A motorcycle transport assembly includes a lift that may be removably coupled to a hitch on a vehicle. A rack is removably coupled to the lift and the lift selectively lifts and lowers the rack. Thus, the rack may be selectively lowered onto and lifted upwardly from a support surface. The rack may support a motorcycle thereby facilitating the vehicle to transport the motorcycle when the rack is lifted upwardly from the support surface.

To decrease the off-load turn-around time of HGVs, the invention involves inter alia a system including vehicle outrigger and landing gear apparatus adapted to be completely separable from a heavy goods vehicle (HGV) vehicle it is intended to be supported on, including a goods supportable frame mountable to a HGV; and a plurality of moveable outrigger arms fitted to the frame, each outrigger arm further including a landing leg fitted thereto, each outrigger arm being moveable from a stowed to a deployed position enabling the frame to be supported on the landing legs in the deployed position; wherein movement of each outrigger arm from its stowed to its deployed position involves both translation and rotation of the arm relative to the frame; and a HGV.

An electric vehicle is in a fleet. A first electric vehicle includes one or more components that have unique identifications and a unique public key stored at the one or more components. When a message is received by the first electric vehicle, the first and second components provide a verification of their existence. The first and second components decrypt and verify their parts of the message. A first electric vehicle processor is provided. The first electric vehicle processor provides at least one of a database, an order module, a distribution module, and a loading module.

A vehicle floor structure includes a floor member that includes an opening that is open at an end corresponding to an entrance, the opening extending toward a vehicle cabin side, and a floor panel that is supported by the floor member to cover the opening and includes an open end at a position corresponding to the entrance. The floor panel is configured by sequentially arranging and integrating unit panels in a width direction with a direction parallel to the open end serving as a longitudinal direction of the unit panels.

Described herein are cargo handling systems for loading, transporting, and unloading cargo from autonomously delivery devices. In some embodiments, the cargo handling system includes: a system processing unit for controlling operations of the cargo handling system; and one or more modular racks. Each rack includes a rack processing unit, a frame, and one or more moveable arm sets. Further, each rack is configured to store, dock, and undock one or more modular cargo containers according to received signals from the system processing unit. In some embodiments, the system processing unit transmits one of: a docking signal and an undocking signal to dock or undock, respectively, the identified modular cargo container. In some embodiments, the system further includes a shuttle for transporting, at least in part, a modular cargo container in the modular racks.

Systems and methods are provided for determining and correcting autonomous transport imbalances. A transport vehicle operates over a route. A fixture plate is coupled to the transport vehicle by a joint to carry a payload. A sensor determines a position of the joint. A controller modifies the operation of the transport vehicle in response to a change in the position of the joint to correct imbalances.

Apparatuses, methods and systems are provided for forming an autonomous vehicle of an upper body unit configured to consume space in an upward direction to minimize a horizontal footprint and enable a stacking of vehicle components on top of each other in the upward direction; a lower chassis unit configured to oppose the upper body unit and include a structure for supporting the modular unit with prismatic cross members to configure to a range of module unit widths, the lower chassis unit including: a set of structural rails on either side of the lower chassis unit configured in a rigid frame unit with longitudinal members wherein the structural rails can be attached to another corresponding set of structural rails; a plurality of compartment units including: front-compartment, rear-compartment, and mid-compartment units configured to be attached on either side of the lower chassis unit for the forming of the autonomous vehicle.

A container for transporting material including a main body and a liner disposed within the interior space of the main body. A gap is provided between a perimeter of the main body and a perimeter of the liner to allow the liner to move with respect to the main body. Also, a container for transporting material including a main body defining an interior space with a lift gate pivotably attached at an open end of the main body. When the container is placed on a transportation vehicle and the main body is raised, the engagement of a link between the lift gate and the vehicle automatically transitions the lift gate from a position in which the open end of the main body is covered by the lift gate to a position in which the open end of the main body is not covered by the lift gate.

A camper system. The camper system may include a kitchen system having a frame configured to move between an indoor position to an outdoor position and guide rails and slides that are slidably connected to one another and coupled to the frame in order to facilitate the transition of the frame from the indoor position to the outdoor position. The camper system may include an adjustable lounge system having a table configured to extend partially outside a window and a lounge with a substantially vertical back hingedly connected to a horizontal seat configured to move between a vertical position and a horizontal position wherein the back is the same height as the seat. The lounge may be moved forward and backward within the camper.

Various examples of arrangements and methods are provided for loading and unloading first and second load units carried by a vehicle. A landing device is arranged between a first end of the first load unit and a second end of the second load unit so that a first portion of the landing device is supported to the first end of the first load unit and a second portion of the landing device is supported to the second end of the second load unit. The landing device can move the first end of the first load unit into a lower level than the second end of the second load unit after the first end of the first load unit is moved so that it passes the second end of the second load unit.