A locking mechanism has a guide and a vertically movable plate. The plate is movable in the guide under gravitational influence between a locked position and an unlocked position. A slot is formed in the plate to receive a guide pin. The guide pin maintains the movable plate in the guide. The slot enables axial vertical movement of the plate in the guide. The plate moves into the locked position upon contact with a surface. In this position, the plate projects from the guide to lock a roll off container onto the hoist. The movable plate reverts to the unlocked position upon removal of the surface so that the plate moves into the guide.

A lift deck assembly has a base frame mounted in the cargo box of a truck and a load supporting platform movable relative to the base frame by a linkage between a loading position substantially at ground level and a transport position above the cargo box in which the side edges of the platform are aligned with the sidewalls of the cargo box and the rear edge of the platform is aligned with the tailgate to provide the general appearance of a tonneau cover. The platform includes a main defining the side edges and an extendable portion that can be extended rearward from the main portion to assist in supporting a load thereon. The extendible portion can be retracted so that the rear edge thereof aligns with the rear edge of the main portion and the tailgate.

The disclosure relates to a lift installation having a lift car which can be moved along a guide rail. The lift installation here comprises at least a first pair of rollers and a second pair of rollers. The guide rail runs between the two rollers of the first pair of rollers and between the two rollers of the second pair of rollers. The lift installation also has an apparatus for subjecting the lift car to a retaining force, wherein there is a horizontal offset between the point at which the retaining force takes effect and the center of gravity of the lift car, and therefore the lift car is subjected to a first torque.

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 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.

An embodiment of a lighting device for a lift gate includes one or more sensors, each sensor configured to generate an output signal based on motion and/or orientation thereof, wherein each sensor is coupled to a movable member of the lift gate to generate an output signal indicating a motion and/or position state of said movable member of the lift gate; a controller circuit coupled to each sensor to receive an output signal from each sensor, wherein the controller circuit is configured to generate one or more control signals for controlling operation of one or more lighting elements; and one or more lighting elements coupled to the controller circuit to receive control signals from the controller circuit; wherein the controller circuit is configured to generate one or more control signals in response to the output signals from each sensor, for controlling operation of one or more lighting elements based on sensed state of the moveable member.

The invention relates to a transport vehicle for transporting at least one transport unit. The transport vehicle including at least one drive unit having at least one electric drive, at least one steerable vehicle wheel, at least one standing platform, at least one control unit (6), and at least one loading fork, and at least two longitudinal outriggers, which are arranged parallel to one another and at a distance from one another and extend in a longitudinal direction of the transport vehicle and between which the loading fork is arranged so as to be height-adjustable and which are in each case connected to the drive unit by one end section and at the respective other end section of which in each case at least one non-steerable vehicle wheel is arranged.

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 mounting system for mounting a lift gate on a structure is provided, the lift gate having a lift platform supported between a pair of spaced support columns. The mounting system comprises a first mounting member configured for attachment onto said structure, wherein the first mounting member includes a support protrusion for engaging an opening in a wall of a corresponding lift gate support column. The mounting system further comprises a second mounting member configured for attachment onto said structure, wherein the second mounting member includes a support protrusion for engaging an opening in a wall of a corresponding lift gate support column. When the mounting members are attached to the structure and the corresponding lift gate support columns are mounted on the support protrusions, the mounting members support the lift gate on the structure.

A mounting system for mounting a lift gate on a structure is provided, the lift gate having a lift platform supported between a pair of spaced support columns. The mounting system comprises a first mounting member configured for attachment onto said structure, wherein the first mounting member includes a support protrusion for engaging an opening in a wall of a corresponding lift gate support column. The mounting system further comprises a second mounting member configured for attachment onto said structure, wherein the second mounting member includes a support protrusion for engaging an opening in a wall of a corresponding lift gate support column. When the mounting members are attached to the structure and the corresponding lift gate support columns are mounted on the support protrusions, the mounting members support the lift gate on the structure.