried by the carriage in such a way as to be adjustable in position, by means of electronically-controlled actuator devices, with respect to the carriage and relative to each other.

Method and apparatus for the flush transfer of large-surface-area panels of different types of construction to a transporting vehicle, having the following features. At least one conveyor for supplying panels of at least one type of construction. At least one pivoting-stack apparatus, having a gripper frame and having adhesion elements fastened thereon. At least one stack framework on a mobile carriage, wherein the latter is connected to at least one transporting vehicle by a switchable coupling. The transporting vehicle is supplied with power, and controlled electronically and/or electrically, by a multiplicity of lines installed in the floor region. An electrically controlled parking brake on each transporting vehicle, for arresting purposes.

An automatic identification and classification production line for mobile terminal liquid crystal display (LCD) screens includes a size and posture identification adjustment part, a model identification part, and a classification storage device. The size and posture identification adjustment part can transport a mobile terminal LCD screen, identify front and back surfaces of the mobile terminal LCD screen, size of the mobile terminal LCD screen, and orientation of the mobile terminal LCD screen, and adjust the front surface of the mobile terminal LCD screen to face up and the orientation of the mobile terminal LCD screen to be the same as the transportation direction during transportation. The model identification part transports the mobile terminal LCD screen after adjustment of the posture, and identifies model of the mobile terminal LCD screen according to the size during transportation. The classification storage device classifies and stores mobile terminal LCD screens according to different models.

A method for the production of glass ribbon portions is provided that includes: transporting a glass ribbon at a velocity v.sub.1, wherein the velocity v.sub.1 is dependent on the predetermined glass thickness (d.sub.1), with the application of a tensile stress parallel to the edges of the glass ribbon, in a plane E.sub.1, and cooling the glass ribbon at a cooling rate that is dependent on the predetermined glass thickness (d.sub.1), inserting a score on the surface of the glass ribbon in at least one edge area by scoring the glass surface with a scoring tool, wherein the score has an angle a to the transport direction of the glass ribbon, deflecting the glass ribbon in a plane E.sub.2 to generate a bending stress and separating a glass ribbon portion with the formation of edges by breaking the glass ribbon on the extension of the score running transversely to the glass ribbon.

A magnetic levitation system for contactlessly holding and moving a carrier in a vacuum chamber, including a base defining a transportation track, a carrier movable above the base along the transportation track, and at least one magnetic bearing for generating a magnetic levitation force between the base and the carrier. The at least one magnetic bearing includes a first magnet unit arranged at the base and a second magnet unit arranged at the carrier. The magnetic levitation system further includes a magnetic side stabilization device for stabilizing the carrier in a lateral direction, the magnetic side stabilization device comprising a stabilization magnet unit arranged at the base, wherein at least one of the first magnet unit and the first stabilization magnet unit is arranged in a housing space of the base, the housing space being separated from an inner volume of the vacuum chamber by a separation wall.

Systems and methods for automated, sequential processing of a continuous glass ribbon by conveying the glass ribbon in a ribbon travel direction, forming a score line in the glass ribbon, separating a glass sheet from the glass ribbon at the score line while supporting the glass sheet with a transfer device, lowering the glass sheet onto a conveyor, and conveying the glass sheet in a sheet travel direction differing from the ribbon travel direction. By transferring and then conveying the glass sheet in a direction differing from the ribbon travel direction (e.g., a 90 degree turn) immediately after glass sheet separation, the systems and method of the present disclosure are conducive to streamlined production of glass sheets utilizing a unique production floor footprint.