Provided is a substrate inverting device that can reverse the front and back of a substrate without causing damage and that can suppress a decrease in work efficiency due to inverting the substrate. A substrate inverting device that inverts the front and back of a substrate comprise: a rectangular frame shaped casing that encloses the circumference of a substrate to be inverted; a first holding unit that is joined to one edge of the casing so as to be able to rotate and that holds the substrate from the front side; a second holding unit that is joined to another edge of the casing facing the one edge so as to be able to rotate and that holds the substrate from the back side; and a support unit that supports the casing so that same can rotate about an axis in the horizontal direction while the substrate is held by the first holding unit and second holding unit.

A method for forming a glass sheet includes forming a glass ribbon. A robot arm is operated to move an end effector through a preprogrammed cycle. The cycle includes engaging a segment of the glass ribbon with the end effector, separating the engaged segment from the glass ribbon to generate a glass sheet, and moving the glass sheet away from the glass ribbon. The preprogrammed cycle designates predetermined positions of the end effector at predetermined points in time. While the robot arm is operating through the preprogrammed cycle, a parameter indicative of a force being exerted on the glass ribbon by the end effector is sensed. A position of the end effector is altered to differ from the predetermined position at the corresponding point in time when the sensed parameter deviates from a target value. An excessive force applied to the glass ribbon can be reduced in real-time.

The invention provides systems and methods for robotically stacking sheets. The systems and methods involve a robot arm and a conveyor line. The robot arm has attached thereto a suction frame. In some embodiments, the systems and methods involve first and second robot arms. In such embodiments, the system and method facilitate and involve a sequentially alternating unloading operation such that the system has a first position in which the first robot arm is elevated and has the first suction frame loaded with one or more sheets while the second robot arm is lowered and has the second suction frame unloaded and the system has a second position in which the second robot arm is elevated and has the second suction frame loaded with one or more sheets while the first robot arm is lowered and has the first suction frame unloaded.

The disclosed system for loading and unloading the substrate includes: a substrate rotation apparatus having a first rotation position and a second rotation position with a difference in rotation angle of 90 degrees, wherein the substrate rotation apparatus includes two layers of sucker assemblies, each of which includes a plate body, a plurality of support suction tubes arranged on the plate body, and first suckers connected with tops of respective support suction tubes respectively, and there are gaps, for inserting the substrate therein, between respective first suckers of a lower layer of sucker assembly, and a plate body of an upper layer of sucker assembly; and a mechanical hand including a plurality of mechanical fingers capable of holding two halves of the substrate, both of which are arranged in a length direction of the mechanical fingers, and joined together into an entire substrate.

Disclosed are a substrate alignment apparatus, a substrate processing apparatus, and a substrate processing method using the substrate alignment apparatus. The substrate alignment apparatus and the substrate processing apparatus include a support plate and a plurality of guide units coupled to the support plate to align a position of the substrate. Each of the guide units includes an alignment pin for aligning the substrate in place and a stationary body having a support surface for supporting an edge region of the substrate aligned, the stationary part being fixedly coupled to the support plate. The alignment pin is rotatable about a central axis of the alignment pin relative to the support surface of the stationary part, thereby rapidly aligning the substrate and thus preventing the substrate transferred between a plurality of process chambers by a transfer robot from being separated or having a negative influence on other apparatuses.

A pick-and-place device of display screen substrate and a control method for picking and placing a display screen substrate are disclosed. The pick-and-place device of display screen substrate includes a housing, a support assembly and a control component. The support assembly is disposed in the housing and includes: a support plate extending in a first direction, and two sets of support bars disposed opposite to each other and spaced apart from each other in the first direction. Each set of support bars includes a plurality of support bars arranged at intervals along a second direction, and each support bar is movable in a third direction. The support plate and the support bar are connected with the housing respectively, and the support plate is provided with an opening configured to allow the support bar to move along the third direction.

A glass sheet processing system for processing a glass sheet includes a conveyor for conveying the glass sheet in a direction of conveyance, and a positioning apparatus for adjusting position of the glass sheet on the conveyor. The positioning apparatus includes a movable carriage having first and second carriage bodies. The first carriage body is translatable in the direction of conveyance, and the second carriage body is supported by the first carriage body such that the second carriage body is movable in a direction generally transverse to the direction of conveyance. The positioning apparatus further includes a first drive assembly for moving the first carriage body in the direction of conveyance, a second drive assembly for moving the second carriage body with respect to the first carriage body, and a positioner member connected to the second carriage body for contacting the glass sheet to adjust position of the glass sheet.

The invention relates to a device and to a method for safely and quickly transferring new glass sheets from the production line to a transport vehicle, having the following features; a) a glass-sheet roller conveyor (8) having a glass-rack gripping and stacking device (7) for receiving glass sheets (9) from a production line, b) two parallel running rails (12) extending centrically at a right angle toward the glass-sheet roller conveyor (8), an underfloor energy supply rail (24) being arranged in the region between the running rails (12), c) at least one glass-rack carriage (3), which moves on the running rails (12) and which has at least one glass rack (4, 6) lying on said glass-rack carriage, a glass rack (4, 6) being able to be loaded with obliquely positioned glass sheets (9) and the glass racks (4, 6) being fixed in the oblique position by means of a pivoting device (14), and d) a rotary device (2) arranged in the course of the running rails for rotating a glass-rack carriage (3) by 180 degrees for loading one glass-rack carriage (3) at a time.

The present disclosure illustrates an inspection apparatus for a display panel and a testing method for display panel. The inspection apparatus includes a platform, a feeding device, a rotatable bearing stage, an optical panel inspection device, a discharging device, a rotation driving device and a transfer device. The platform includes a support frame having a loading-and-unloading area and an inspection area. The feeding device transports the display panel along a feeding direction. The rotation driving device includes a rotation axe and a rotation driving mechanism. The rotation axe has an end fixed at a central part of a bottom surface of the rotatable bearing stage, and the rotation driving mechanism can rotate the rotation axe. The display panel placed on the rotatable bearing stage can be exchanged between the loading-and-unloading area and the inspection area when the rotatable bearing stage is rotated.

A system for handling sheets of flexible material. The system comprises a first roller (5.2) which comprises a plurality of first releasable connectors (3.2) and a second roller (5.3) which comprises a plurality of second releasable connectors. The system further comprises an array of third releasable connectors (2.1) which is displaceable between at least the first and second rollers (5.2, 5.3). The first, second and third releasable connectors releasably attach to a sheet of flexible material in use.