A liftable carrying apparatus for loading a pocket wagon with vehicles by a lifting apparatus includes a first support portion for at least one vehicle that extends over a length, at least one second support portion for at least one vehicle, that is arranged above the first support portion and extends over a length, and receiving locations, in particular receiving pockets, for a lifting apparatus, that are arranged at the first and the at least one second support portions. The length over which the first support portion extends and the length over which the at least one second support portion extends differ from each other, and the first and the at least one second support portions are or can be releasably connected together for joint lifting by a lifting apparatus.

A liftable carrying apparatus for loading a pocket wagon with vehicles by a lifting apparatus includes a first support portion for at least one vehicle that extends over a length, at least one second support portion for at least one vehicle, that is arranged above the first support portion and extends over a length, and receiving locations, in particular receiving pockets, for a lifting apparatus, that are arranged at the first and the at least one second support portions. The length over which the first support portion extends and the length over which the at least one second support portion extends differ from each other, and the first and the at least one second support portions are or can be releasably connected together for joint lifting by a lifting apparatus.

The invention concerns a method for simulating and optimizing loading of a system for transporting loads in order to determine an optimized loading plan. The method includes: a) inputting the previously defined structural and functional parameters of at least one transport system; b) inputting the number and the dimensional and weight parameters of the loads to be transported; c) inputting the spacing between the loads from previously defined values; d) inputting the route and/or the destination of the load to select the previously defined legal constraints during transport; e) carrying out an optimization calculation in real time, taking into account the parameters and constraints of steps a), b), c) and d) to simulate at least one optimized loading plan consistent with all of the constraints; and f) presenting an optimized loading calculated in e) or approximating an initial loading request.

The invention concerns a method for simulating and optimizing loading of a system for transporting loads in order to determine an optimized loading plan. The method includes: a) inputting the previously defined structural and functional parameters of at least one transport system; b) inputting the number and the dimensional and weight parameters of the loads to be transported; c) inputting the spacing between the loads from previously defined values; d) inputting the route and/or the destination of the load to select the previously defined legal constraints during transport; e) carrying out an optimization calculation in real time, taking into account the parameters and constraints of steps a), b), c) and d) to simulate at least one optimized loading plan consistent with all of the constraints; and f) presenting an optimized loading calculated in e) or approximating an initial loading request.

A stowage system (14) is provided for stowing a two-wheeled vehicle (30) in a motor vehicle (12), having a loading floor (16) for depositing the two-wheeled vehicle (30), and a lifting device (20) which can be supported on a load-bearing structure (22) of the motor vehicle (12) for moving the loading floor (16) between a loading position and a stowing position. The loading floor (16) has at least one three-dimensionally shaped first centring means (26) for positioning the two-wheeled vehicle (30) at least in a first coordinate direction relative to the loading floor (16). A two-wheeled vehicle (30) can be stowed in a space-saving manner and protected against damage by of the loading floor (16) which can be lowered and the at least one centring means (26).

A stowage system (14) is provided for stowing a two-wheeled vehicle (30) in a motor vehicle (12), having a loading floor (16) for depositing the two-wheeled vehicle (30), and a lifting device (20) which can be supported on a load-bearing structure (22) of the motor vehicle (12) for moving the loading floor (16) between a loading position and a stowing position. The loading floor (16) has at least one three-dimensionally shaped first centring means (26) for positioning the two-wheeled vehicle (30) at least in a first coordinate direction relative to the loading floor (16). A two-wheeled vehicle (30) can be stowed in a space-saving manner and protected against damage by of the loading floor (16) which can be lowered and the at least one centring means (26).

A transport trailer includes an elongated body having spaced vertical supports for vertical actuators, a lower deck extending along and supported by the elongated body, and an upper deck supported by the vertical actuators. The upper deck is movable along the vertical supports via the vertical actuators. The upper deck can be lowered to a position to be substantially superimposed on top of the lower deck by the vertical actuators.

A transport trailer includes an elongated body having spaced vertical supports for vertical actuators, a lower deck extending along and supported by the elongated body, and an upper deck supported by the vertical actuators. The upper deck is movable along the vertical supports via the vertical actuators. The upper deck can be lowered to a position to be substantially superimposed on top of the lower deck by the vertical actuators.

An assistance vehicle tilt lift supports an assistance vehicle above a bed of a hauling vehicle and includes one or more pivoting racks. Each pivoting rack includes a track to receive one or more wheels of the assistance vehicle. Each pivoting rack is rotatably attached to a pivot point near the front end of the bed of the hauling vehicle. One or more tapered rails are attached to the bed of the hauling vehicle. One or more roller support members are in contact with the one or more tapered rails and rotatably attached to the one or more pivoting racks. An actuator is operably connected to the one or more roller support members. The actuator raises and lowers the rear end of the one or more pivoting racks relative to the pivot point by moving the one or more roller support members along the one or more tapered rails.

An assistance vehicle tilt lift supports an assistance vehicle above a bed of a hauling vehicle and includes one or more pivoting racks. Each pivoting rack includes a track to receive one or more wheels of the assistance vehicle. Each pivoting rack is rotatably attached to a pivot point near the front end of the bed of the hauling vehicle. One or more tapered rails are attached to the bed of the hauling vehicle. One or more roller support members are in contact with the one or more tapered rails and rotatably attached to the one or more pivoting racks. An actuator is operably connected to the one or more roller support members. The actuator raises and lowers the rear end of the one or more pivoting racks relative to the pivot point by moving the one or more roller support members along the one or more tapered rails.