There is provided a method for picking up an object from a bin to be implemented by a robotic arm including a controller and a picking-up module. The method includes: recognizing, by the controller, at least one object in the bin based on an image of an interior of the bin so as to determine a type of each object; determining, by the controller, a score for each object based on the type thereof; determining, by the controller, whether a greatest score among the score(s) of the at least one TBT object is greater than a predetermined value; and by the picking-up module, picking up one of the at least one TBT object that has the greatest score when it is determined that the greatest score is greater than the predetermined value.

A multi-axis gantry system comprising a multi-axis gantry apparatus and vacuum system, and method for repositioning is disclosed. The multi-axis gantry system comprises a frame. The frame includes a plurality of curved base members, a first rail, a second rail, a bridge slidably moveable along the first rail and the second rail, a carriage including an end effector, and a first plurality of pucks and a second plurality of pucks. The vacuum system comprises a vacuum controller, a first vacuum source and a second vacuum source. Each of the first and second vacuum sources is in fluid communication with one or more pucks of the first and second pluralities of pucks. The frame is reconfigurable from a first configuration mountable on a first work surface to a second configuration mountable on a second work surface that may be different from the first work surface.

A suction clamp for clamping an object. The suction clamp includes a base structure including a base and a connection area, and a first pad for receiving the object. The suction clamp further includes a resilient member connecting the first pad to the connection area of the base structure such that the first pad is moveable relative to the base between a receiving position for receiving the object and a clamping position for clamping the object, wherein the resilient member is adapted to bias the first pad to the receiving position. The suction clamp further includes a suction opening arranged in the base and adapted to be connected to a suction device for providing a suction force for clamping the object on the first pad.

A robot gripper including: a base section; a first finger connected to the base section by a base section joint and n phalanxes; a second finger connected to the base section by a base section joint and n+m phalanxes, each phalanx of the second finger being connected to an adjacent phalanx by a phalanx joint and the first and second fingers being opposable to one other; wherein n and m are positive integers.

An object of the invention is to realize a high transfer throughput in a wafer transfer apparatus in which a wafer transfer robot transfers a wafer via an aligner. A wafer transfer apparatus includes a wafer transfer robot, and a separation dimension between a pair of wafer holding rods forming a finger of the wafer transfer robot is set to be larger than a dimension of a body portion of an aligner in a width direction provided in the wafer transfer apparatus. In addition, an elevating mechanism provided in the wafer transfer apparatus is configured to be able to move the finger to below the body portion of the aligner, thereby achieving the object of the invention.

A control apparatus causes a robot device to move a suction head to a predetermined position at which a workpiece is fed and attempt to pick up the workpiece with the suction head at the predetermined position. Upon determining that the suction head has yet to pick up the workpiece, the control apparatus causes the robot device to rotationally move the suction head spirally in a horizontal direction while causing the suction head to perform a suction operation for the workpiece, and estimates a direction in which the workpiece is located with respect to the predetermined direction based on a change in compressed air pressure during the rotational movement of the suction head.

An object recognition system includes: an image capture system for capturing at least one image of an object, and for providing image data representative of the captured image; a patch identification system in communication with the image capture system for receiving the image data, and for identifying at least one image patch associated with the captured image, each image patch being associated with a potential grasp location on the object, each potential grasp location being described as an area that may be associated with a contact portion of an end effector of a programmable motion device; a feature identification system for capturing at least one feature of each image patch, for accessing feature image data in the database and for providing feature identification data responsive to the image feature comparison data; and an object identification system for providing object identify data responsive to the image feature comparison data.

A slab handling system provides an accessory that can be configured to secure vacuum grippers to a beam. The accessory includes a body having a passageway therethrough for receiving the beam. The body further including slots on either side of the passageway that are configured to receive connectors of a vacuum gripper. In one embodiment the accessory can also be configured as a height-adjusting device. In one embodiment the accessory can also be configured as a traction device. The height-adjusting device and the traction device may be used in conjunction with the accessory and vacuum grippers to facilitate handling of one or more slabs.

An apparatus for an efficient label application comprising a conveyor belt; a barcode reader that is disposed above a conveyor belt and attached to a first cross beam; a 3D profiler that is disposed above said conveyor belt and attached to a second cross beam, and records size, shape, and orientation of a shipping package; a first plexiglass shield that comprises a light curtain; wherein said first plexiglass shield and light curtain protect a robotic arm's operating space on one side of said conveyor belt; a second plexiglass shield that protects said robotic arm's foot; a printer that is disposed next to said robotic arm; two upward facing fans that are disposed between said printer and said robotic arm, and, together, create an air cushion; a third plexiglass shield that protects said robotic arm, air cushion, and printer on second side of said conveyor belt; said first plexiglass shield, third plexiglass shied, and said conveyor belt define and protect a critical zone of said robotic arm's operating space; a printer control panel that is mounted on said third plexiglass shield; an operator control panel that allows said apparatus to be started, stopped, and calibrated, and is mounted on said third plexiglass shield.

The embodiments of this application provide a goods box take-out mechanism, device, and method, and a transport robot, belong to the field of transport robot technologies, and are intended to resolve the problem of wasting part of storage space of the warehouse when the current transport robots are used to carry goods boxes. The goods box take-out device includes a take-out assembly that is connected to a front surface of a to-be-transferred goods box and that can take out the goods box from a warehousing shelving unit. Since the take-out assembly is connected to the front surface of the to-be-transferred goods box, there is no need to reserve space below, above, or on left and right sides of the goods box for insertion and movement of the take-out assembly. Therefore, the storage space of the warehouse is fully utilized, and the storage density of the warehouse is improved.