A self-driven carriage (2) stores and accesses containers (4) in a storage rack arrangement (3) and includes a first wheel set (37) driving along a first axis (x) and a second wheel set (43) driving along a second axis (y) transverse to the first axis (x). At least one of the wheel sets is essentially vertically movable between a driving position and an idle position. A lower one of the wheel sets is in the driving position and the upper one of the wheel sets is in the idle position. The carriage includes a support surface (39) that carries a bottom surface of the container and a centering and securing system, centering and securing a container on the support surface, and including engaging elements movable in opposite directions between an idle position and a securing position in which the engaging elements engage the container.

A storage system is disclosed where goods can be stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of rails (e.g., tracks) on which load handling devices can run. To take containers from the stacks and deposit then at alternative locations in the stacks or deposit then at stations where goods may be picked. The framework may be provided with one or more of the following exemplary services: power, power control, heating, lighting, cooling, sensors, and data logging devices. The provision of these services within the framework rather than across the system as a whole, can allow for flexibility in storage whilst reducing cost and inefficiency.

A storage system includes a rack with a plurality of layers, each layer including an aisle and a plurality of rows extending from the aisle defining storage locations for items. A shuttle usable with the rack includes a first cart movable along the aisle and a second cart configured to be carriable by the first cart and to be movable along a row. The second cart is configured to carry an item between the first cart and the storage locations. A conveyor is located on one of the first or second carts to move the item onto or off the first cart. Related methods of storing and/or retrieving items from a rack are also disclosed. A rack system is disclosed and is readily assembled without welding, transferring loading so that the weight of the rack and any item stored therein is supported by the upright elements via support brackets.

A processing system for processing objects using a programmable motion device is disclosed. The processing system includes a perception unit for perceiving identifying indicia representative of an identity of a plurality of objects received from an input conveyance system, and an acquisition system for acquiring an object from the plurality of objects at an input area using an end effector of the programmable motion device. The programmable motion device is adapted for assisting in the delivery of the object to an identified processing location. The identified processing location is associated with the identifying indicia and the identified processing location is provided as one of a plurality of processing locations. The system also includes a delivery system for receiving the object in a carrier and for delivering the object toward the identified processing location.

An order fulfillment system includes a storage structure for storing totes, workstations for processing customer orders and a staging and sequencing buffer having staging locations for storing the totes. The staging and sequencing buffer provides a buffer for totes as mobile robots transfer totes from the storage structure and to the one or more workstations.

An automated guided vehicle, a system for sorting cargo, and a method of sorting cargo using the same are provided. The system for sorting cargo according to an embodiment includes an automated guided vehicle, a cargo supply unit, a plurality of cargo sorting units, a supply control unit configured to load the plurality of pieces of cargo supplied from the cargo supply unit into the plurality of cargo loading units of the automated guided vehicle, a transport control unit configured to transport the pieces of cargo to each cargo sorting unit while controlling a movement path of the automated guided vehicle into which the plurality of pieces of cargo are loaded; and a discharge control unit configured to discharge at least one piece of cargo transported through the automated guided vehicle to each cargo sorting unit to sort the at least one piece of cargo.

The present invention relates to the technical field of vertical automatic storage cabinets and provides a vertical automatic storage cabinet that comprises: a cabinet body; storage racks; a grasping structure and a conveying structure. In the present vertical automatic storage cabinet, at least two storage racks are provided to be spaced apart in the height direction of the cabinet body, and the grasping structure is located in the area between the two storage racks. When in use, the storage boxes on both the upper and lower sides can be taken off the mounting rack, then can be transferred to the conveying structure, and the storage boxes can be conveyed to the outside of the cabinet body.

A storage, retrieval and processing system is disclosed for processing objects. The system includes a plurality of bins including objects to be distributed by the processing system, said plurality of bins being provided in at least a partially generally circular arrangement, a programmable motion device that includes an end effector for grasping and moving any of the objects, said programmable motion device being capable of reaching any of the objects within the plurality of bins, and a plurality of destination containers for receiving any of the objects from the plurality of bins, said plurality of destination containers being provided in a region that is generally within the at least partially generally circular arrangement of the plurality of bins.

Systems and methods can enhance efficiencies of order fulfillment processes. For example, this document describes systems and methods for optimizing the efficiency of multiple order sortation process lines to expedite order processing in a cost-effective manner. In some embodiments, this innovation includes an efficient method for loading or filling the capacity of multiple parallel order sortation process lines so that they operate at peak efficiently and the operators are utilized at a high level. Additionally, the systems and methods promote efficiency enhancements of order sortation equipment by reducing the potential for downtime due to material flow interferences.

A method for storing containers in an automated storage and retrieval system includes a framework structure including upright members, horizontal members and storage columns provided between the members. Storage containers are stackable in stacks within the storage columns. The method includes: defining a first storage area, wherein the first storage area includes specific storage columns within the framework structure; setting a first maximum weight threshold for the first storage area; determining a total weight for all storage containers stored in the first storage area; determining a weight for a further storage container which is to be stored within the framework structure; and determining a storage position for the further storage container to be within the first storage area if the sum of the total weight and the weight of the further storage container is below the first maximum weight threshold, or determining the storage position for the further storage container to be outside of the first storage area if the sum of the total weight and the weight of the further storage container is above the first maximum weight threshold.