A handling equipment for a placement shelf of display panel is provided. The handling equipment includes a rack, a rotatable driving wheel and a cleansing device. The cleansing device is configured to cleanse the driving wheel. The driving wheel and the cleansing device both are disposed on the rack. The cleansing device contacts with the driving wheel. The driving wheel is configured to contact a bottom frame of the placement shelf of display panel. The driving wheel is disposed with a cleaning layer on the radial periphery of the driving wheel.

Swirl flow-forming body includes main body, first end face that is formed at main body and faces a member to which suction is applied, hole that opens on first end face, jetting port that is formed on inner periphery of main body, inner periphery facing hole, and fluid passage that allows fluid to be discharged into hole via jetting port so as to form a swirl flow that generates negative pressure for applying suction to the member. Inner periphery is formed so as to guide fluid discharged via jetting port, in a direction away from the member, to be discharged from hole.

An avoidance conveying device and an avoidance conveying method are provided. The device includes a receiving device, a front lifting device, a transition device, a rear lifting device, and a sending device arranged in sequence along a direction of conveying glass sheets; the receiving device receives the glass sheets conveyed by a front roller conveyor of an original sheet production line; the sending device conveys the glass sheets to a rear roller conveyor of the original sheet production line; an avoidance channel is formed between the front lifting device and the rear lifting device. Pedestrians and forklifts directly pass through the glass production line at any time through the avoidance channel, shortening the travel distance and the travel duration of pedestrians and forklifts. The glass sheets are finally conveyed to the rear roller conveyor by bypassing the avoidance channel, which ensures continuous and uninterrupted transportation of the glass sheets.

A glass plate bend-breaking machine includes a flexible endless belt on which a glass plate is placed; a supporting mechanism for supporting the glass plate through the endless belt; a glass plate receiving device disposed below the endless belt and having a glass plate receiving surface for receiving the glass plate through the endless belt and a recess surrounded by the glass plate receiving surface; a moving device for moving the glass plate receiving surface of the glass plate receiving device; a press-breaking device disposed above the endless belt and having a pressing surface for press-breaking the glass plate; and a moving device for moving the pressing surface of the press-breaking device.

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.

The present disclosure generally relates to a method and apparatus for loading, processing, and unloading substrates. A processing system comprises a load/unload system coupled to a photolithography system. The load/unload system comprises a first set of tracks having a first height and a first width, and a second set of tracks having a second height and a second width different than the first height and first width. An unprocessed substrate is transferred from a lift pin loader to a chuck along the first set of tracks on a first tray while a processed substrate is transferred from the chuck to the lift pin loader along the second set of tracks on a second tray. While a first tray remains with a substrate on the chuck during processing, the load/unload system is configured to unload a processed substrate and load an unprocessed substrate on a second tray.

The present invention relates to a method and an apparatus for determining the position of a substrate within a closed chamber, wherein the substrate is moved within the chamber by a transport system comprising at least one rotating shaft. A load-converting element is provided adjacent to at least one of the rotating shafts, wherein the load-converting element detects a load acting on the at least one rotating shaft and converts it into an electrical parameter. While no substrate is present on the at least one rotating shaft, a first output signal corresponding to a first value of the electrical parameter is measured. The output signal is then monitored and a presence of the substrate on the at least one rotating shaft is detected when the output signal differs from the first output signal by at least a predetermined amount.

A glass sheet acquisition and positioning system and associated method are utilized in a glass sheet optical inspection system installed in-line in a glass sheet processing system. The acquisition and positioning system include an exterior support frame and a moveable glass sheet support frame connected to the exterior support frame such that the glass sheet support frame may be selectively positioned from first orientation whereby a glass sheet is removed from a conveyor and retained on the support frame, to a second orientation whereby the glass sheet is positioned for processing by the optical inspection system. The system may also include a glass sheet part identifier and a programmable control including logic for analyzing acquired image data and identifying the glass sheet as one of a set of known part types and thereafter securing and positioning the glass sheet on the glass sheet support frame based upon the part-shape analysis.

A method and a support for holding a substrate, wherein the support is included in a transportation system configured to transport the substrate. The method includes attaching an adhesive to the support, wherein the material of the adhesive is a synthetic setae material and wherein the adhesive is configured to attach the substrate to the support; and attaching the adhesive to the substrate. Moreover, the thickness of the substrate is about 0.3 mm or less, and/or wherein the substrate has a size of 1.4 m.sup.2 or more. The support includes a support body and an adhesive, wherein the material of the adhesive is a synthetic setae material and wherein the adhesive is configured to attach the support body to the substrate, wherein the support is included in a transportation system configured to transport the substrate.

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.