A wafer storage system includes a main rail, an overhead hoist transport (OHT) on the main rail, the OHT being configured to transfer at least one storage case with wafers, an interface port on at least one side of the main rail, an auxiliary rail on one side of the interface port, the auxiliary rail being parallel to the main rail, and the interface port being between the main rail and the auxiliary rail, an auxiliary transport on the auxiliary rail, the auxiliary transport being configured to move along the auxiliary rail and to move the at least one storage case, a storage shelf on at least one side of the auxiliary transport, the storage shelf being configured to store the at least one storage case, and a worktable on one side of the storage shelf, the storage shelf being between the worktable and the auxiliary transport.

A method is provided for measuring optical characteristics of a glass sheet as the glass sheet is conveyed in a system for fabricating glass sheets including one or more processing stations and one or more conveyors for conveying the glass sheet during processing. The method comprises providing a background screen including contrasting elements arranged in a pre-defined pattern and a camera for acquiring an image of the background screen; acquiring data associated with a shape of a glass sheet travelling on a conveyor upstream from the background screen; removing the glass sheet from the conveyor; and positioning the glass sheet between the camera and the screen and thereafter acquiring an image of the background screen; re-positioning the glass sheet for continued movement of the glass sheet on the conveyor; and performing one or more processing operations using the acquired image data to analyze the optical characteristics of the glass sheet.

A substrate support system 10 for a conveyor printer is provided, comprising a support unit 100 comprising a plurality of vacuum apertures 108 arranged for fluidic communication with a source of negative pressure. The support unit 100 also comprises at least one air bearing 114 arranged for fluidic communication with a source of positive pressure. The air bearing 114 comprises porous media 116. The substrate support system 10 also comprises a conveyor belt 150 arranged over the support unit 100 for supporting a substrate 170 to be printed on. The conveyor belt 150 comprises a plurality of belt apertures. The vacuum apertures 108 are arranged to convey a negative pressure through the belt apertures for retaining the substrate 170 on the conveyor belt 150. The at least one air bearing 114 is arranged to convey a positive pressure to support the conveyor belt 150.

A glass sheet processing apparatus includes a first gantry assembly that extends across a glass sheet in a cross-machine direction. The first gantry assembly includes a processing head that moves along a length of the first gantry assembly and includes a laser comprising an optical arrangement positioned in a beam path of the laser providing a laser beam focal line that is formed on a beam output side of the optical arrangement. A second gantry assembly extends across the glass sheet in the cross-machine direction. The second gantry assembly includes a processing head that moves along a length of the second gantry assembly.

A substrate processing apparatus includes: a carrier block including carrier placement parts and configured to load/unload a substrate into/from a carrier; a processing block provided on one side of the carrier block to process the substrate; first and second carrier placement parts of the carrier placement parts and provided side by side in a front-rear direction in a plan view; substrate placement parts provided to be arranged step by step vertically on one side of a substrate transfer region formed between the first and second carrier placement parts; a first substrate transfer mechanism provided in the substrate transfer region to deliver the substrate between the carrier of the first carrier placement part and a first substrate placement part of the substrate placement parts; and a second substrate transfer mechanism for moving upward and downward so as to deliver the substrate between first and second substrate placement parts.

The present disclosure relates to a method for manufacturing a bent component. The present disclosure moreover relates to a shaping tool for manufacturing a bent component. The shaping tool comprises a first tool half, a second tool half and at least one movable cylinder pin. The first tool half of the shaping tool is arranged opposite the second half of the shaping tool. An outer end of the at least one cylinder pin herein points in the direction of the second half of the shaping tool. A holding element for receiving a flat bendable element is assembled on this outer end of the at least one cylinder pin.

A loading/unloading assembly of flat ceramic products comprising: a conveying unit for conveying a plurality of flat ceramic products; at least one loading/unloading device for flat ceramic products for receiving a support structure so that it rests on it and at least one pick-up device for picking up and transferring at least one flat ceramic product from the conveying unit to the support structure, and/or vice versa; the loading/unloading device comprises at least one bearing device for bearing at least said support structure and a plurality of flat ceramic products stacked on top of one another, and a moving device for moving said support structure, between a first position at a first height from said bottom, and at least a second position at a second height from said bottom, the second height is greater than the first height.

A loading/unloading assembly of flat ceramic products comprising: a conveying unit for conveying a plurality of flat ceramic products; at least one loading/unloading device for flat ceramic products for receiving a support structure so that it rests on it and at least one pick-up device for picking up and transferring at least one flat ceramic product from the conveying unit to the support structure, and/or vice versa; the loading/unloading device comprises at least one bearing device for bearing at least said support structure and a plurality of flat ceramic products stacked on top of one another, and a moving device for moving said support structure, between a first position at a first height from said bottom, and at least a second position at a second height from said bottom, the second height is greater than the first height.

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 bars 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.

In a laser irradiation apparatus 1 according to one embodiment, each of first and second flotation units 30a, 30b includes a base 31, and a porous plate 32 bonded to an upper surface of the base 31 by an adhesive layer 34, the base 31 includes a rising portion 312 protruding upward at an outer periphery facing at least the gap, and the porous plate 32 includes a cutout portion 321 configured to fit to the rising portion 312, and the adhesive layer 34 is formed along an inner wall of the rising portion 312 having fitted to the cutout portion 321.