A system and method directed for a tumbler insert which secures a tumbler from the inside without contacting any exterior surfaces, the insert having a plurality of flexible members or claws that may be bent or contracted when pressed into the tumbler, which creates sufficient tension to secure the holder within the vessel.

A robot includes a body coupled to a wheel assembly and a container retrieval device. The wheel assembly has a plurality of wheels and a drive mechanism arranged to move the body along a first set of parallel rails and along a second set of parallel rails. The container retrieval device includes an extendable and retractable grapple arranged to selectively secure an engagement feature positioned between a rim and a bottom surface of a container. The grapple thus allows the robot to lift multiple containers in a single lift.

Various aspects of robotic grippers are disclosed herein. In one aspect, a robotic gripper may include three gripper fingers arranged on a mechanical end effector, the three gripper fingers configured to translate radially when actuated to contact and align with a gripper interface located on a part to enable manipulation of the part. In various embodiments, each gripper finger may include an elongated portion configured to contact an outer surface of the gripper interface when the gripper fingers are actuated. Each gripper finger may further include a hook portion configured to contact an inner surface of the gripper interface opposing the outer surface. In various embodiments, the hook portion may include a receptacle positioned to align with a complementary protrusion on the gripper interface.

The invention relates to a consumable-material handling device for transporting and/or handling at least one consumable material (12a; 12b), in particular packaging material, comprising at least one at least partially autonomous handling unit (14a; 14b), which is at least provided for handling the consumable material (12a; 12b). According to the invention, the machine tool comprises at least one, in particular at least partially autonomous, mobility unit (16a; 16b), on which the handling unit (14a; 14b) is arranged and which is at least provided for enabling locomotion, in particular at least partially autonomous locomotion, of the handling unit (14a; 14b).

A manipulator configured for transferring a block having a core, the manipulator includes an end effector including an elongated member including a tip; and a resilient member configured for assuming a first state in which the resilient member has a first hardness and first size and a second state in which the resilient member is configured for assuming a second state in which the resilient member has a second hardness and second size, the resilient member is disposed on the tip, wherein the elongated member is configured to be disposed such that the tip is disposed within the core and the resilient member is disposed in the first state before the resilient member is disposed in the second state to engage the core and the elongated member is moved to transfer the block.

Systems, methods, and associated components for robotic manipulation of physical objects. The physical objects include three-dimensional gripping features configured to be detected by an optics system and gripped by an end-effector of a robotic arm with sufficient gripping force to move the physical objects against the force of gravity. Sets of the physical objects can have different sizes and shapes and, in some examples, include identically constructed three-dimensional gripping features.

A mechanical device for grasping an object includes a receiver having a distal end shaft with an internal bore, the internal bore defining a recessed track. The recessed track defines a curvilinear path having two sets of resting peaks, each set of resting peaks being at a different height relative to a centerline of the curvilinear path. An actuator is slidably engaged with the receiver and includes a central shaft and an activator disposed at a distal end portion of the central shaft. A rotatable sleeve is disposed within the internal bore of the receiver and is coupled to the actuator. The rotatable sleeve has opposed protrusions, the opposed protrusions being disposed within the recessed track of the receiver. A pilot is secured to a distal end portion of the receiver and a grasping device is mounted to the pilot and coupled to the activator.

A gripping device includes a side supporting unit supporting or releasing a side of a workpiece, a plurality of pusher members pushing the workpiece downward, and a pusher member shifting unit shifting the pusher members in a direction toward or away from the workpiece. An engaging pin to be engaged with a through-hole created in the workpiece is disposed inside at least one of the pusher members.

The disclosure concerns a pivoting unit for a handling robot for opening a flap (e.g. door) of a motor vehicle body, comprising a mounting flange, a gripper arm and a first gripping tool for gripping an engagement on the flap to be opened, the first gripping tool being mounted on the gripper arm, and a pivoting head for pivoting the gripper arm between an initial position and an engaged position. The disclosure provides that a second gripping tool is also mounted on the gripper arm, and that the two gripping tools on the gripper arm are adapted to be inserted in different insertion directions into engagement with the openable flap of the motor vehicle body, in particular from top to bottom for the first gripping tool and from bottom to top for the second gripping tool. The disclosure further comprises an associated method.

A robot tool, a robot system and a method for packaging coils of sheet metal. A robot tool for coil packaging, having two ends, each end being provided with a coupling tool piece configured to interface with a robot arm; a roll holder shaft configured to hold a roll of wrapping material, the holder shaft at one end being rotatably mounted substantially midway between said ends and projecting substantially perpendicular to an axis extending between said ends. A robot system for coil packaging, having two industrial robots, each robot being provided with a robot arm having a coupling robot piece configured to interface with a robot tool; and a robot tool, the robot tool having two ends, each end being provided with a coupling tool piece configured to interface with a said robot arm.