A loading/unloading system for an associated truck bed includes first and second laterally spaced rails configured for re) receipt in the associated truck bed. First and second support leg assemblies are operatively associated with the first and second rails, respectively. First and second motors are received on the first and second leg assemblies, respectively, and are configured to selectively raise and lower the first and second rails. A sensor assembly is mounted on the rails to monitor the position of the first rail relative to the second rail. The sensor assembly is interconnected to the first and second motors for maintaining the rails at the same height relative to one another.

A liftgate in accordance with the present disclosure includes a lift mechanism and a moveable load platform. The load platform includes a proximal deck section, a distal deck section, and a center deck section positioned between the proximal deck section and the distal deck section. The load platform is selectively vertically movable between a lowered position and a raised position. The proximal deck section, center deck section, and distal deck section are pivotally coupled to one another such that the load platform is selectively moveable between an extended-operational position, wherein all of the deck sections are located substantially coplanar with one another for supporting cargo, and a retracted-stored position wherein the deck sections are folded with respect to one another and are located substantially parallel and adjacent to one another.

An autonomous cargo loading or unloading system for a delivery vehicle is disclosed. The system includes a storage compartment having at least a two high by two wide array of compartment portions that store associated cargo received from or delivered through an opening to the storage compartment. A conveyor is located in each compartment portion and the conveyor configured to assist in the delivery or receipt of the associated cargo from or into the compartment portion. A lift assembly is movably mounted to the storage compartment and configured to receive associated cargo from a compartment portion, the lift assembly including a lift assembly conveyor that receives associated cargo from or delivers associated cargo to a compartment portion. The platform can move vertically up and down, and side to side relative to the storage compartment.

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.

A liftgate assembly, such as a for a delivery vehicle, includes a liftgate that is movable by hydraulic power between a raised position and a lowered position. The hydraulic power unit includes an energy-recovery mechanism that stores energy while the liftgate is being lowered under load. Energy stored by the energy-recovery mechanism, such as in an accumulator, may be used to raise the liftgate. The hydraulic power unit includes a pump that pumps hydraulic fluid for providing hydraulic pressure. The liftgate assembly thereby uses energy more efficiently, enabling repurposing part of the energy from lowering the liftgate (and any cargo thereupon) in raising the liftgate.

The subject invention pertains to stowable, modular lift conversion systems configured for aftermarket or OEM application to a truck, all-terrain vehicle (ATV), or utility task vehicle (UTV). Lift systems provided include removable and mounted systems with power provided by a battery, a winch, or linear motion device either on the lift or on the vehicle. Modular implements and lift attachments are provided.

A modular robot system which may be configured to accommodate packages of varying sizes is provided. The modular robot may include a base having omni-directional wheels and cameras and sensors, one or more modular containers, and a lid, which may be releasably linked together to form a small, medium or larger units. The base may include a lifting mechanism to vertically raise the robot to a desired height in alignment with a delivery vehicle. Moreover, retractable loading arms of the vehicle may be extended from the vehicle to engage with the robot to facilitate self-loading of the robot into the delivery vehicle.

A lift raises and lowers a boat to load and unload the boat onto a roof of or a roof rack on a vehicle. The lift has an upper frame having a longitudinal axis, a lower frame having a longitudinal axis, and a linkage connecting the upper frame to the lower frame. In a first position the linkage is extended and the lift is raised and in a second position the linkage is retracted and the lift is lowered. At least one lift rack extends from or is part of the upper frame. The lift rack is adapted to support a boat at least vertically such that in the extended linkage first position a boat may be slid in a longitudinal direction between the lift rack and the roof or the roof rack of the vehicle. A method for using the lift is also disclosed.

A deployable hay pod elevator system for a transport trailer, such as a livestock trailer, provides a readily deployable hay pod, storage pod, or supply platform with the trailer, and is readily stowable above the trailer in a raised configuration for travel. The elevator system includes a deployable supply platform and a vertical raising and lowering mechanism or lift system configured to move the supply platform relative to the trailer. The lift includes a pivot arm system coupled to a sidewall of the trailer and a lift assist mechanism, such as a linear actuator, to vertically raise and lower the deployable supply platform. The elevator system includes a supply platform pivot actuation mechanism to adjust the angle of the platform relative to the pivot arm during stowage and deployment of the system. The elevator system may be fitted to various types of vehicles to store and transport various materials.

A liftgate in accordance with the present disclosure includes a lift mechanism and a moveable load platform. The load platform includes a proximal deck section, a distal deck section, and a center deck section positioned between the proximal deck section and the distal deck section. The load platform is selectively vertically movable between a lowered position and a raised position. The proximal deck section, center deck section, and distal deck section are pivotally coupled to one another such that the load platform is selectively moveable between an extended-operational position, wherein all of the deck sections are located substantially coplanar with one another for supporting cargo, and a retracted-stored position wherein the deck sections are folded with respect to one another and are located substantially parallel and adjacent to one another.