A glass sheet semiconductor deposition system (20) for coating semiconductor material on glass sheets is performed by conveying the glass sheets vertically suspended at upper extremities thereof by a pair of conveyors (38) through a housing (22) including a vacuum chamber (24). The glass sheets are conveyed on shuttles (42) through an entry load station (26) into the housing vacuum chamber (24), through a heating station (30) and at least one semiconductor deposition station (32, 34) in the housing (22), and to a cooling station (36) prior to exiting of the system through an exit load lock station (28). The semiconductor deposition station construction includes a deposition module (102) and a radiant heater (104) between which the vertical glass sheets are conveyed for the semiconductor deposition.

A Cartesian transport device for the transportation of a container plate or a stack of container plates, with a horizontal linear axis, on which a vertical linear axis is arranged such that the plate is movable in the x direction. A transfer unit is arranged on the vertical linear axis such that it is moveable in the z direction. The transfer unit has a support structure and two telescopic arms connected to it and arranged in parallel. A container plate may be grasped and held between the telescopic arms. A horizontal shelf is solidly arranged under the transfer unit on the vertical linear axis between the telescopic arms, such that the container plate may be set down between the telescopic arms.

An automatic identification and classification production line for mobile terminal liquid crystal display (LCD) screens includes a size and posture identification adjustment part, a model identification part, and a classification storage device. The size and posture identification adjustment part can transport a mobile terminal LCD screen, identify front and back surfaces of the mobile terminal LCD screen, size of the mobile terminal LCD screen, and orientation of the mobile terminal LCD screen, and adjust the front surface of the mobile terminal LCD screen to face up and the orientation of the mobile terminal LCD screen to be the same as the transportation direction during transportation. The model identification part transports the mobile terminal LCD screen after adjustment of the posture, and identifies model of the mobile terminal LCD screen according to the size during transportation. The classification storage device classifies and stores mobile terminal LCD screens according to different models.

An automatic identification and classification production line for mobile terminal liquid crystal display (LCD) screens includes a size and posture identification adjustment part, a model identification part, and a classification storage device. The size and posture identification adjustment part can transport a mobile terminal LCD screen, identify front and back surfaces of the mobile terminal LCD screen, size of the mobile terminal LCD screen, and orientation of the mobile terminal LCD screen, and adjust the front surface of the mobile terminal LCD screen to face up and the orientation of the mobile terminal LCD screen to be the same as the transportation direction during transportation. The model identification part transports the mobile terminal LCD screen after adjustment of the posture, and identifies model of the mobile terminal LCD screen according to the size during transportation. The classification storage device classifies and stores mobile terminal LCD screens according to different models.

An insulating glass unit cooling assembly and method of cooling an insulating glass unit is provided. The cooling assembly includes a cooling unit that directs air at insulating glass units and a conveyor that transports insulating glass units along a path of travel defining an axis of travel for the insulating glass units. The conveyor has a conveyor planar surface that supports a corresponding planar glass surface of the insulating glass units as the insulating glass units are conveyed along the axis of travel such that the planar surface of the insulating glass units are substantially horizontal and substantially parallel to the conveyor planar surface. The air from the cooling unit is directed in a path substantially parallel with the conveyor planar surface and the planar glass surface of the insulating glass units as the insulating glass units travel along the conveyor.

Disclosed is a guide module and a driving device having the guide module. The driving device includes a moving unit mounted on a pinion interacting with a rack and moving with the pinion along a trajectory of the rack, and a guide module arranged at at least any one side of the rack, connected to the moving unit, and guiding a movement of the moving unit that moves with the pinion along the trajectory of the rack.

A panel transfer tray according to an embodiment includes an accommodation part which accommodates a target panel, a protrusion protruding upward direction from an upper edge of the accommodation part, and a first movement prevention member disposed at one side of the accommodation part and disposed adjacent to the protrusion, and the first movement prevention member has a stair shape of which a planar area gradually decreases along the upward direction.

The present disclosure is directed to carrier device, and related systems. A device may include a handle and at least one attachment device coupled to the handle. The at least one attachment device may be configured to couple to a solar module, wherein each attachment device includes at least one of a channel for receiving a portion of a frame of the solar module.

A conveyance apparatus includes a stator in which a plurality of coils is arranged along a first direction and a movable element to move along the plurality of coils. The stator includes a first magnet group including a plurality of first magnets arranged along the first direction and magnetized in one direction. The movable element includes a second magnet group including a plurality of second magnets arranged to face the plurality of coils, and a third magnet group including a plurality of third magnets arranged to face the first magnet group and magnetized in a direction repelling the first magnet group.

A conveyance apparatus includes a stator in which a plurality of coils is arranged along a first direction and a movable element to move along the plurality of coils. The stator includes a first magnet group including a plurality of first magnets arranged along the first direction and magnetized in one direction. The movable element includes a second magnet group including a plurality of second magnets arranged to face the plurality of coils, and a third magnet group including a plurality of third magnets arranged to face the first magnet group and magnetized in a direction repelling the first magnet group.