A delivery control system includes a communication device configured to receive an image of a product from a computing device of a customer, at least one processor, and a memory storing instructions which, when executed by the at least one processor, cause the delivery control system to perform an image recognition process on the image to identify at least one product based on the image, transmit the identified at least one product to the computing device via the communication device, receive from the computing device a product selected by the customer from among the identified at least one product, and instruct an robot vehicle to deliver the selected product to the customer.

According to one aspect, a platform for providing at least one item to a customer is disclosed. The platform includes an autonomous, semi-autonomous, or fully autonomous vehicle that includes at least one compartment configured to contain a first item ordered by the customer and to contain a second item not ordered by the customer. The platform further includes an application including an ordering module configured to obtain an order from the customer that includes the first item, and a release detection module configured to determine when the first item has been removed from the at least one compartment and configured to determine when the second item has been removed from the at least one compartment. In one embodiment, the second item is predicted using a machine learning algorithm.

Provided herein is an autonomous or semi-autonomous vehicle fleet comprising a plurality of autonomous or semi-autonomous vehicles for delivering a food or beverage item to a customer. The autonomous vehicle herein may comprise of storage units that are easily configured to effectively and efficiently carry different types of food or beverage items, including a temperature control system configured to maintain a target unit temperature for different types of food or beverage items.

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 picking attachment is secured to a fork carriage assembly and comprising an X-Y-Z-Ψ positioner to engage and disengage a target tote such that movement of the picking attachment along a Z axis by the X-Y-Z-Ψ positioner is independent of movement of the fork carriage assembly along the vertical axis Z′ by the mast assembly and mast assembly control unit. The fork carriage assembly may comprise a mobile storage cart support platform defined by one or more cart lifting forks, and an anti-rock cart engagement mechanism configured to engage a mobile storage cart supported by the cart lifting forks.

A picking system may provide a fast, flexible pick cart solution that may be deployed in warehouses or distribution centers to enable users to pick multiple items to put into a plurality of order bins (or carts) with high speed and accuracy to create completed orders ready for packing and shipping. Hardware and software may be bundled on the carts which may shorten training times, simplify integration, and allow for adjustment of carts based on product/items needs, all while improving picking efficiency. The picking system may include a cloud-based computer platform that may control light and displays in the lighted pick shelves that direct users to place a specified quantity of items in specific order bins. Users in remote locations may be linked to the cloud-based computer platform that may control lighted pick shelves in the users' locations.

A transfer station configured to handle cargo receptacles, wherein the transfer station includes: a transfer device that includes at least one holder component configured to hold and release cargo receptacles, at least one platform configured to support the cargo receptacles, at least one transfer device frame extending in a vertical direction, in which the at least one platform is mounted in a vertically displaceable manner, the transfer device frame includes at least one lifting drive component configured to vertically displace the platform, a base member on which the transfer device frame is mounted, an electronic circuit configured to control the operation of at least one component of the transfer station.

A conveyance robot system according to the present disclosure includes an intrusion detection sensor that detects an intrusion of an object into the arm opening, and a distance sensor that measures a clearance distance indicating a distance between an arm entry/exit surface and a shelf, the arm entry/exit surface being a surface of the conveyance robot in which the arm opening is provided from among surfaces of the conveyance robot 1 constituting the safety cover, and the object being stored in the shelf. The distance sensor is disposed at a fixed height of the shelf in a horizontal direction and at a height of the shelf corresponding to a part to be measured.

A system and method for automated loading of delivery vehicles using automated guided vehicles (“AGV”s) is described. In an example implementation, a loading coordination engine may assign a location on a mobile cart to an item and generate a task list including instructions to a first and a second AGV to position the item on the mobile cart based on the assigned location and to transport the mobile cart into a delivery vehicle. The first AGV may transport the item from an item loading area to a point proximate to the assigned location on the mobile cart and place the item at the assigned location based on the task list. The second AGV may transport the mobile cart from a cart loading zone into the delivery vehicle based on the task list and, in some instances, secure the mobile cart to the delivery vehicle based on the task list.

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.

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.