A system to detect and avoid spilled cargo in an automobile vehicle, includes an automobile vehicle rear cargo area including a floor to temporarily receive a storage item in the cargo area. A lift gate is moved between a closed and latched position and a fully open position inclusive to allow loading and removal of the storage item. A vision system identifies the storage item when initially loaded in the cargo area and identifies if the storage item is initially positioned in a cargo spill position or subsequently moves to the cargo spill position. A cargo stop device is releasably connected to the lift gate. An operating system releasably stores the cargo stop device when the storage item is not in the cargo spill position and deploys the cargo stop device when the storage item is in the cargo spill position.

A roof waste removal assembly is provided and includes a chute system and a self-propelled expanding trailer. The chute system includes a roof guide and a gutter shield. The self-propelled expanding trailer includes a frame, an extension device secured to the frame, and a storage bin secured to the extension device.

A hitch mounted lift gate system and method of loading and loading a payload from a cargo vehicle using the lift gate system. The frame and platform of the lift gate system is pivotable relative to the hitch and hitch receiver as between a vertical use position and a horizontal dropped position for facilitating opening and closing of rear doors on the vehicle to which the lift gate system is mounted when the rear doors pivot about a vertical axis.

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.

The present invention is directed to properly maneuver heavy cargo to an ergonomically correct lifting height, including for equipment stored on firefighting and rescue vehicles. Mechanically and electromechanically actuated means for raising, lowering, and storing heavy equipment in, on, and around vehicles and other structures are provided.

A system and a method for providing an opening for delivering a shipment into a loading space of a vehicle, as well as a corresponding vehicle and a method for delivering a shipment into a vehicle, include a controller arranged and configured to calculate a first length of the opening based on received and/or determined dimensions of the shipment and further based on an area of the opening configured to receive the shipment through the opening in the loading space of the vehicle. An actuator is arranged and configured to move a first element of the vehicle relative to a second element of the vehicle by the calculated first length of the opening in order to provide the exactly necessary opening.

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.

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.

Systems, devices, and methods having a liftgate frame; a first bracket mount connected to a beam via one or more upper actuators and two or more upper linkages, the two or more upper linkages pivotally mounted between the first bracket mount and the liftgate frame, and where the first bracket mount is configured to move from a first stowed position under the liftgate frame to a second engage position via the one or more upper actuators and the two or more upper linkages; a second bracket mount connected to the beam; a third bracket mount connected to second bracket mount via one or more lower actuators and two or more lower linkages, the two or more lower linkages pivotally mounted between the second bracket mount and the third bracket mount; and a lift platform connected to the third bracket mount, where the lift platform is configured to move from an up position to a down position positioned selectively relative to an external surface; where the first bracket mount moves in an arcuate path from the first stowed position under the liftgate frame to the second engaged position.

A transport trailer and a method for transporting an oversize load are provided. In one nonlimiting example, the transport trailer includes a trailer. The trailer includes an elongated body that extends in a length direction and that has an upper base surface. A support assembly is configured to support the oversize load and is pivotably coupled to the trailer to move between a first position and a second position. In the first position, the support assembly extends over the upper base surface and beyond the trailer in a width direction that is transverse to the length direction to define a wide load overhang that extends beyond the trailer in the width direction. In the second position, the support assembly is positioned at an incline relative to the first position to one of reduce and eliminate the wide load overhang.