An automated storage and retrieval system includes a rail system, at least one vehicle operating on the rail system, at least one charging station on or at the perimeter of the rail system, and a control system. The rail system includes a first set of parallel rails extending in a first direction and a second set of parallel rails extending in second direction. The second direction is perpendicular to the first direction. The at least one vehicle includes at least one power storage source, and a local controller adapted to control movements of the at least one vehicle. The at least one charging station is adapted to be electrically connected with the at least one power storage source of the at least one vehicle. The control system is adapted to communicate with the local controller in the at least one vehicle and the at least one charging station. The control system is further adapted to, upon detecting a failure with the charging station, instruct the at least one vehicle to move to the at least one charging station such that the at least one power storage source of the vehicle electrically connects to the at least one charging station. The at least one charging station is further adapted to, transmit a charger diagnostic to the control system using power from the at least one power storage source of the at least one vehicle.

A pack wall carton selection and replenishment system comprising: a delivery cart with a delivery cart controller configured to receive information representing a replenishment shipping carton to be retrieved from a shipping carton supply area and delivered to a pack wall, provide for retrieving one or more shipping cartons from the shipping carton supply area, actuate a cart indicator assembly to identify a cart partition where to place the retrieved shipping cartons on the delivery cart, actuate a delivery cart indicator assembly to identify the replenishment shipping carton to be placed on the pack wall; and, a pack wall controller in communication with the delivery cart controller configured to receive an order item information, actuate a first pack wall indicator assembly to indicate a desired shipping carton to be used for packing an items represented by the order item information.

A method for managing inventory carriers using mobile robotic units (MRUs) in a pod that is configured to receive online orders at a replenishment station for pickup by customers at a delivery station includes receiving, by an MRU, instructions that identify a first inventory carrier, moving the MRU to a location of the identified inventory carrier, and using the MRU to transport the identified inventory carrier to the replenishment station for pickup by a delivery vehicle.

A variety of vehicle-based and warehouse-based solutions are provided to increase the adaptability, utility, and efficiency of materials handling vehicles in the warehouse environment, such as a materials handling vehicle comprising a hand-held drive unit comprising a user interface and an operational command generator responsive to the user interface. The hand-held drive unit is configured to send operational commands generated in response to user input at the user interface to the vehicular controller(s) to control operational functions of the traction control unit, the braking system, the steering assembly, the mast assembly, the picking attachment, or combinations thereof.

A system-directed single line pick batching is described. In an example implementation, the system may receive data describing a set of orders including SKU identifiers associated with items in the orders, identify an eligible cart, and assign a location to a task queue of the cart based on the location being associated with a particular SKU identifier. In some instances, the location or SKU identifier may be determined based on an order with a certain quantity of different SKU identifiers. In some instances, the system may navigate the cart to the location and instruct the item to be picked from the location. In response to completion of the pick of the item, the system may navigate the cart to an end point.

Systems and methods for autonomous delivery management are disclosed. In various embodiments, the system includes one or more processors and a memory storing instructions which, when executed by the processor(s), cause the autonomous delivery management system to provide a user interface for a customer to enter subscription information, receive subscription information from the user interface where the subscription information includes an item and a time interval for regularly delivering the item to the customer, store the subscription information, determine a handling itinerary for the item that includes delivery of the item in compliance with the time interval, and communicate instructions to an autonomous vehicle based on the handling itinerary.

A workstation receives bots carrying order totes and bots carrying product totes for transfer of goods from the product totes to the order totes. The workstation comprises a robot for automated transfer of goods between the product and order totes, but may also have a station for an operator to perform manual transfer. Cameras may be provided to capture images of the product and/or order totes to identify contents of totes and to identify positions where goods are to be picked from the product totes and placed into the order totes.

The present invention relates to a sorting robot and a sorting method. The sorting method is applicable to the foregoing sorting robot, where the sorting robot is configured to deliver specific goods to be sorted to a specific sorting position, and a sorting mechanism carrying the specific goods to be sorted corresponds to the specific sorting position. The sorting method includes: S130: the sorting mechanism receiving goods to be sorted; S140: the sorting mechanism being raised or lowered to a height corresponding to the sorting position under drive of a lifting mechanism; and S160: the sorting mechanism performing an action to deliver the goods to be sorted that is placed on the sorting mechanism to the corresponding sorting position.

A method and system for picking or put-away within a logistics facility. The system includes a central server and at least one mobile manipulation robot. The central server is configured to communicate with the robots to send and receive picking data which includes a unique identification for each item to be picked, a location within the logistics facility of the items to be picked, and a route for the robot to take within the logistics facility. The robots can then autonomously navigate and position themselves within the logistics facility by recognition of landmarks by at least one of a plurality of sensors. The sensors also provide signals related to detection, identification, and location of a item to be picked or put-away, and processors on the robots analyze the sensor information to generate movements of a unique articulated arm and end effector on the robot to pick or put-away the item.

Cargo receptacle including a mount and a flexible member expandable and collapsible in height, wherein the flexible member in an at least partially expanded state bounds a storage volume for holding the cargo, and wherein the mount is self-supporting and comprises a frame with a rim, the rim being suitable for mounting the cargo receptacle and a system of laterally spaced-apart tracks.