A funicular intended particularly for transporting heavy loads between an upstream station (10) and a downstream station (12), comprises a track (14), preferably a railway, connecting the upstream station (10) to the downstream station (12), a vehicle (16)running on the track (14) and at least one towing cable (30) in closed loop having a first towing section (32.1) passing over a first pulley (20.1) of the upstream station and over a first return pulley (26) fixed to the vehicle (16) and a second towing section (32.2), in all ways separate from the first towing section and passing over the return pulley (26) and over a second pulley (20.2) of the upstream station (10).

A funicular intended particularly for transporting heavy loads between an upstream station (10) and a downstream station (12), comprises a track (14), preferably a railway, connecting the upstream station (10) to the downstream station (12), a vehicle (16)running on the track (14) and at least one towing cable (30) in closed loop having a first towing section (32.1) passing over a first pulley (20.1) of the upstream station and over a first return pulley (26) fixed to the vehicle (16) and a second towing section (32.2), in all ways separate from the first towing section and passing over the return pulley (26) and over a second pulley (20.2) of the upstream station (10).

A transport system has at least one hauling cable to which a cableway vehicle formed with running gear and a vehicle cab can be coupled. Alternatively, the system has a carrying cable or a track on which a cableway vehicle formed with running gear and a cab can be moved by a traction cable. The section with the hauling cable or carrying cable, or the track, is adjoined by a further track section along which a carrying vehicle for the cableway vehicle can be moved. The carrying vehicle has a drive motor. The running gear of the cableway vehicle runs onto and attaches to the carrying vehicle, whereupon the cableway vehicle is movable along the adjoining track by the carrying vehicle.

A transport system has at least one hauling cable to which a cableway vehicle formed with running gear and a vehicle cab can be coupled. Alternatively, the system has a carrying cable or a track on which a cableway vehicle formed with running gear and a cab can be moved by a traction cable. The section with the hauling cable or carrying cable, or the track, is adjoined by a further track section along which a carrying vehicle for the cableway vehicle can be moved. The carrying vehicle has a drive motor. The running gear of the cableway vehicle runs onto and attaches to the carrying vehicle, whereupon the cableway vehicle is movable along the adjoining track by the carrying vehicle.

A cable car system includes vehicles that are clamped to a hauling cable along the route and decoupled from the hauling cable upon entering the stations. The vehicles are moved through the stations by control tires which are coupled to one another by gear mechanisms and driven via a supporting pulley for the hauling cable. The control tires are mounted on a supporting frame on at least one supporting structure. The rotation of the supporting pulley that drives the control tires is derived from the hauling cable by way of a drive belt. The drive belt runs over the supporting pulley, which is mounted on a pivotable rocker, and over at least one control tire. The pivotable rocker is mounted on the supporting structure for the supporting frame, or the pivotable rocker is mounted on a supporting structure to which the supporting frame is not attached.

A cable car system includes vehicles that are clamped to a hauling cable along the route and decoupled from the hauling cable upon entering the stations. The vehicles are moved through the stations by control tires which are coupled to one another by gear mechanisms and driven via a supporting pulley for the hauling cable. The control tires are mounted on a supporting frame on at least one supporting structure. The rotation of the supporting pulley that drives the control tires is derived from the hauling cable by way of a drive belt. The drive belt runs over the supporting pulley, which is mounted on a pivotable rocker, and over at least one control tire. The pivotable rocker is mounted on the supporting structure for the supporting frame, or the pivotable rocker is mounted on a supporting structure to which the supporting frame is not attached.

Load transport and retraining devices and methods for restraining industrial machines or heavy machinery, such as, turbines, to prevent displacement during adverse environmental conditions, such as, pitching and rolling seas, are provided. The devices include support structures adapted to support loads and having wheels positioned and adapted to engage rails. The wheels include a first set of wheels adapted to ride on top of the rails and a second set of wheels adapted to engage the sides of the rails and thereby retain the support structure to the rails. The devices may also include a third set of wheels adapted to also engage the sides of the rails. The devices may include brake and drive assemblies to facilitate handling. Aspects of the disclosure are uniquely adapted to turbines, but other aspects of the disclosure may restrain any industrial machine that may be exposed to adverse environmental conditions.

A high-carrying-capacity non-stop rail transit system, wherein, comprising a main passage, a main rail arranged in the main passage, an exit and entrance passage and independent small compartments, wherein, the independent small compartment is provided with a connecting device, the exit and entrance passage is provided with a rail change structure, the connecting device realizes transfer and rail change between the main passage and the exit and entrance passage through the rail change structure, the main rail is used to place the independent small compartment and drive the independent small compartment to move. The system adopts the independent small compartment mode, so every passenger has a seat and the non-stop purpose is realized; stable and continuous kinetic energy for advancing are provided; and the independent small compartments have no relative displacement and can reach a high speed under high density.

A high-carrying-capacity non-stop rail transit system, wherein, comprising a main passage, a main rail arranged in the main passage, an exit and entrance passage and independent small compartments, wherein, the independent small compartment is provided with a connecting device, the exit and entrance passage is provided with a rail change structure, the connecting device realizes transfer and rail change between the main passage and the exit and entrance passage through the rail change structure, the main rail is used to place the independent small compartment and drive the independent small compartment to move. The system adopts the independent small compartment mode, so every passenger has a seat and the non-stop purpose is realized; stable and continuous kinetic energy for advancing are provided; and the independent small compartments have no relative displacement and can reach a high speed under high density.

The present disclosure relates to a method and a combined-propulsion system for high-speed vehicles, which includes a closed tubular guiding structure and a vehicle designed to move through the inside of the tubular structure. The system includes a vacuum system coupled to the tubular structure to provide a safe atmosphere at low pressure, always above the Armstrong limit; electric propulsion means arranged in an initial section of the structure, to accelerate the vehicle to a determined cruising speed; and compressed-air propulsion means arranged on the vehicle, to maintain the cruising speed.