The present disclosure concerns a transport vehicle for handling a rotor blade mold for the production of a rotor blade of a wind power installation or a shell portion of a rotor blade of a wind power installation, adapted for use in a handling apparatus. The handling apparatus includes a first rail set for displacement of the transport vehicle in a first direction, and a second rail set for displacement of the transport vehicle in a second direction. In addition the transport vehicle includes a first wheel set including a plurality of wheels for movement on the first rail set, and a second wheel set including a plurality of wheels for movement on the second rail set.

Provided herein are transit systems for travel overhead of streets, having: at least a first vehicle and a second vehicle; a main track on which the vehicles travel, the main track having a suspended overhead rail over the streets by a support structure, such that the vehicles travel at an elevated level overhead of street level; docking stations for the vehicles to lower to the street level for loading and/or unloading passengers and/or cargo; a two-position switch at each docking station, having cables enabling vertical movement of the vehicle, and a replacement track; wherein the two-position switch allows for docking of the first vehicle while the second vehicle passes the docked first vehicle, by enabling lowering of the first vehicle from the elevated level to the street level, and the replacement track providing a track portion for the second vehicle on which to pass the first vehicle.

Transit systems for travel overhead of streets, having: at least a first vehicle and a second vehicle; a main track on which the vehicles travel, the main track having a suspended overhead rail over the streets by a support structure, such that the vehicles travel at an elevated level overhead of street level; docking stations for the vehicles to lower to the street level for loading and/or unloading passengers and/or cargo; a two-position switch at each docking station, having cables enabling vertical movement of the vehicle, and a replacement track; wherein the two-position switch allows for docking of the first vehicle while the second vehicle passes the docked first vehicle, by enabling lowering of the first vehicle from the elevated level to the street level, and the replacement track providing a track portion for the second vehicle on which to pass the first vehicle.

Provided herein are transit systems for travel overhead of streets, having: at least a first vehicle and a second vehicle; a main track on which the vehicles travel, the main track having a suspended overhead rail over the streets by a support structure, such that the vehicles travel at an elevated level overhead of street level; docking stations for the vehicles to lower to the street level for loading and/or unloading passengers and/or cargo; a two-position switch at each docking station, having cables enabling vertical movement of the vehicle, and a replacement track; wherein the two-position switch allows for docking of the first vehicle while the second vehicle passes the docked first vehicle, by enabling lowering of the first vehicle from the elevated level to the street level, and the replacement track providing a track portion for the second vehicle on which to pass the first vehicle.

Provided herein are transit systems for travel overhead of streets, having: at least a first vehicle and a second vehicle; a main track on which the vehicles travel, the main track having a suspended overhead rail over the streets by a support structure, such that the vehicles travel at an elevated level overhead of street level; docking stations for the vehicles to lower to the street level for loading and/or unloading passengers and/or cargo; a two-position switch at each docking station, having cables enabling vertical movement of the vehicle, and a replacement track; wherein the two-position switch allows for docking of the first vehicle while the second vehicle passes the docked first vehicle, by enabling lowering of the first vehicle from the elevated level to the street level, and the replacement track providing a track portion for the second vehicle on which to pass the first vehicle.

A self-propelled unit for movable operation on a support structure along a first axis of movement and a second axis of movement that is transverse to the first axis of movement includes a carrier configured for movable displacement on the support structure. A first conveyor assembly is operable to move the carrier on the support structure along the first axis of movement. A second conveyor assembly is operable to move the carrier on the support structure along the second axis of movement. A light source can be attached to the carrier in an operable mode to provide illumination to an area in proximity to the carrier. At least one power contact is configured to maintain electrical contact between the carrier and the support structure.

A self-propelled unit for movable operation on a support structure along a first axis of movement and a second axis of movement that is transverse to the first axis of movement includes a carrier configured for movable displacement on the support structure. A first conveyor assembly is operable to move the carrier on the support structure along the first axis of movement. A second conveyor assembly is operable to move the carrier on the support structure along the second axis of movement. A light source can be attached to the carrier in an operable mode to provide illumination to an area in proximity to the carrier. At least one power contact is configured to maintain electrical contact between the carrier and the support structure.

A shuttle bar (20) for a freight-handling device for transferring cargo from road to rail and vice versa using horizontal transverse loading, for moving a railcar pallet of a freight car to a loading platform and vice versa, wherein the shuttle bar (20) includes lifting mechanism for raising and lowering of the railcar pallet from or onto a railcar undercarriage of the freight train as well as from or onto the loading platform, wherein the shuttle bar (20) includes a bar base frame (30), a lifting bar (31), and a lifting-bar drive device (32) for raising and lowering the lifting bar (31) relative to the bar base frame (30), as well as a freight-handling device for combined freight transport with such shuttle bars, and a freight-handling method.

A shuttle bar (20) for a freight-handling device for transferring cargo from road to rail and vice versa using horizontal transverse loading, for moving a railcar pallet of a freight car to a loading platform and vice versa, wherein the shuttle bar (20) includes lifting mechanism for raising and lowering of the railcar pallet from or onto a railcar undercarriage of the freight train as well as from or onto the loading platform, wherein the shuttle bar (20) includes a bar base frame (30), a lifting bar (31), and a lifting-bar drive device (32) for raising and lowering the lifting bar (31) relative to the bar base frame (30), as well as a freight-handling device for combined freight transport with such shuttle bars, and a freight-handling method.

A self-propelled unit for movable operation on a support structure along a first axis of movement and a second axis of movement that is transverse to the first axis of movement includes a carrier configured for movable displacement on the support structure. A first conveyor assembly is operable to move the carrier on the support structure along the first axis of movement. A second conveyor assembly is operable to move the carrier on the support structure along the second axis of movement. A light source can be attached to the carrier in an operable mode to provide illumination to an area in proximity to the carrier. At least one power contact is configured to maintain electrical contact between the carrier and the support structure.