A slide rack gripper apparatus is provided that simultaneously conveys a plurality of glass slides in the protection of a slide rack within a digital slide scanning apparatus. The slide rack gripper apparatus conveys the plurality of glass slides from a slide rack carousel to a scanning stage for processing. The slide rack gripper includes a first motor attached to a base configured to drive a finger mount attached to the base along a first linear axis. The slide rack gripper apparatus also includes a second motor attached to the finger mount and configured to drive opposing gripper fingers attached to the finger mount along a second linear axis. The second motor is also configured to drive individual gripper fingers along a third linear axis to move the gripper fingers toward each other and away from each other to grasp or release a slide rack.

An apparatus for printing on containers includes a transport arm and a lift that cooperate to form a first container-transport device that moves a container at a container-loading position into a printing position. The transport arm is arranged on the lift and pivotable about a pivot axis thereof. The lift is axially displaceable and displaces the transport arm axially in relation to the pivot axis. At the printing position, a print head prints on the container.

An automatic case loader for loading product in a trailer is disclosed. A mobile base structure provides a support framework for a drive subassembly, conveyance subassembly, an industrial robot, a distance measurement sensor, and a control subassembly. Under the operation of the control subassembly, product advances through a powered transportation path to an industrial robot which places the product within the trailer. The control subassembly coordinates the selective articulated movement of the industrial robot and the activation of the drive subassembly based upon the distance measurement sensor detecting objects within a detection space, dimensions of the trailer provided to the control subassembly, and dimensions of the product provided to the control subassembly.

A mass measurement device comprises a force sensor, a hose, a base part, an article-holding part, and a computation unit. The force sensor has a fixed end and a free end, and outputs a sensing signal in accordance with the magnitude of a force in a sensitivity direction. The hose is configured to pass suctioned air through it. The fixed end is fixed to the base part. The article-holding part is fixed to the free end, one end of the hose is connected to the article-holding part, and the article-holding part holds an article by air suction. The computation unit computes the mass of the article based on the sensing signal.

Provided is a workpiece conveying apparatus including: two SCARA robots each including: a raising and lowering frame supported on a stationary frame so as to be movable in an up-and-down direction, the stationary frame being mounted to extend along a width direction orthogonal to a workpiece conveying direction of a passage space for conveying a workpiece; a first arm supported on the raising and lowering frame through intermediation of a first joint; a second arm held through intermediation of a second joint; a first arm driving mechanism configured to drive the first arm to rotate; and a second arm driving mechanism configured to drive the second arm to rotate; raising and lowering mechanisms arranged to correspond to the two SCARA robots, respectively, and configured to enable the corresponding raising and lowering frames to mutually independently move in the up-and-down direction; a cross arm; and a cross bar unit.

An artificially intelligent harvest and reuse system for planting vegetables has a first mechanic arm moving a plurality of planting plates around a first conveyor, a second conveyor, a first shelf and a second shelf. The planting plates are sent to a connecting conveyor for the grown vegetables thereon to be picked up by a second mechanic arm and further sent to a root cutting apparatus then to a packaging apparatus, while the empty planting plates are further sent to an exit end of the first conveyor and a third mechanic arm places nursery foams with sprouts from a storage area onto the empty planting plates. Then the refilled planting plates are sent back to the corresponding shelf via the second conveyor and placed back into the corresponding layers neatly by the first mechanic arm on a first distributing apparatus.

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 overhead transport vehicle travels along a rail on a ceiling of a building to transport a FOUP. The overhead transport vehicle includes a holding base and an upper shelf transfer device. The holding base holds at least one of a side surface and a bottom surface of the FOUP. The upper shelf transfer device moves the holding base at least upwardly while holding the FOUP. The upper shelf transfer device moves the holding base from the holding position in which the holding base holds and transfers the FOUP to the upper transfer position to transfer the FOUP, which is a different position from the holding position in a plan view and higher than the holding position.

The invention discloses an automatic-sensing transfer device based on an edge-tracing alignment algorithm, which is characterized by comprising a device body, a rotating device, a lifting device, a stretchable device, a sensing device, a gripping device and a control device. The rotating device, the stretchable device, the lifting device, the sensing device, the gripping device and the control device are all arranged on the device body. The control device is connected to the rotating device, the stretchable device, the lifting device, the gripping device and the sensing device. Accurate positioning of the gripping device can be realized through the transfer device, so that the production efficiency is improved.

A rear suspension member (RSM) transfer assembly for transferring an RSM from a sub-assembly line to a main assembly line includes a first RSM lifter, an RSM buffer, and a second RSM lifter. The first RSM lifter is configured to travel laterally between the sub-assembly line and the main assembly line. The first RSM lifter includes a lifting body and a rotatable arm configured to retrieve the RSM from the sub-assembly line and transport the RSM to the main assembly line. The RSM buffer is configured to receive the RSM from the first RSM lifter and transport the RSM through a plurality of resting positions. The second RSM lifter is configured to receive the RSM from the RSM buffer and raise the RSM into position for installation on a vehicle.