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.

The present application relates to a movable buffer, an automated material handling system and a corresponding overhead hoist transfer. The movable buffer includes: an inclined track including a first end and a second end opposite to each other, wherein the second end of the inclined track is higher than the first end of the inclined track; a storage tray connected to the inclined track, wherein the storage tray is provided with a space for accommodating a front opening unified pod, the storage tray is provided with at least one opening; and a transmission mechanism, wherein the upper surface of the transmission mechanism is connected to the lower surface of the overhead buffer, the lower surface of the transmission mechanism is connected to the inclined track, and the transmission mechanism is used for driving the storage tray to slide from the first end of the inclined track to the second end.

A substrate transfer device includes a substrate holder and a base to which the substrate holder is movably attached. The substrate holder includes first and second suction holes provided to be open in a placing surface, first and second protrusions disposed respectively in the first and second suction holes, and first and second supports provided respectively in the vicinity of the first and second suction holes so as to protrude upward from the placing surface. The first protrusion is pressed by a first elastic member toward an upward direction to protrude from the first suction hole such that the first protrusion blocks the first suction hole, and the second protrusion is pressed by a second elastic member toward an upward direction to protrude from the second suction hole such that the second protrusion blocks the second suction hole.

Provided is an apparatus for transporting articles that can effectively treat numerous articles. The apparatus for transporting articles comprises: a frame; a first transport mounting portion connected to the frame and configured to support a first-class article from below; a second transport mounting portion connected to the frame, disposed over the first transport mounting portion and configured to support the first-class article from below; a third transport mounting portion connected to the frame, disposed over the second transport mounting portion and configured to support a second-class article different from the first-class article from below. The first transport mounting portion operates independently of the second and third transport mounting portions, and the second transport mounting portion and the third transport mounting portion operate simultaneously.

Provided is a substrate transferring method which is capable of accurately mounting a substrate at a desired rotation angle. In order to eliminate a misalignment of a wafer W in a rotational direction in a vacuum process chamber, which is caused by a variation in a transfer distance of the wafer W, the wafer W is mounted on a stage while being offset from the center of the stage in a load lock chamber and an angle of rotation of the wafer W with respect to a fork when a transfer arm receives the wafer W is changed.

A transfer device including at least one first transfer component and at least one second transfer component are provided. The first transfer component includes a first carrier pad contacting the transferred object, and the second transfer component includes a second carrier pad contacting the transferred object, and material of the first carder pad has stronger capability to capture electrons than that of the second carrier pad and material of the second carrier pad has stronger capability to lose electrons than that of the first carder pad.

A vehicle windshield triangulation assembly (11), and triangulation method using it with a railing (22) fixed to a vehicle (16) via sliding/rotatable/orientation-adjustable/height-adjustable mounts (18). A sliding seat (21) on railing (22) receives the telescoping end (1) of assembly (11) after its two connected 360-degree rotation swivel clamps (7), each having a suction cup (8), are secured against the old windshield's (17) exterior surface. Assembly (11) triangulation transfers to a new/replacement windshield (17) by releasing suction cups (8) and pairing them in the same manner with the new/replacement windshield (17), and making needed height adjustment to a top stop (12/13) and the swivel clamp (7) remote from top stop (12/13). The telescoping end (1) of assembly (11) is then engaged with sliding seat (21), allowing one person to easily and accurately move the new windshield (17) into the same positioning of the old windshield (17). This triangulation method accommodates windshields (17) having any size and curvature, and installation of windshields (17) occurs without a dry set step, measuring, templating, or educated guessing being required.

A suspended transport vehicle travels along a track supported by a ceiling and transfers an article to a shelf of a rack installed on a floor, the suspended transport vehicle has a driving part, a first traveling part and a second traveling part, a ceiling-side member that is suspended downwards from the first traveling part and the second traveling part and has a transferring part that transfers the article to the shelf of the rack, a floor-side member that is provided so as to be capable of relative movement with respect to the ceiling-side member and has travel rollers being contacting parts in contact with a first guide part installed on the floor, and a distance sensor that detects a relative distance between the ceiling-side member and the floor-side member.

A substrate guide of the present invention is provided on a carrier frame of a carrier which holds a substrate substantially vertically so that a surface of the substrate is in a substantially vertical direction and supports the substrate by being in contact with at least a peripheral edge end surface portion of the substrate. The substrate guide includes a base attached to the carrier frame, a substrate support which comes into contact with the peripheral edge end surface portion of the substrate held by the carrier and is attached to the base to be movable in a normal direction of the peripheral edge end surface portion in a direction parallel to the surface of the substrate, and a force-applying member which applies a force to the substrate support toward the substrate with respect to the base.

A carrier transport system for transporting a carrier within a vacuum chamber is described. The carrier transport system includes a track assembly extending in a transport direction, the track assembly comprising: a first passive magnetic unit provided at a first vertical coordinate and extending in the transport direction, a second passive magnetic unit provided at a second vertical coordinate and extending in the transport direction, wherein the first passive magnetic unit and the second passive magnetic unit are configured to counteract the weight of the carrier; and a roller transportation track provided at a third vertical coordinate and comprising a plurality of rollers configured to support partial weight of the carrier, wherein a first vertical distance between the first vertical coordinate and the second vertical coordinate is larger than a second distance between the second vertical coordinate and the third vertical coordinate.