A unified hinge may comprise a hinge tube that is rigidly attached to a truck frame and a bed section of a truck bed and a tail section of the truck bed, each of the bed section and the tail section having opposing hinge barrels affixed thereto that concentrically align on the hinge tube. Similarly, a unified hinge may comprise one or more mounting barrels that are rigidly attached to a truck frame and a bed section of a truck bed and a tail section of the truck bed, each of the bed section and the tail section having opposing hinge barrels affixed thereto that concentrically align on the one or more mounting barrels; a hinge tube runs through the one or more mounting barrels and the opposing hinge barrels. The unified hinge allows the bed section and the tail section to independently pivot along the hinge tube.

The invention involves a cargo carrier for vehicles that facilitates loading and unloading of items onto an enclosure; the cargo carrier may be automated and self-loading via actuators and a motorized mechanism that may be remotely controlled. The actuators may be configured to tilt the enclosure or a component thereof and one or more motors may be configured to deploy a deployable tray housed within the enclosure, which minimizes user loading or unloading labor. Typically, on a front end of the enclosure, one or more actuators may couple the enclosure to a portion of a vehicle support structure. The deployable tray may include a tiltable mechanism to further facilitate loading or unloading.

A plastic roll-off container is disclosed, including a roll-off container comprising a front side and a rear side. The roll-off container is configured, via a first rail and a second rai positioned on a bottom side of the roll-off container, to be onloaded, offloaded, and transported by a roll-off truck or a hook lift roll-off truck. An integrally molded sidewall is connected to a bottom having a concave shape to facilitate the removal of a material from an interior of the roll-off container.

A bucket system (10) comprising a frame (12) including first and second rails (26, 27). A bucket (14) is provided having a bucket support (16) including front wheels (32, 33) and rear wheels (34, 35) being slidable within channels (30) in the first and second rails (26, 27). Rear portions (39) of the rails (26, 27) are pivotable between extended and stored positions. When the rear portions (39) are moved to the extended positions, gaps (42) are defined in upper sides of each of the rails (26, 27) such when the rear wheels (34, 35) are moved into the rear portions (39) of the first and second rails (26, 27), the front wheels (32, 33) may move upwardly through the gaps (42) to allow the bucket (14) to pivot about the rear wheels (34, 35).

An agricultural dump cart including a frame, ground conveyance devices carrying the frame, a dump bed, a dumping mechanism and at least one live wall mechanism. The dump bed is coupled to and carried by the frame, and the dump bed has a non-dumping position and a dumping position. The dumping mechanism is connected to the dump bed, and is configured to move the dump bed between the non-dumping position and the dumping position. The at least one live wall mechanism is operatively located along a side of the dump bed. The at least one live wall mechanism is configured for moving a crop material out of the dump bed.

An apparatus for loading and unloading containers of various sizes onto and off of a roll-off vehicle comprises a top frame and at least one lift actuator operable to pivot the top frame away from a horizontal home position to rearwardly incline the top frame. The top frame includes a main portion, a head portion longitudinally displaceable relative to the main portion, a plurality of sheaves, a cable extending through the sheaves, and a hoist actuator operable to displace the head portion between a retracted position and an extended position. The cable has a fixed end coupled to the head portion and a free end for coupling to a container. The hoist actuator is operated while the top frame is away from the home position to displace the head portion toward the extended position to load a container onto the vehicle, and toward the retracted position to unload the container.

An apparatus for loading and unloading containers of various sizes onto and off of a roll-off vehicle comprises a top frame and at least one lift actuator operable to pivot the top frame away from a horizontal home position to rearwardly incline the top frame. The top frame includes a main portion, a head portion longitudinally displaceable relative to the main portion, a plurality of sheaves, a cable extending through the sheaves, and a hoist actuator operable to displace the head portion between a retracted position and an extended position. The cable has a fixed end coupled to the head portion and a free end for coupling to a container. The hoist actuator is operated while the top frame is away from the home position to displace the head portion toward the extended position to load a container onto the vehicle, and toward the retracted position to unload the container.

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 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 tow truck carrier with sub frame rails above the carrier chassis frame rails that also reduces platform height thereby presenting a lower center of gravity. Sub frame rails of rectangular steel tubing with the wider dimension of the tubing are used in a horizontal, low profile orientation, with the direct attachment of the lift cylinder ends to the sub frame rails or to a cross beam to lower the platform. The sub frame rails form a descending ladder frame with cross members attached via brackets so that they are lowered into the recess between the chassis side frame. A lifting bracket is welded to the underside of each sub frame rail underneath the overhang and adjacent to the chassis frame to accept the end of a lifting cylinder rod while leaving some space for sliding engagement of a platform beam which engages three edges of the sub frame rail.