A system for picking items from a containerised storage system is described. The items are stored in storage bins in stacks within a framework comprising a grid system disposed above the stacks of bins. Robotic devices are disposed on the grid, the devices acting so as to pick containers from the stacks of bins. The storage system is provided with at least one picking device for picking items from bins and depositing them directly in delivery containers DT.

A storage system includes a storage grid structure having a top rail grid upon which container handling vehicles work to store and retrieve storage containers in and from storage columns beneath the top rail grid. The storage system includes multiple transfer rails forming a horizontal transfer rail grid arranged at a level below the top rail grid. At least one transport vehicle operates on the transfer rail grid. The storage system includes a picking/stocking station for picking/stocking items between a storage container and a packaging box, and an unloading/loading assembly for unloading/loading packaging boxes containing such items. The transport vehicle is arranged to move upon the transfer rail grid in two perpendicular directions and comprises a carrier platform. The transfer rail grid is arranged to allow access for the transport vehicle to transport one or more packaging boxes at a time between the picking/stocking station and the unloading/loading assembly.

Systems and methods are disclosed for wireless powering and control of conveyors on shuttles. An example system may include a track, and a shuttle configured to move along the track, the shuttle having a conveyor, and a first induction coil. The system may include a second induction coil disposed at a first location along the track, where the second induction coil is configured to interact with the first induction coil to power the conveyor. The shuttle may not have an onboard power source coupled to the conveyor.

System includes an article supply location that includes a plurality of articles to be sorted, first and second transport vehicles, each having a first position in which an article is stowed about the vehicle and a second position in which the article is deposited into a proximal container, and one or more removal devices that transport the container to a location of further processing. System further includes a control system configured to receive an order for a plurality of disparate articles, determine one destination container of a plurality of destination containers to direct the transport vehicle to deposit a selected article, direct the first transport vehicle to transport a selected article to the destination container, deposit the article in the destination container, and transport the destination container to a location for further processing by manipulation of the removal device.

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.

An inventory management system includes pick stations, automated vehicles having an onboard power source, a first drive system configured to horizontally displace the vehicle, a second drive system configured to vertically displace the vehicle along a guide system, and a platform for supporting an item during displacement of the vehicle. A first plurality of storage locations store inventory items at a first zone of vehicle operation and a second plurality of storage areas store inventory items at a second zone of vehicle operation. A first pick station is closer to the first storage locations than to the second storage locations, Vehicles are configured to transfer a selected item from one of the second plurality of storage locations to the first pick station or to transfer the selected item from the second plurality of storage locations to the first plurality of storage locations.

A control unit causes a transfer machine to execute a first article take-out operation by moving a locking part to a depth-direction near side with the locking part locked to a rear surface portion of a first article; and a second article position adjustment operation of moving the locking part disposed between the first article and a second article in the depth direction toward a far side to a position corresponding to a front surface portion of the second article located at a second article proper position, and the control unit is configured to, after the locking part has been disposed between the first article and the second article during execution of the first article take-out operation using the transfer machine, cause the transfer machine to execute the second article position adjustment operation, and to complete the first article take-out operation upon completion of the second article position adjustment operation.

The present invention provides a storage system (1) comprising a storage grid structure (104) having a top rail grid upon which container handling vehicles (200,300) work to store and retrieve storage containers (106) in and from storage columns (105) beneath the top rail grid, wherein the storage system comprises multiple transfer rails (110′,111′) forming a horizontal transfer rail grid (5) arranged at a level below the top rail grid, at least one transport vehicle (19) operating on the transfer rail grid, a picking/stocking station (8) for picking/stocking items between a storage container (106) and a packaging box (24), and an unloading/loading assembly (23) for unloading/loading packaging boxes containing such items, the transport vehicle (19) is arranged to move upon the transfer rail grid (5) in two perpendicular directions and comprises a carrier platform (20), wherein the transfer rail grid is arranged to allow access for the transport vehicle (19) to transport one or more packaging boxes at a time between the picking/stocking station and the unloading/loading assembly (23).

A method for turning a pinion-driven lift-robot in an intersection of rails. Moving the pinion-driven lift-robot in a first motion mode to position the pinion-driven lift-robot in a first position at the intersection. The pinion-driven lift-robot is turned over a corner of the intersection that is accessible from the first position and that includes continuous rails connecting a vertical track and a horizontal track, whereby positioning the pinion-driven lift-robot in a second position at the intersection. The pinion-driven lift-robot is moved in a second motion mode towards a designated direction.

A track arrangement (1) for self-driven carriages (2) in a storage rack arrangement (3) stores and accessed objects (4). A plurality of storage sites (5) are arranged in a rack extending over k storage levels (7). The track arrangement connects each storage level (7) with at least one interaction site (10) for processing stored objects and/or issuing objects to be stored and includes Z track levels, Z≥k, an entry point (27) on the m.sup.th track level for each interaction site (10), mϵ{1, . . . , Z}, and an exit point (28) on the n.sup.th track level for each interaction site, n∈{1, . . . , Z}. Each interaction site has: Z−m first one-way ramps (14) directed downward towards the entry point, m−1 second one-way ramps (16) directed upward towards the entry point, Z−n third one-way ramps (20) directed upward away from the exit point, and n−1 fourth one-way ramps (22) directed downward away from the exit point.