A robotic system has a vehicle, a robot, a first removable rack and a second removable rack. The robot, the first removable rack and the second removable rack are mounted on a platform of the vehicle. A plurality of latches are used to lock or unlock the first removable rack and the second removable rack. The robot comprises a rotatable base. A method uses the robotic system to move a plurality of items from a stationary rack to a designated location.

A system for positioning a lifting cart in an automated storage facility is described. In one example, the system includes a motorized lifting cart configured to move about a railway of a storage area. An encoder on the cart reads a property of rotation of a rotating element on the cart, and a controller may receive the property of rotation from the encoder and convert it to a rotation count of the rotating element. The rotating element may be an encoder shaft, drive shaft, and like elements. Some systems include a signal emitter or photo sensor to position the lifting cart and to facilitate providing instructions to the cart.

A variety of vehicle-based and warehouse-based solutions are provided to increase the adaptability, utility, and efficiency of materials handling vehicles in the warehouse environment, such as a goods storage and retrieval system, comprising a multilevel warehouse racking system, a mobile storage cart, a cart home position, and a materials handling vehicle disposed on a vehicle transit surface and comprising a fork carriage assembly, a navigation subsystem, a cart engagement subsystem, and one or more vehicular controllers to use the navigation subsystem to navigate the materials handling vehicle along the vehicle transit surface to a localized engagement position where the cart home position is within a cart engagement field of view, and use the cart engagement subsystem to engage the mobile storage cart in the cart home position with the fork carriage assembly.

A workstation receives bots carrying order totes and bots carrying product totes for transfer of goods from the product totes to the order totes. The workstation comprises a robot for automated transfer of goods between the product and order totes, but may also have a station for an operator to perform manual transfer. Cameras may be provided to capture images of the product and/or order totes to identify contents of totes and to identify positions where goods are to be picked from the product totes and placed into the order totes.

A delivery system includes a database configured to store information of a customer where the information includes a default payment method, a communication system configured to communicate with an autonomous vehicle and with a device of the customer, where the device includes a display screen having a button to summon an autonomous vehicle, at least one processor, and a memory storing instructions. The instructions, when executed by the at least one processor, cause the delivery system to receive an indication via the communication system that the button on the device of the customer has been clicked, and instruct the autonomous vehicle to travel to a location of the customer.

It is disclosed a method (70) for operating a storage and order-picking system (10) in which a plurality of manipulators (40) process a plurality of picking/storing orders in accordance with a manipulator-to-handling-unit principle, wherein the system (10) comprises a provision zone (12), a picking zone (14), a plurality of provision units (42, 62) in the provision zone, a plurality of, particularly stationary arranged, transfer locations (46) in the picking zone (14), a DTS (18) including a plurality of DTVs (20), and a controlling device (32), and wherein the method (70) comprises the following steps of: analyzing (S10) the plurality of picking/storing orders by the controlling device (32) for determining retrieval/delivery locations in the provision zone (12); setting (S12) of transfer actions (48) by selecting for each of the retrieval/delivery locations one or more of the transfer locations (46) in the picking zone (14) as delivery/retrieval location and by assigning the same thereto, wherein the delivery/retrieval location is located within an action zone (72) extending around the respective retrieval/delivery location and moving dynamically with the respective manipulator (40); generating (S14) an action order for each of the manipulators (40) by selecting some of the transfer actions (48), and setting a, particularly unidirectional, moving path (74) along which the respective manipulator (40) moves between the selected retrieval/delivery locations throughout the, preferably entire, picking zone (14); and generating (S16) transport orders for the DTVs (20) so that each of the manipulators (40), during performance of its action order, can perform its transfer actions (48) within its action zone (72), preferably without interruption.

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.

An order-picking method includes autonomously routing a plurality of mobile robotic units in an order fulfillment facility and picking articles to or putting articles from the robotic units in the order fulfillment facility. A material-handling robotic unit that is adapted for use in an order fulfillment facility includes an autonomous mobile vehicle base and a plurality of article receptacles positioned on the base. A visual indicator associated with the receptacle facilitates picking articles to or putting articles from the robotic unit.

An example system includes a conveyor configured to move a plurality of items, a ramp configured to support at least one item of the plurality of items as the at least one item is transferred from the conveyor to a tote, and a platform supported on a support surface and configured to support the tote at a location proximate the ramp. In some examples, the tote includes a base having a top surface defining at least part of an interior space of the tote. Further, the platform positions the tote such that the top surface of the base extends at an angle, relative to a horizontal plane, greater than approximately 5 degrees and less than approximately 10 degrees.

A hybrid modular storage fetching system is described. In an example implementation, an automated guided vehicle of the hybrid modular storage fetching system includes a drive unit that provides motive force to propel the automated guided vehicle within an operating environment. The automated guided vehicle may also include a container handling mechanism including an extender and a carrying surface, the container handling mechanism having three or more degrees of freedom to move the carrying surface along three or more axes. The container handling mechanism may retrieve an item from a first target shelving unit using the carrying surface and the three or more degrees of freedom and place the item on a second target shelving unit. The automated guided vehicle may also include a power source coupled to provide power to the drive unit and the container handling mechanism.