This box assembling and packing system is provided: a first jig which is fixed at a predetermined position and against which a side part of a body of a packing box is thrust; a second jig which is fixed at a predetermined position and against which a flap part and a tuck part of the packing box are thrust; and a robot having two articulated arms. A first articulated arm of the two articulated arms holds and moves the packing box in a flatly collapsed form by a packing box holding mechanism, folds and raises the body of the flatly collapsed packing box into a rectangular tubular shape in cooperation with the first jig, and maintains the folded and raised body of the packing box in the rectangular tubular shape by a packing box rectangular tubular shape maintaining mechanism. The second articulated arm moves a folding member into contact with the flap part and the tuck part of the packing box being held by the packing box holding mechanism of the first articulated arm, forms each of a bottom and a lid of the packing box in cooperation with the second jig, and moves an object-to-be-packed being grasped by an object-to-be-packed grasping mechanism and inserts it into the body from an end portion at a timing between forming the bottom and forming the lid.

A robotic pack station is disclosed. The robotic pack station automates the transfer of items from a tote or bin to a shipping container such as a box in a warehouse, storage or sales facility. The robotic pack station includes system and method components, and includes a work cell with a robotic arm, machine vision or sensing system, a conveyor and pack platform. Imaging of the contents of the tote with a scan tunnel and connectivity with a sorter device allows for the operation of multiple robotic pack stations, each with a specialized function such as a small box line, a medium box line, and the like.

Methods and apparatus for performing repair operations using an unmanned aerial vehicle (UAV). The methods are enabled by equipping the UAV with tools for rapidly repairing a large structure or object (e.g., an aircraft or a wind turbine blade) that is not easily accessible to maintenance personnel. A plurality of tools are available for robotic selection and placement at the repair site. The tools are designed to perform respective repair operations in sequence in accordance with a specified repair plan, which plan may take into account the results of a previously performed UAV-enabled inspection.

A system for unloading parcels from a cargo area includes: an extendible conveyor; a transfer conveyor for conveying parcels to the extendible conveyor; and a mobile robot assembly configured to engage and transfer parcels in the cargo area onto the transfer conveyor. The mobile robot assembly repeatedly advances and transfers parcels in the cargo area to the transfer conveyor. As the mobile robot assembly advances within the cargo area, the transfer conveyor and the extendible conveyor follow to provide a pathway along which parcels transferred by the mobile robot assembly can be transferred out of the cargo area. The mobile robot assembly includes: a mobile base for repositioning the mobile robot assembly; a framework mounted to the mobile base; a first robot and a second robot, each mounted for vertical movement with respect to the framework and configured to engage and transfer parcels; and a vision and control subsystem.

A robotic end effector tool having multiple manipulator elements. The end effector includes a body, a suction cup movable relative to the body between a retracted position and an extended position, a plurality of fingers spaced around the suction cup and being actuatable between an open condition and a clamped condition, and a roller coupled to at least one of the fingers such that the roller is arranged to rotate about a first axis. The combination of the suction cup, the fingers and the rollers are arranged to pick an item and adjust the orientation of an object without setting the object down.

A waste sorting robot can include a manipulator comprising a suction gripper for interacting with one or more waste objects to be sorted within a working area, and wherein the manipulator is moveable within the working area. There is a controller configured to send control instructions to the manipulator. At least one pressure sensor is in fluid communication with the suction gripper and configured to generate a pressure signal in dependence on a fluid pressure in the suction gripper. The controller is configured to receive the pressure signal and to determine manipulator instructions in dependence on the pressure signal.

A robot control system includes: a selector configured to perform a selection of a task object from among a plurality of workpieces by using a first vision sensor; and an operation control section configured to control a robot to perform a task on the task object by using a tool. The selection and the task are executed simultaneously and in parallel, the selector transmits the information of the selected task object to the operation control section before the task, and the operation control section controls the robot based on the transmitted information of the task object.

Robotic systems are provided for flexibility in assembly operations. A robotic system includes a suction module having a front side with a face shaped to match a mating component and a rear side with a coupling for a suction line. Openings extend through the face. The suction module defines internal passages connecting the coupling with the at least one opening through the face. An end-effector has a base plate, a mounting plate selectively moveable relative to the base plate, and a clamp. The suction module is selectively mounted to the mounting plate and releasably secured by the clamp. An actuator is mounted to selectively move the mounting plate and the suction module relative to the base plate.

A handling device for a handling of products (14), in particular food products, which are conveyed by means of a transport device (12), has at least one handling unit (16) comprising a plurality of movably supported movement carriages (18), in particular movers, and a plurality of, in particular movably supported, handling elements (20), in particular vacuum grippers, wherein on each movement carriage (18) respectively at least one handling element (20) is arranged, and has at least one carrier structure (22), which in particular extends at least partially transversally over the transport device (12) and has at least one carrier element (24) on which the movement carriages (18) are supported in such a way that they are drivable, independently from each other in terms of speed and/or position, at least along a direction (28) running at least substantially parallel to a longitudinal axis (26) of the carrier element (24), the handling elements (20) being supported on the movement carriages (18) so as to be movable, in particular individually movable, the handling elements (20) in each case having a movement axis (30, 32) that extends transversally to the longitudinal axis (26) of the carrier element (24), and/or the carrier structure (22) comprising at least one bearing unit (34), in particular a rotary bearing unit and/or a linear bearing unit, by means of which the carrier element (24), in particular together with the movement carriages (18) arranged thereon, is supported so as to be vertically movable, wherein for a movement of the handling elements (20) relative to the movement carriages (18), the movement axes (30) of the handling elements (20) in each case run at least substantially parallel to a product support surface (60) of the transport device (12), wherein the handling device further comprises at least one electromagnetic drive unit (68) for an individual movement of the movement carriages (18) relative to the carrier element (24), the electromagnetic drive unit (68) being realized as a linear motor system, wherein the handling unit (16) comprises fluidic drives (42), in particular hydraulic or pneumatic cylinders, or electromagnetic drives, in particular electromagnetic drives assigned to a further linear motor system of the handling device, for a translational movement of the handling elements (20) along the respective movement axis (30) of the handling elements (20).

A remote operated underwater vehicle, ROV, is provided, where the ROV includes at least one extendible pair of tubulars supported on the ROV, the one tubular of the pair being movable longitudinally relative to the other tubular of the pair, for extending a combined reach of the tubulars; and at least one pump connected to the tubulars, the pump being operable for pumping or suctioning fluid through the pair.