A product order fulfillment system includes multiple decks arrayed at different levels and defining multilevel decks, at least one autonomous transport vehicle on each of the decks, and configured for holding and transporting a pickface on each deck, at least one lift, traversing and connecting more than one level of the decks, and arranged for lifting and lowering the pickface from the decks, and at least one pickface transfer station on each deck interfacing between the transport vehicle and the at least one lift to effect transfer of the pickface between the transport vehicle and the at least one lift, the at least one lift defines a fulfillment stream of mixed case pickfaces outbound from the multilevel decks to a load fill, at least one stream of the fulfillment stream has an ordered sequence of streaming pickfaces wherein the ordered sequence of streaming pickfaces is based on another fulfilment stream.

A fire extinguishing robotic service device is described for use with a robotic picking system grid. The fire extinguishing robotic service device is configured for driving to any location on the grid in order to extinguish a fire. The service device may also be provided with a camera sensor to locate the fire.

A storage system for storing product items includes a grid structure and a number of first storage bins configured to be stored in vertical stacks in the grid structure. Each first storage bin is configured to contain at least one product item. A vehicle is arranged to move horizontally at the top level of the grid structure, and further arranged to pick up, carry, and place the first storage bins at desired locations within the grid structure. The storage system further includes a robot device that includes a movable arm with a picking mechanism in one end thereof. The robot device is configured to move a storage item between a first location and a second location by means of its picking mechanism. The first location is the location of a first storage bin stored in the storage grid.

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.

Various embodiments relate to magnetically moveable displacement devices or robotic devices. Particular embodiments provide systems and corresponding methods for magnetically moving multiple movable robots relative to one or more working surfaces of respective one or more work bodies, and for moving robots between the one or more work bodies via transfer devices. Robots can carry one or more objects among different locations, manipulate carried objects, and/or interact with their surroundings for particular functionality including but not limited to assembly, packaging, inspection, 3D printing, test, laboratory automation, etc. A mechanical link may be mounted on planar motion units such as said robots.

A sensor-based item transport system, and a method therefore are described. The system includes, for example, a cart station, within a restricted area including a plurality of automated drive. A light curtain is adjacent to the cart station. A first sensor and a second sensor are spaced apart from the first sensor within the cart station. A first mode associated with the light curtain is maintained causing an alarm system associated with the light curtain to remain armed. The first mode is caused to change to a second mode associated with the light curtain, the second mode causing the alarm system to be muted, based at least in part on the identity of the cart. The identity is determined based at least in part on one or more signals received from the first sensor and the second sensor.

A stacking storage arrangement having multiple container receiving spaces that are arranged in multiple rows and columns, wherein a loading space in which at least one loading vehicle can be moved is arranged below the container receiving spaces. The operation of a stacking storage arrangement of this type is configured to be economical. For this purpose, a transverse transport device is provided with which the loading vehicle can be moved between positions that are respectively assigned to a row.

Vehicle (S), provided with a loading space (L), which comprises a movement device (M1), comprising: a support body (F); a barrier (1), associated with the support body (F) and movable between an active position, in which it protrudes from the support body (F) to interact with an object to be displaced, and an inactive position, in which it is not able to interact with an object to be displaced: a first connecting rod (10), associated with the support body (1) rotatably about a first axis of rotation (X1): a second connecting rod (20), associated with the support body (1) rotatably about a second axis of rotation (X2) parallel to the first axis of rotation (X1); an arm (30), rotatably connected to the first connecting rod (10) and the second connecting rod (20) at a third axis of rotation (X3) and at a fourth axis of rotation (X4) rotatably parallel to the first and the second axis of rotation (X1,×2); wherein the distance between the first axis of rotation (X1) and the third axis of rotation (X3) is equal to the distance between the second axis of rotation (X2) and the fourth axis of rotation (X4).

A picking system is configured to pick items from, and put items into, storage containers. The picking system includes a picking station. The picking station includes: a picking system controller configured to receive product orders from a warehouse management system; at least one container contents handling position; a camera configured to produce an image of contents of a storage container; an image processing system in communication with the camera for processing the image produced by the camera in order to identify a position of a specific item in the storage container, and a robotic picking device. The image processing system is further in communication with a picking system controller and is adapted to inform the picking system controller of the position of the specific item. The robotic picking device is in communication with the picking system controller and is configured to, under guidance from the picking system controller, to pick said specific item from said position in the storage container. The camera and the robotic picking device are arranged to operate, at any one instance, on different containers such that the camera is producing an image and the image processing system is processing the produced image of the contents of a storage container in a first product order while the robotic picking device is handling a second storage container on the basis of an earlier image that has been produced by the camera and processed by the image processing system.

A dynamic routing method and apparatus for an Overhead Hoist Transport (OHT) system are disclosed. The present disclosure in some embodiments provides a dynamic routing method for an OHT system, including generating a Q table of records of at least one Q value which is a time for a vehicle to move through an edge between two adjacent nodes to a node other than the two adjacent nodes, measuring a transit time of the vehicle when assigned a destination node and passing a transit edge between a current node and next node, extracting target edges to be updated according to the transit time from a plurality of edges, and differentially updating Q values for the target edges according to distances to the transit edge partially based on the transit time, the Q values for the target edges being time values for the vehicle to move through the target edges to the destination node.