Disclosed are a dual power driving-based parallel movable shelf and an unloading apparatus thereof. The parallel movable shelf comprises: an upper transverse rod, an upper sliding block and an upper power driving apparatus being fixed on the upper transverse rod, and the upper power driving apparatus being able to control the upper sliding block to move back and forth only along the upper transverse rod; a lower transverse rod, arranged parallel to the upper transverse rod, a lower sliding block and a lower power driving apparatus being fixed on the lower transverse rod, and the lower power driving apparatus being able to control the lower sliding block to move back and forth only along the lower transverse rod; and a vertical rod, the top of the vertical rod being coupled to the upper sliding block, and the bottom of the vertical rod being coupled to the lower sliding block.

A position display method, a picking robot, and a storage medium are provided. The method includes: obtaining a picking task, and determining, based on the picking task, an item to be picked, where the picking robot includes at least one container for carrying the item to be picked, the picking robot moves between a plurality of shelves in a warehouse to transport items, the shelf includes a plurality of goods storage compartments for storing different items respectively, and the item to be picked is an item that needs to be manually picked; determining a robot position of the picking robot between the shelves and a compartment position of the goods storage compartment where the item to be picked is located; and displaying, in a preset display interface of the picking robot, a relative position relationship between the compartment position and the robot position.

An automated package Pickup and Receiving Station (PRS) (100) with autonomous ground vehicles (AGV) (18) are presented, which may be used to pick up, deliver and securely store packages (28), parcels, mail, prepared food, groceries or other items that may be placed in a tray, which may include an integrated container. A portal (10) facilitates loading of items into, and removal of items from, the PRS (100). Within the PRS (100), items (28) may be transported from source to destination on standardized trays (25), via a two-dimensional gantry (32) and an end of arm tool (22). The gantry (32) may be oriented for movement through a central corridor (21) in the PRS (100), with end of arm tool (22) adapted for pushing trays towards, or pulling trays from, either side of the gantry (32). Items may be stored on a tray (25) in internal shelving (20), or placed directly into an AGV (18), on either side of the PRS (100).

A method includes: obtaining a batch of item group definitions, each item group definition having one or more item identifiers and corresponding quantities; for each item identifier, retrieving (i) a location of a corresponding item in a facility, and (ii) a dimensional attribute of the corresponding item; based on the locations and dimensional attributes, assigning sets of the item group definitions to respective receptacle configurations, each receptacle configuration including, for each item group definition in the set, a receptacle type with a predefined capacity; monitoring availability of a plurality of transporters in the facility, each transporter having a chassis configured to support a selectable set of receptacles; and responsive to detecting that a transporter is available, selecting one of the receptacle configurations, and presenting the selected receptacle configuration via an output device, to initiate placement of receptacles onto the chassis of the transporter according to the selected receptacle configuration.

Automated mobile sortation and delivery systems may include a track or rail system positioned within a cargo area of a vehicle, a plurality of carrier robots that move along the track system, and a plurality of package or item racks that are engaged and moved by the carrier robots. The carrier robots may load and unload package racks relative to the cargo area, may sort or shuffle the package racks among a plurality of positions, and may position or place package racks at an access position to enable access to packages loaded within the package racks by associates for delivery. The automated mobile sortation and delivery systems may facilitate faster, more reliable, and more efficient delivery of packages using automated and highly organized sortation and retrieval processes, thereby reducing the time and effort associated with finding, identifying, and delivering correct packages to delivery destinations according to a delivery route or schedule.

A rack includes: a casing; M pairs of supports that are provided inside the casing so as to extend in a depth direction and arrayed at regular intervals in an up-down direction; and a lock mechanism that locks returnable containers each housed while being supported so as to be slidable along one pair of supports. The casing of the rack is divided into N rows by (N1) partition plates, with the M pairs of supports provided in each row, to be able to house a maximum of (MN) returnable containers. The lock mechanism is provided in each of the (N1) partition plates so as to extend through the partition plate and correspond to each tier, and simultaneously locks two returnable containers that are housed adjacent to each other on one side and the other side of the partition plate.

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.

A hybrid modular storage fetching system is described. In an example implementation, the system may include a warehouse execution system adapted to generate a picking schedule for picking pick-to-cart and high-density storage items, and an AGV dispatching system adapted to dispatch a cart automated guided vehicle and a modular storage fetching automated guided vehicle based on the picking schedule. The cart automated guided vehicle may be adapted autonomously transport a carton through a pick-to-cart area and to a pick-cell station. The modular storage fetching automated guided vehicle may be adapted to synchronously autonomously transport a modular storage unit containing items to be placed in the cartons from a high-density storage area to the pick-cell station.

It is possible to provide a replenishment assistance robot and a replenishment assisting system capable of assisting a worker in efficiently replenishing a product. A replenishment assistance robot includes a housing for housing a product, an RFID reader including an antenna capable of reading RFID tags attached to the product on a shelf and capable of reading an RFID tag of the product when the product is housed in the housing, a terminal configured to receive a replenishment instruction of a product on the shelf, and a mobile body containing the housing and the RFID reader and configured to move to a location where a stock of the product is arranged based on location information of the product included in the replenishment instruction.