The present disclosure provides a holding arrangement. The holding arrangement for holding a substrate includes: a body portion having a first side; a dry adhesive material provided on the first side of the body portion; a seal surrounding the dry adhesive material and configured to provide a vacuum region on the first side, wherein the dry adhesive material is provided in the vacuum region; and a conduit to evacuate the vacuum region.

A vacuum gripper device including at least one suction cup including a fastener body from which there extends an elastically deformable skirt having a free annular edge for coming into contact with an object to be grasped. The suction cup includes at least one electrically conductive track secured at least to the skirt. The conductive track is made of a material that is electrically conductive and elastically deformable so as to deform together with the skirt. The device includes an electronic processor circuit that is connected electrically to two connection pads belonging to the conductive track and that is arranged to monitor an electrical property of the conductive track, which electrical property varies with the deformation of the conductive track, and to compare that property with reference data so as to anticipate a failure of the suction cup.

A system comprises a floatation table comprising a plurality of ports to flow gas sufficient to produce a gas bearing to float a substrate over the floatation table; a fluidic network coupled to supply gas to the plurality of ports of the floatation table; and a controller configured to control the fluidic network to independently control flows of gas through ports of the plurality of ports disposed in each of a first zone, a second zone, and a third zone of the floatation table. The first, second, and third zones are defined by sections of the floatation table extending parallel to a direction the substrate is conveyed along the floatation table. The first zone is defined by a central section of the floatation table disposed between two sections defining the second zone, and the first and second zones are disposed between two sections defining the third zone.

A display panel vacuum suction system includes a control device, a robot arm, and a vacuum device. The robot arm includes two or more retractable rods, and each of the retractable rods is connected with a vacuum plate. Each vacuum chamber is disposed in each of the vacuum plates, and each vacuum hole is disposed on a surface of each of the vacuum plates, wherein each vacuum chamber is connected with the vacuum device by a suction pipe. The control device controls expansion and retraction of the retractable rods of the robot arm, so that the vacuum plates connected with the retractable rods can be combined to pick up a single display panel or pick up two display panels respectively. By combining vacuum plates, and controlling the opening or closing of the vacuum holes of each of the vacuum plates, different sizes of display panels can be sucked.

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.

A fuel cell separator conveying device that ensures reducing dirt adhesion on a sealing surface of a stacked fuel cell separator using a protection sheet and reducing the protection sheet being left adhered when the fuel cell separator is conveyed is provided. The fuel cell separator conveying device that lifts up and conveys the fuel cell separator placed on the protection sheet includes a grasping portion that grasps the fuel cell separator by a suction force, a moving unit that moves the grasping portion in a lift-up direction of the fuel cell separator, and an air blowing portion that applies a downward force in an opposite direction of the lift-up direction of the fuel cell separator to the protection sheet through an opening of the fuel cell separator when the moving unit moves the grasping portion.

An end manipulator for picking packages is provided. An example end manipulator includes a vacuum plate coupled to a machine where the vacuum plate includes a first set of vacuum cups. Further, the end manipulator includes a grasper plate movably coupled to the machine. The grasper plate moves between a retracted position and an extended position. In the retracted position, the grasper plate aligns with the vacuum plate such that the grasper plate abuts the vacuum plate. In the extended position, the grasper plate extends out from the vacuum plate. In some examples, when the grasper plate is in the retracted position, the end manipulator is configured to pick and place a first type of package. Further, in some examples, when the grasper plate is in extended position, the end manipulator is configured to pick and place a second type of package.

Provided are a die pickup module and a die bonding apparatus including the same. The die pickup module includes a wafer stage for supporting a wafer including dies attached on a dicing tape, a die ejector arranged under the dicing tape and for separating a die to be picked up from the dicing tape, a non-contact picker for picking up the die in a non-contact manner so as not to contact a front surface of the die, a vertical driving unit for moving the non-contact picker in a vertical direction to pick up the die and an inverting driving unit for inverting the non-contact picker to invert a die picked up by the non-contact picker.

An adsorbing apparatus for a glass wafer includes an adsorbing head and a block structure mounted to the adsorbing head. The adsorbing head defines a cavity and an opening directly touching a glass wafer. The block structure defines a channel connected with the cavity. A plurality of supporting posts for supporting the glass wafer are densely arranged in the cavity. The adsorbing apparatus as a transfer tool for a glass wafer, which can transport unmolded wafer to the mold for molding, and can remove the glass wafer before fully executing cool down, thereby avoiding many adverse effects in the glass wafer forming process and shortening production time and improving production efficiency.

A method of manufacturing a glass sheet includes a start point forming step of forming a scribe line on a preset cutting portion of a glass sheet, a setting step of causing, through use of a support member having a groove-shaped recess, the support member to support the glass sheet having the scribe line formed thereon from one surface side so that the preset cutting portion is arranged on the recess, and a cutting step of generating a negative pressure in the recess to bend the preset cutting portion on the recess so that the one surface side protrudes, to thereby cut the glass sheet along the preset cutting portion with the scribe line as the start point. At the time of performing the cutting step, the entire recess is covered with a cover member from another surface side of the glass sheet through intermediation of the glass sheet.