An automated palletizer includes an automated package pick device capable of moving packages from a package deposit section to a pallet to form a pallet load from packages, a controller that is operably connected to the automated pick device, the controller having a pallet load generator configured to determine a pallet load structure of mixed packages, the pallet load generator being programmed so that it determines the load structure from mixed package layers overlaid over each other at least one of the mixed package layers being formed of stacks of mixed packages, top and bottom surfaces of the stacks corresponding to the at least one mixed package layer respectively forming top and bottom surfaces of the at least one mixed package layer that are substantially flat. The controller generates commands for the pick device to build the pallet load from the load structure determined by the pallet load generator.

An article supplying apparatus includes a retention unit configured to retain an article, a robot hand configured to insert the article retained in the retention unit into a container, and a control unit configured to control operation of the robot hand. The robot hand has a holding portion for holding the article. The control unit executes holding control in which the article is held by the holding portion; and stand-by insertion control in which after the holding portion is temporarily disposed at a stand-by position different from a position immediately above an article insertion port in the container and set on a movement path from a start position of the holding through the holding control to the position immediately thereabove, the holding portion is moved to the position immediately thereabove, and the article is inserted into the container via the article insertion port.

An article supplying apparatus includes a retention unit configured to retain an article, a robot hand configured to insert the article retained in the retention unit into a container, and a control unit configured to control operation of the robot hand. The robot hand has a holding portion for holding the article. The control unit executes holding control in which the article is held by the holding portion; and stand-by insertion control in which after the holding portion is temporarily disposed at a stand-by position different from a position immediately above an article insertion port in the container and set on a movement path from a start position of the holding through the holding control to the position immediately thereabove, the holding portion is moved to the position immediately thereabove, and the article is inserted into the container via the article insertion port.

A system and method for operating a robotic system to place objects into containers that have support walls is disclosed. The robotic system may detect an unexpected condition associated with a container during or before a real-time operation. Accordingly, the robotic system may dynamically adjust an existing packing plan based on detecting the unexpected condition.

A system and method for operating a robotic system to place objects into containers that have support walls is disclosed. The robotic system may detect an unexpected condition associated with a container during or before a real-time operation. Accordingly, the robotic system may dynamically adjust an existing packing plan based on detecting the unexpected condition.

Systems, methods, and computer-readable media are disclosed for concentric suction cup tools with parallel pistons. In one embodiment, an example picking assembly may include a first piston subassembly with a first air cylinder, a first sliding rail that slides relative to the first air cylinder, and a first suction cup. The example picking assembly may include a second piston subassembly comprising a second air cylinder, a second sliding rail that slides relative to the second air cylinder, and a second suction cup, where the first and second piston subassemblies may be configured to independently actuate from a retracted position to an extended position. The example picking assembly may include a first guide plate with a first aperture for the first piston subassembly and a second aperture for the second piston subassembly, a shell that forms a housing for the picking assembly, and an airflow coupler.

Systems, methods, and computer-readable media are disclosed for concentric suction cup tools with parallel pistons. In one embodiment, an example picking assembly may include a first piston subassembly with a first air cylinder, a first sliding rail that slides relative to the first air cylinder, and a first suction cup. The example picking assembly may include a second piston subassembly comprising a second air cylinder, a second sliding rail that slides relative to the second air cylinder, and a second suction cup, where the first and second piston subassemblies may be configured to independently actuate from a retracted position to an extended position. The example picking assembly may include a first guide plate with a first aperture for the first piston subassembly and a second aperture for the second piston subassembly, a shell that forms a housing for the picking assembly, and an airflow coupler.

A method for operating a robotic system includes determining a discretized object model representative of a target object; determining a discretized platform model representative of a task location; determining height measures based on real-time sensor data representative of the task location; and dynamically deriving a placement location based on (1) overlapping the discretized object model and the discretized platform model for stacking objects at the task location and (2) calculating a placement score associated with the overlapping based on the height measures.

A method for operating a robotic system includes determining a discretized object model representative of a target object; determining a discretized platform model representative of a task location; determining height measures based on real-time sensor data representative of the task location; and dynamically deriving a placement location based on (1) overlapping the discretized object model and the discretized platform model for stacking objects at the task location and (2) calculating a placement score associated with the overlapping based on the height measures.

The invention relates to a palletizing apparatus (10) comprising a compressing apparatus (60) which has a peripheral closed frame (70), wherein at least one slider (61, 62, 63, 64) that is movable in a horizontal direction is arranged on the frame (70), and a set-down device (50) which defines a transport face (53) for transporting article layers (15). The frame (70) surrounds a through-opening (67) that passes through in a vertical direction (Z), and the set-down device (50) is movable in a longitudinal direction (X) relative to the compressing apparatus (60) between a first longitudinal position, in which the transport face (53) is arranged in a manner offset in the longitudinal direction (X) with respect to the frame (70), and a second longitudinal position, in which a projection of the through-opening (67) in the vertical direction (Z) lies on the transport face (53). The compressing apparatus (60) and the set-down device (50) are in this case arranged on a lifting apparatus (20) so as to be movable in the vertical direction (Z). The invention also relates to a method for operating a palletizing apparatus (10) according to the invention, which comprises a plurality of steps.