The disclosed is a vehicle for the autonomous transport of an object to a destination, having a loading bed for receiving the object, a side wall extending longitudinally around the loading bed and bounding a usable area of the loading bed, and a controller, wherein the loading bed is designed to alter the usable area, and the controller is designed to navigate the vehicle to the destination along a route that takes the alteration in the usable area into consideration.

A robot system includes a robot having a gripping unit for picking and placing down/throwing goods, wherein the goods are differentiated into multiple types with respect to their dimensional stability, compressive stability, flexural rigidity, strength, their absolute weight and/or specific weight. When the goods are manipulated, the robot and/or the gripping unit are controlled depending on the type determined for the goods. Moreover, a method operates the robot system.

The disclosure relates to the control of a printed product processing system, which comprises a collecting system having a conveyer and a plurality of feed conveyers for creating product collections from products fed by the feed conveyers, occupancy plans are generated and stored which specify, for the feed conveyers, in each case a chronological sequence of the products to be fed by the feed conveyer to the conveyer to create the product collections. On the basis of the occupancy plans, for the feed conveyers, in each case one product to be fed is determined and transmitted to mobile transport devices. The occupancy plans enable the operating personnel to announce early and in good time which products the feed conveyers are to be occupied with and which must for this purpose be supplied thereto on pallets.

The invention relates to a method for bundling conveyed streams on a material handling element (Ka . . . Kz, K1 . . . K34) comprising a number of incoming conveyor segments (1a, 1b), at least one coupling (2) to an outgoing conveyor segment (3), on which the incoming conveyor segments (1a, 1b) converge, and a number of holding devices (4a, 4b) for holding a conveyed stream on the incoming conveyor segments (1a, 1b). In a first step the conveyed objects (17) are vectorially combined in in ascending/descending order according to a desired sorting sequence. When a conveyed object (17) passes the material handling element (Ka . . . Kz, K1 . . . K34) a vector corresponding to the actual sequence is entered in the vector combination. Conveyed objects (17) are released if a ring with a constant direction is avoided in the vector combination. The invention further relates to a material handling element (Ka . . . Kz, K1 . . . K34) for carrying out said method.

An order picking system, which includes a plurality of motorised mobile units able to carry containers for receiving one or more products of an order dropped in them by an order picker. The containers have a single product dispensing tray mounted on a base configured so as to elevate the tray at least 60 cm, preferably at least 80 cm. The base includes an interlock with the mobile units and the ground support. Also provided is an order picking method for preparing at least a portion of an order.

A sortation system is disclosed that includes a programmable motion device including an end effector, a perception system for recognizing any of the identity, location, and orientation of an object presented in a plurality of objects, a grasp selection system for selecting a grasp location on the object, the grasp location being chosen to provide a secure grasp of the object by the end effector to permit the object to be moved from the plurality of objects to one of a plurality of destination locations, and a motion planning system for providing a motion path for the transport of the object when grasped by the end effector from the plurality of objects to the one of the plurality of destination locations, wherein the motion path is chosen to provide a path from the plurality of objects to the one of the plurality of destination locations.

Described in detail herein is an automated fulfillment system including a computing system programmed to receive requests from disparate sources for physical objects disposed at one or more locations in a facility. The computing system can combine the requests, and group the physical objects in the requests based on object types or expected object locations. Autonomous robot devices can receive instructions from the computing system to retrieve a group of the physical objects and deposit the physical objects in storage containers.

Described in detail herein is an automated fulfillment system with automatic exception handling. A computing system can transmit instructions to an autonomous robot device to retrieve physical objects disposed in facility. An autonomous robot device can navigate to the location of the physical objects and pick up a first quantity of physical objects. The autonomous robot device can pick up the physical objects and can determine a set of attributes associated with the picked up physical objects. The autonomous robot device detect an error with the physical objects picked up by the autonomous robot device based on the set of attributes. The autonomous robot device can resolve the error with the physical objects that were picked up by the autonomous robot device. For example, autonomous robot device can discard the physical objects. The autonomous robot device can pick up replacement physical objects.

Described in detail herein is an automated fulfilment system including a computing system programmed to receive requests from disparate sources for physical objects disposed at one or more locations in a facility. The computing system can combine the requests, and group the physical objects in the requests based on object types or expected object locations. Autonomous robot devices can receive instructions from the computing system to retrieve a group of the physical objects and deposit the physical objects in storage containers.

A method for executing orders by at least one robot on a plurality of items stored at locations throughout a warehouse including reading a bar code affixed to an item storage array disposed on said at least one robot. The item storage array includes a plurality of interconnected containers each for storing items associated with an order. The method also includes using the read bar code to retrieve information about at least one characteristic of the item storage array and assigning an order associated to each of the plurality of containers of the item storage array. The orders are based in part on the at least one characteristic of the item storage array. The method further includes navigating the at least one robot to locations throughout the warehouse to execute the orders associated with each of the plurality of containers of the item storage array.