Some embodiments are directed to a method for retrieving garments within an automatic warehouse. The method may include maintaining sets of garments in enclosures, the enclosures are positioned on shelfs of the automatic warehouse. Each set of garments is located within an enclosure of the enclosures, and is hung on hangers located within the enclosure; accessing a selected enclosure of the enclosures, by a first robot. The selected enclosure encloses a garment of interest; obtaining the selected enclosure by the first robot; and providing the enclosure to an interface point within the automatic warehouse, by the first robot.

An object processing system is disclosed that includes a plurality of track sections, and a plurality of remotely actuatable carriers for controlled movement along at least portions of the plurality of track sections, wherein each of the remotely controllable carriers is adapted to support and transport an object processing bin.

The present invention makes an instruction for causing a transport robot to carry out transport easier for a person to understand. A transport system (1) is such that an address indicating a transport destination or a transport source is represented by a tree structure including a node indicating loading locations and a node indicating equipment to which the loading locations are provided, and when the address of the transport destination indicates equipment, a transport robot (20) sequentially loads objects to be transported in accordance with a preset loading priority order in loading locations where no objects to be transported have been loaded, from among the loading locations belonging to that equipment.

Provided is a relay goods picking system, the system includes: a plurality of carrying robots, a manual picking area, auxiliary pickup tools for manual goods picking which store goods for manual picking, a robot picking inventory container area provided with a plurality of inventory containers used for storing goods and being carried by the plurality of carrying robots, operating positions and a control system capable of communicating with the plurality of carrying robots and manual picking persons. For a mixed order which involves both goods in the manual picking area and goods in the robot picking rack area, under control of the control system, a person-to-goods picking mode and a goods-to-person picking mode are used to complete the goods picking.

A recycling kiosk for vaping devices includes a digital link for accessing digital data from a vaping device; at least two storing compartments for storing of vaping devices of different conditions; wherein the recycling kiosk is arranged to store vaping devices in the respective storing compartment based on the digital data accessed from the vaping device. A method for accepting a vaping device by a recycling kiosk is also provided.

A system includes location indicators, a central computing system, and a mobile scanning device. The location indicators transmit location signals and are arranged in a store that includes stocked items. The central computing system stores an item association table that maps location values to the stocked items. The location values indicate locations of the stocked items in the store. The mobile scanning device receives ordered items from the central computing system, detects location signal(s), and determines a first location value based on the detected location signal(s). The mobile scanning device arranges the ordered items on a display based on the first location value, scans a first ordered item, and transmits data to the central computing system indicating that the first ordered item is associated with the first location value. The central computing system updates the item association table based on the data.

A computer system for optimizing node and edge selections within a digital graph model accesses a digital graph model of a physical warehouse location. The digital graph model comprises information indicating a location of multiple specific items of inventory among shelves in the physical warehouse location. The computer system identifies a set of orders that each comprise one or more items and an order priority. The computer system then maps each item in each order selected from the set or orders to the multiple nodes within the digital graph model. The computer system identifies a ranking node from the multiple nodes. The computer system then traverses one or more edges that extend from the ranking node to identify a shortest path within the digital graph model to fill a digital model of a picking cart above a packing threshold level.

A system includes a shelving unit, a sensor and a processor. The shelving unit includes a pocket. The sensor is associated with the pocket and is configured to obtain a parameter indicative of a weight of the pocket. The processor configured to execute instructions stored in a nontransitory computer-readable medium. The instructions include obtaining the parameter indicative of the weight of the pocket from the sensor, determining the weight of the pocket based on the parameter, comparing the weight of the pocket to a predetermined value, generating a paint chip order that includes a request in response to the weight of the pocket being below the predetermined value, and transmitting the paint chip order to a computing system.

The present disclosure provides a method and apparatus for controlling a warehousing system, a guard door, and a warehousing system. The method includes: obtaining a door-opening-request signal of a guard door, and determining a target region corresponding to the guard door; determining that a state of a first goods-carrying tool in the target region is a non-operating state; and controlling a state of the guard door to be an open state. The safety of the target region where a user enters is ensured. In addition, the state of the goods-carrying tool in the target region corresponding to the guard door is controlled to be a non-operating state and a goods-carrying tool in a non-target region is kept to operate normally, and therefore, when compared with the related art of stopping all goods-carrying tools, the warehousing efficiency is improved and a hardware loss caused to the goods-carrying tool due to repeated starting and stopping is reduced.

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.