The described technology generally relates to a method of manufacturing a display device and a manufacturing apparatus for the same. In one aspect, the method includes placing a carrier, in which a display panel is formed, into a film attachment portion such that the carrier is pulled onto a carrier adsorption surface of a first stage. The method also includes attaching a first protection film onto a first surface of the display panel in the film attachment portion, wherein the first surface is located opposite to a second surface of the display panel that faces the carrier. The method also includes first transferring the first stage to a carrier separation portion, separating the display panel from the carrier, and second transferring the display panel to a second stage such that the attached protection film is pulled onto a second film adsorption surface of the second stage.

A cell cutting device and a cell cutting method are disclosed. The cell cutting device includes a loading stage configured to load a display sheet including a plurality of display cells, a rotation driving unit connected to the loading stage and configured to rotate the loading stage and to separate the display sheet into the plurality of display cells, and a position change unit connected to the loading stage and configured to change a position of the loading stage.

A device for lifting and transporting sheet material includes a base portion; wheels on which the base portion is supported; a mast that extends upwardly from the base portion; a boom that extends from a first end outwardly from the mast to a second end; a supporting head that is configured to support sheet material; and a pivot coupling at the second end of the boom. The pivot coupling is arranged to couple the supporting head to the boom, and enable the supporting head to be rotated about a pivot axis between a first position in which sheet material supported by the supporting head is in a generally transverse orientation relative to the boom, and a second position in which the angle between sheet material supported by the supporting head and the boom is reduced.

A method of cutting a glass article includes translating a laser beam relative to a first surface of the glass article. The laser beam includes a beam waist having a center. The center of the beam waist of the laser beam is positioned at or below a second surface of the glass article. The laser beam creates a plurality of defects along a score line in the glass article such that the plurality of defects extends a distance into the glass article, and at least some individual defects of the plurality of defects are non-orthogonal to the first surface of the glass article and are biased in a direction of translation of the laser beam. Glass articles having edge defects are also disclosed.

A device for unloading insulating glass from a production line has a support frame and a manipulator frame arranged on the support frame and having a manipulator plane provided with a matrix of suction cups adapted to achieve adhesion of the insulating glass to the manipulator plane, and brackets for supporting the insulating glass. Each bracket is movable between a retracted position, where the bracket does not protrude or has minimal protrusion from the manipulator plane, and an extracted position, where the bracket has maximum protrusion from the manipulator plane. A movable abutment moves in a direction substantially parallel to the brackets and interacts with the brackets by a first contact portion of an operating surface to push the brackets towards the retracted position so that the brackets assume a given protrusion with respect to the manipulator plane between the retracted and extracted positions.

To provide a levitation air plate that can be easily manufactured and can float a substance being conveyed such as a glass while maintaining its high rigidity and controlling a floating amount in high accuracy. A levitation air plate 1 provided with: a top plate 2 in which a plurality of air ejection holes 2c and suction holes 2d penetrating from an upper surface 2a to a lower surface 2b are arranged in alternating fashion as viewed from the upper surface, the top plate 2 having a counter-bored portion 2e on the lower surface side of each of the plurality of air ejection holes; an orifice sheet 3 having a plurality of orifices 3c penetrating from an upper surface 3a to a lower surface 3b in positions corresponding to the counter-bored portions of the top plate, and having communicating holes 3d communicated one-to-one with the suction holes of the top plate and penetrating from the upper surface to the lower surface; and bottom side plates 4, 5 having an air supply channel 4c and an air supply hole 5c for supplying air to all of the orifices drilled in the orifice sheet, and an air suction channel 4d and a suction hole 5d for suctioning air from all of the communicating holes communicated with the suction holes.

When handling panel-shaped objects, such as glass panes, a gripping device (4) is used in order to remove the objects from stacks (1, 2), in which the objects are inclined towards the vertical, or to position the objects onto stacks (1, 2), wherein the gripping device allows at least two stacks (1, 2) of objects to be formed on bearing blocks, the stacks (1, 2) differing from each other. The gripping device (4) has at least two grippers which are independent of each other. Suction heads (7) are provided as the grippers of the gripping device (4), the suction heads being pivotal independently of each other into and out of the suction head working position associated with the objects. In the process, gripping device (4) suction heads (7) pivoted out of their operating position are arranged above the stacks (1, 2).

The invention relates to a system and a method for the multi-step processing of planar substrates, more particularly planar glass substrates, on a substrate carrier, wherein a plurality of mutually spatially separated processing stations are interconnected by means of a substrate-carrier conveying device, and wherein a substrate carrier is conveyed from one processing station to the next processing station by means of the substrate-carrier conveying device in order to subject a planar substrate laid on a substrate carrier to a plurality of processing steps in succession.

A floating unit carries and transport is a substantially flat body, with a carrier plate which has a first multiplicity of pressure nozzles and a first multiplicity of vacuum nozzles on a first surface, wherein a first multiplicity of channels which extend both from the pressure nozzles of the first multiplicity of pressure nozzles and from the vacuum nozzles of the first multiplicity of vacuum nozzles is provided in the first surface.

Embodiments of the present disclosure generally relate to optical devices. More specifically, embodiments described herein relate to apparatuses and methods for gripping optical devices. In an embodiment, an apparatus for gripping an optical device includes a base coupled to a proximal end of a stem extending from a bottom surface of the base. The apparatus also includes a plurality of arms movably coupled to the bottom surface of the base. The plurality of arms are coupled to an actuator operable to move the plurality of arms laterally along a X-Y plane parallel to the bottom surface of the base. In some embodiments, the apparatus includes a suction pad operable to provide a non-contact vertical suction force.