An automatic warehouse control system and method are provided. The system comprises a goods transport module, an information input module, a data storage module, a data retrieval module, and a drive control module. The goods transport module moves goods containers. The information input module is configured to input goods information to form goods warehousing data. The data storage module stores the goods warehousing data. The data retrieval module retrieves goods warehousing data and sends a retrieved result to the drive control module according to information of to-be-picked goods. The drive control module controls operation of the goods transport module to transport a goods container containing the to-be-picked goods to the goods-picking location according to the retrieved result. The technical solution is easy to implement, has a low cost, and allows one warehouse operator to manage multiple racks at the same time, which can significantly reduce hardware and time cost.

An area storage for storing vehicle bodies, the longitudinal extension of which equals at least one and a half times the transverse extension thereof, having a storage area having at least two storage spaces and two associated vehicle body receptacles, wherein the storage area is designed such that vehicle bodies can be stored on the storage area in a plane on the at least two storage spaces on one of the vehicle body receptacles in each case, at least one multi-track industrial vehicle, which can be coupled to the vehicle body receptacle. The industrial vehicle is designed for omnidirectional travel, such that the direction of conveyance can be chosen independently of the orientation of the industrial vehicle and the industrial vehicle having the coupled vehicle body receptacle can carry out a conveyance direction change without changing the relative orientation of the vehicle body receptacle and industrial vehicle. A method for conveying vehicle body receptacles is also disclosed.

An area storage for storing vehicle bodies, the longitudinal extension of which equals at least one and a half times the transverse extension thereof, having a storage area having at least two storage spaces and two associated vehicle body receptacles, wherein the storage area is designed such that vehicle bodies can be stored on the storage area in a plane on the at least two storage spaces on one of the vehicle body receptacles in each case, at least one multi-track industrial vehicle, which can be coupled to the vehicle body receptacle. The industrial vehicle is designed for omnidirectional travel, such that the direction of conveyance can be chosen independently of the orientation of the industrial vehicle and the industrial vehicle having the coupled vehicle body receptacle can carry out a conveyance direction change without changing the relative orientation of the vehicle body receptacle and industrial vehicle. A method for conveying vehicle body receptacles is also disclosed.

In an automated warehouse, if a controller receives an instruction to retreat a first carrier and if the first carrier is holding an article or if an article is housed in a housing shelf corresponding to an isolation region that is a retreat destination, the controller causes the first carrier to carry the article to a housing shelf to and from which a second carrier is able to transfer an article, then causes the first carrier to retreat, and then drives the second carrier within a range of a track except for the isolation region. When it is detected that one of first doors corresponding to the isolation region has been opened, the controller continues driving the second carrier.

In an automated warehouse, if a controller receives an instruction to retreat a first carrier and if the first carrier is holding an article or if an article is housed in a housing shelf corresponding to an isolation region that is a retreat destination, the controller causes the first carrier to carry the article to a housing shelf to and from which a second carrier is able to transfer an article, then causes the first carrier to retreat, and then drives the second carrier within a range of a track except for the isolation region. When it is detected that one of first doors corresponding to the isolation region has been opened, the controller continues driving the second carrier.

The technical field of intelligent warehousing is related, and an intelligent warehousing system, a processing terminal, a warehouse robot, and an intelligent warehousing method are disclosed. Where the intelligent warehousing system (100) includes: a warehouse robot (10) and a material fetching device (20); the warehouse robot includes a first warehouse robot (11) and/or a second warehouse robot (12); the first warehouse robot is configured to receive a first scheduling instruction, and handle a material box to a first target position according to the first scheduling instruction; the second warehouse robot is configured to receive a second scheduling instruction, and handle a portable shelf to a second target position according to the second scheduling instruction; and the material fetching device is configured to receive a material fetching instruction, and fetch a material from the material box and/or the portable shelf according to the material fetching instruction.

Methods and systems for managing temporary storage in warehouses are disclosed herein. An example method includes receiving a first electronic notification that items of a shipment are to be stored in temporary locations in a warehouse; in response to the first notification, automatically redirecting location information determined electronically based on asset tags affixed to the items from a warehouse management system to a temporary storage management system as the items are stored in the temporary locations; receiving a second electronic notification that the items are to be moved from the temporary locations to final locations; and in response to the second notification, automatically communicating the redirected location information to enable the warehouse worker to locate the items at the temporary locations based on the redirected location information and store them at the final locations, the final locations identified for the warehouse worker by the warehouse management system.

Methods and systems for managing temporary storage in warehouses are disclosed herein. An example method includes receiving a first electronic notification that items of a shipment are to be stored in temporary locations in a warehouse; in response to the first notification, automatically redirecting location information determined electronically based on asset tags affixed to the items from a warehouse management system to a temporary storage management system as the items are stored in the temporary locations; receiving a second electronic notification that the items are to be moved from the temporary locations to final locations; and in response to the second notification, automatically communicating the redirected location information to enable the warehouse worker to locate the items at the temporary locations based on the redirected location information and store them at the final locations, the final locations identified for the warehouse worker by the warehouse management system.

A system of warehouse racks placed perpendicularly to a working aisle. After selecting a place of storage of a given product, at least one rack is moved to the working aisle. The goods are placed or removed from the indicated place in the rack, and then the rack is moved to an initial position. The movement of the rack to the working aisle and its return to its initial position is made by movable, shared platform moving under at least one row of racks that is perpendicular to the direction of movement of the rack and parallel to the working aisle. The system includes a drive system, a power supply system, at least one running gear, a rack lifting system and a positioning system extending or retracting the rack. During movement to the working aisle and return to the initial position, the rack is lifted above the ground surface by the positioning system of the shared platform.

Systems, methods, and computer-readable media are disclosed for automated item sortation and container handling. In one embodiment, an example method may include determining, by a controller, a first item identifier of a first item at an induction portion of a sortation system, determining an order identifier associated with the first item identifier, and determining a first container associated with the order identifier. The method may include causing a first mobile carrier unit to receive the item, and causing the first mobile carrier unit to deliver the first item to the first container.