A device for automatically stacking packages on a support comprising at least one feeding conveyor; a lifting and lowering unit for lifting and lowering a pallet; a position conveyor embodied as a travel container, which is arranged horizontally and longitudinally to one side of the storage place, in order to position the packages in the X-direction; at least one sliding plate and a pusher in order to transport the packages from the travel path in the Z-direction to the predetermined position in the stack. The at least one sliding plate may comprise a flat, strip-like plate that can move horizontally and longitudinally on the side of the storage place and transversally thereto, in order to remove packages from the positioning conveyor in the X direction when pushed by the pusher and arranging on the pallet in the Z-direction. The travel container contains pivotable stops and can be moved on rails.

A palletizing elevator is provided that lowers gradually a pallet thereon from an upper level as it is filled with products, and by providing an empty pallet infeed system that moves empty pallets towards the palletizing elevator simultaneously to the palletizing of products thereon. The empty pallet infeed system includes an empty pallet elevator for raising empty pallets to the upper level and a conveying system between the empty pallet elevator and the palletizing elevator for moving the empty pallets of from the empty pallet elevator at the upper level to the palletizing elevator while a pallet is moved by the palletizing elevator during its filling.

A block storage system with a block storage element, which includes a carrier frame and a load-bearing element, and a vehicle and a method for operating the block storage system. The method includes, via the vehicle, at least one of detaching the load-bearing element from the carrier frame or engaging the load-hearing element with the carrier frame.

Disclosed is a palletizing device (10) with a vertically mobile transfer station (14) which is in conveying communication with upstream conveying equipment (18) for conveying items, packaged goods, packages (20), or the like, to be palletized. The transfer station (14) is followed in the conveying direction (22) by a vertically mobile loading station (16) which is in conveying communication with a stacking position (28) for palletizing the items, packaged goods, and/or packages (20). The transfer (14) and loading stations (16) which are independently adjustable in the vertical positions thereof are associated with a common support structure, having separate guide devices (30) for vertically mobile guiding and drive devices for vertical position adjustment of the transfer (14) and loading stations (16), respectively. In addition, a method for handling such a palletizing device (10) is disclosed wherein the base planes (26, 48) of the transfer (14) and loading stations (16) are approximately flush at least while a layer of items, packaged goods, and/or packages (21) is pushed over between the two stations (14, 16).

Disclosed is a palletizing device (10) with a vertically mobile transfer station (14) which is in conveying communication with upstream conveying equipment (18) for conveying items, packaged goods, packages (20), or the like, to be palletized. The transfer station (14) is followed in the conveying direction (22) by a vertically mobile loading station (16) which is in conveying communication with a stacking position (28) for palletizing the items, packaged goods, and/or packages (20). The transfer (14) and loading stations (16) which are independently adjustable in the vertical positions thereof are associated with a common support structure, having separate guide devices (30) for vertically mobile guiding and drive devices for vertical position adjustment of the transfer (14) and loading stations (16), respectively. In addition, a method for handling such a palletizing device (10) is disclosed wherein the base planes (26, 48) of the transfer (14) and loading stations (16) are approximately flush at least while a layer of items, packaged goods, and/or packages (21) is pushed over between the two stations (14, 16).

Example systems and methods may provide for a heterogeneous fleet of robotic devices for collaborative object processing in an environment, such as a warehouse. An example system includes a plurality of mobile robotic devices configured to transport one or more objects within an environment, a fixed robotic manipulator positioned within the environment that is configured to manipulate one or more objects within an area of reach of the fixed robotic manipulator, and a control system. The control system may be configured to cause one or more of the plurality of mobile robotic devices to deliver at least one object to at least one location within the area of reach of the fixed robotic manipulator, and to cause the fixed robotic manipulator to distribute the at least one object to a different one or more of the plurality of mobile robotic devices for delivery to one or more other locations within the environment.

Example systems and methods may provide for a heterogeneous fleet of robotic devices for collaborative object processing in an environment, such as a warehouse. An example system includes a plurality of mobile robotic devices configured to transport one or more objects within an environment, a fixed robotic manipulator positioned within the environment that is configured to manipulate one or more objects within an area of reach of the fixed robotic manipulator, and a control system. The control system may be configured to cause one or more of the plurality of mobile robotic devices to deliver at least one object to at least one location within the area of reach of the fixed robotic manipulator, and to cause the fixed robotic manipulator to distribute the at least one object to a different one or more of the plurality of mobile robotic devices for delivery to one or more other locations within the environment.

An arrangement of loaded packages is estimated three-dimensionally. A loading position at which a target package is loaded next is determined based on the estimated arrangement. A position at which the target package is loaded is instructed by irradiation with an index light indicating the determined loading position. This method allows a package to be loaded in a limited space, for example, the package to be loaded optimally in a transport device or in a storehouse.

An arrangement of loaded packages is estimated three-dimensionally. A loading position at which a target package is loaded next is determined based on the estimated arrangement. A position at which the target package is loaded is instructed by irradiation with an index light indicating the determined loading position. This method allows a package to be loaded in a limited space, for example, the package to be loaded optimally in a transport device or in a storehouse.

The automatic layer picking assembly for a warehouse comprises a movable layer transporter comprising layer positioner that is operable to position the movable layer transporter with respect to the predetermined pallet positions separately from a pallet transporter during a pallet layer mixing operation.