A delivery system for delivery items includes sidewalls that define a cargo space. A retention assembly is operably coupled to the sidewalls. The retention assembly includes a housing and a retention feature that is operably coupled to the housing. The retention feature has an attachment portion and a control unit that is operably coupled with the retention feature. A controller is communicatively coupled to the control unit of the retention assembly, and a memory storage is communicatively coupled with the controller.

The disclosure is generally directed to systems and methods for a reconfigurable on-board package sorting system for a delivery vehicle including an enclosed storage compartment with a horizontal plane, a plurality of bins for holding packages, each bin including a computer readable identifier, a set of correlated conveyor belts on each horizontal plane, the correlated conveyors belts sized as a function of the bins, including at conveyor belts linearly oriented on the horizontal plane, mixing conveyors, each oriented adjacent to each convey belt to provide directional transition to a next conveyor belt, wherein the correlated conveyor belts provide directional movement of the bins in a loop on the horizontal plane by selective rotation of each conveyor belt, and a computer including a processor and memory to receive data from each identifier, the processor including instructions to: identify a location of bin and direct the operation of the correlated conveyor belts.

An AV receives a delivery request made by a user. The AV navigates to the user's location. The AV's onboard controller determines that the AV has arrived at the location. The onboard controller then commands the AV's motor to pause motion. The onboard controller provides the user an access to a delivery assembly in the AV. The onboard controller or the delivery assembly detects, by using sensors in the delivery assembly, whether an item has been removed from or placed into the container. Subsequent to detecting that the item has been removed from or placed into the container, the onboard controller commands the AV's motor to resume motion. The onboard controller or delivery assembly may also control a movable element in the container to allow the user to load or unload the item from a safe spot or control a divider in the container to protect the user's privacy.

Loading, securing, transporting, and/or depositing objects as well as systems, methods, and apparatuses for the same, including those that operate in automated or semi-automated fashion, are disclosed herein. In one embodiment, a mobile robotic platform is provided. The mobile robotic platform is designed to receive, transport, and deposit objects at desired destinations. In another embodiment, a flat transport surface, e.g., a pallet, is provided. The flat transport surface is designed to facilitate efficient loading, transport, and deposit of objects, e.g., between automated or semi-automated handling systems, in one aspect. In another embodiment, a system for handling objects is provided. The system is designed to support automated or semi-automated loading and/or unloading of objects, e.g., onto or from a mobile robotic platform, and may be implemented in a vehicle, in one aspect.

A delivery robot control apparatus for controlling a delivery robot to unload an object and a method thereof are disclosed. A camera is provided in the delivery robot having an internal loading space for one or more floors and obtains an image including a door module which is provided in the delivery robot and connected to a frame forming the internal loading space. The controller determines up and low positions of the door module based on the image, and controls a first motor to move the door module to a target position based on the determined up or low position of the door module.

A delivery vehicle having a cargo area and a package positioning system that includes a moveable panel. The moveable panel may move a package in the cargo area. In at least one configuration, the panel may be mounted to first and second cassettes that are moveably disposed in first and second rails.

Methods are described that perform a dispatched consumer-to-store return or swap logistics operation for an item being replaced using a modular autonomous bot apparatus assembly and a dispatch server. The method begins with receiving a return operation dispatch command that includes identifier information, transport parameters, and designated pickup information for the item being replaced/returned, along with authentication information related to an authorized supplier of the item being replaced. Modular components of the bot apparatus are verified to be compatible with the dispatched logistics operation. The MAM then autonomously causes the bot apparatus to move to the designated pickup location, notifies the authorized supplier of an approaching pickup, receives supplier authorization input to permissively allow access to a payload area within the bot apparatus, monitors loading as the item being replaced is received along with return documentation, and then autonomously causes movement of the bot apparatus back to the origin location.

Described herein are various systems and processes for vehicles for delivery of real-time, on-demand orders for perishable goods, and operations thereof. The vehicles may each include a plurality of different modules that couple to a chassis. The modules may include battery modules, drive modules, cargo modules, and other modules. Each drive module may include wheels and motors and steering mechanisms that control the wheels. A plurality of such modules may be disposed on the chassis. The modules may be disposed on different portions of the chassis and be given different operational commands accordingly. Furthermore, operation of the vehicle may be adjusted based on the cargo carried by the vehicle.

A shelving system includes side members that each define a first channel having a slide disposed therein. A cross member extends between and connects the slides. The cross member defines a second channel having a guide member disposed therein. The guide member defines a third channel and a flange. A container includes side walls having a rail. One of the rails is movably disposed in the third channel. The rails include a first locking element and a second locking element. The handle includes a third locking element that engages the first locking element. The handle is movable between a first position in which the second locking element engages the flange and the container is fixed relative to the guide member and a second position in which the second locking element is spaced apart from the flange and the container can translate relative to the guide member.

A system for delivering an article from a first location to a second location with a robot having a closeable transport container for housing the article during transport. A closeable recipient container is provided at the second location for receiving the article. At least one computer configured to navigate the robot over an outdoor transportation network between locations is provided. The robot has a robot article transport mechanism controlled by the at least one computer for removing the article from the transport container and the recipient container has a recipient article transport mechanism for moving the article inside the recipient container.