A loading system for laterally loading and unloading an upper body structure onto and from a vehicle platform includes loading gear rails mounted on respective lengthwise ends of the vehicle platform, the loading gear rails configured to jointly extend and retract from the vehicle platform by moving in a lateral direction of the vehicle platform, each loading gear rail having first gear teeth gear-engaging with a correspondingly formed platform gear wheel rotatably mounted on the vehicle platform and second gear teeth configured to engage a correspondingly formed upper body gear wheel at a respective lengthwise end of the upper body structure, wherein the platform gear wheel actuates lateral movement of the loading gear rails to engage the upper body structure with the loading gear rails at the upper body gear wheels and to load the engaged upper body structure onto the vehicle platform or to load and unload the engaged upper body structure from the vehicle platform.

A deployment mechanism and a delivery container enabling unattended delivery of cargo by a vehicle navigating autonomously on both vehicle lanes and pedestrian ways. A trailer for an autonomous vehicle for hauling additional cargo and power supplies. A method for delivering and picking up goods using delivery trucks, autonomous vehicles, and trailers. The deployment mechanism can include a crane, a robot arm, a forklift, straps, and sails. The delivery container can include visible, partly visible, or hidden security features and grasping features, and can be foldable and stackable. The trailer can include a 4-bar linkage, the 4-bar linkage enabling consistent pitch between the trailer cargo and a cargo hold of the towing vehicle. The trailer wheels are decoupled from the 4-bar linkage, connected by swing arms and possible shock absorbers. The trailer can buffer fore/aft movement of the trailer.

An article management system utilizes an electric cart which may autonomously move, automatically and easily managing articles and ensuring the convenience of delivery service by the automation of article delivery.

Package sorting systems and methods of use are disclosed herein. An example system includes a platform of a vehicle, where the platform is arranged as a grid having a plurality of slots (including an open slot and a target slot). A plurality of slabs can be placed into the grid except for in the open slot. A slab moving assembly is used, to move the slabs in order to place a selected slab into the target slot on the platform.

A drawer for storage is positioned within a wheel well of a vehicle. A bottom panel of the drawer has an arcuate or faceted shape to accommodate the wheel over which the drawer sits. The drawer is movable between a closed and an open position on slides received within guide rails mounted either directly on the vehicle or on panels of a cabinet which encloses the drawer, the cabinet being mounted on the vehicle.

Embodiments of the present disclosure provide a transport vehicle and an installation method for a case of a mobile power generation system. The transport vehicle includes: a chassis and a lifting mechanism assembly located on the chassis. The lifting mechanism assembly includes: a turning frame hinged to the chassis at a hinged position of the chassis, at least one turning hydraulic cylinder connected to the turning frame and the chassis, and a connecting frame configured to be detachably connected to the case. In the main beam, the first body portion is located between the hinged position and the second body portion, and a third plane in which a surface of the second body portion facing towards the turning frame is located is farther away from the connecting frame than the first plane.

Described herein are systems and methods for using different truck types for deliveries. A package is initially loaded into a specially configured cargo container that can be transported either on a primary truck or a secondary truck. A secondary truck is smaller than a primary truck and is configured to transport fewer cargo containers than the primary truck. An initial leg of the overall delivery (e.g., from a warehouse to a transfer point) is performed using a primary truck. The cargo container is then transferred to a secondary truck, which completes the delivery. Empty cargo containers can be transferred back to a primary truck, e.g., in a stacked or folded manner, for transporting back to the warehouse. The configurations of primary and secondary trucks are such that these transfers can occur at any location (e.g., a parking lot) with minimal human involvement.

Described herein are systems and methods for using different truck types for deliveries. A package is initially loaded into a specially configured cargo container that can be transported either on a primary truck or a secondary truck. A secondary truck is smaller than a primary truck and is configured to transport fewer cargo containers than the primary truck. An initial leg of the overall delivery (e.g., from a warehouse to a transfer point) is performed using a primary truck. The cargo container is then transferred to a secondary truck, which completes the delivery. Empty cargo containers can be transferred back to a primary truck, e.g., in a stacked or folded manner, for transporting back to the warehouse. The configurations of primary and secondary trucks are such that these transfers can occur at any location (e.g., a parking lot) with minimal human involvement.

A method and an arrangement for optimizing load position in relation to a transportation vehicle, comprising a platform arranged to the transportation vehicle for receiving a load; an actuating device for moving the platform in relation to the transportation vehicle; a sensing device configured to generate a vehicle sensing signal and/or a non-vehicle sensing signal; a controlling device configured to receive at least one of the vehicle sensing signal and the non-vehicle sensing signal; generate controlling commands based on the received at least one of the vehicle sensing signal and the non-vehicle sensing signal; and transmit the controlling commands to the actuating device; wherein the actuating device is configured to receive the controlling commands and to move the platform in relation to the transportation vehicle based on the controlling commands.

A container deck of a trailer includes a front mounting floor, a central elevating floor, a rear mounting floor and a rear elevating floor, the central elevating floor is capable of loading and unloading the air container from the left or right side of the trailer vehicle body, the rear elevating floor is capable of loading and unloading the air container from any of the left and right sides and rear end, the front and rear mounting floors are provided with a roller conveyor for movably placing the container and a roller conveyor and a fixed side guide for slidably engaged the container, the central elevating floor is rotatable, the rear elevating floor includes a turntable and a ball conveyor, the central elevating floor and the rear elevating floor are capable to move up and down a single container.