A wind turbine blade has a disassembled condition defined by separated blade sections. Each blade section has a residual leading edge remaining from an original leading edge of the blade, a residual trailing edge remaining from an original trailing edge of the blade, and a residual length delimited by a severed edge of the blade. Blade support fixtures are configured for mounting on a transportation platform at spaced-apart locations. Each fixture has a plurality of blade-receiving seats, and each seat is configured with reference to a residual edge portion of a respective one of the separated blade sections.

The present invention provides a removable frame system for transporting vehicles in a container. The frame system is be assembled in the container, the vehicles are loaded on the frame system, the container is shipped to the location, the vehicles are unloaded from the frame system, and the frame system is disassembled and returned to the manufacture or stored for later use.

A transport system for transporting a wind turbine blade on first and second railcars that serve as load cars. A root end fixture on the first railcar is connected to a root end portion of the wind turbine blade. A mid-frame fixture on the second railcar supports a reinforced midsection of the wind turbine blade using a pair of support saddles. A tip end fixture restrains a tip end portion of the wind turbine blade against lateral movement outside of a preselected range of movement in opposite lateral directions and causing bending of the blade about the mid-frame fixture when the restraint device imparts sufficient restraining force to the tip end portion of the blade.

A method for making a railcar having a span bolster is disclosed. The method involves fabricating and joining the components of the span bolster in a manner such that a camber is built into span bolster. A camber is cut into longitudinal supports that span the length of the bolster. A jig is used to shape top and bottom plates prior to attaching the plates to the longitudinal supports, thus forming the bolster. Truck assemblies are attached to the bolster and a railcar body mounted to the combined unit.

A rail-road intermodal freight system. In an embodiment, a conveyor system is provided for placing rail cars in a position for loading shipping containers thereon, while an over-the-road trailer is secured to the rail car. Rail cars have a frame with a front end and a rear end, and a bogie having at least four flanged rail wheels is pivotally mounted to the rear of the frame of the rail car. A method for unloading the rail cars includes lifting the front of the frame of the rail cars and pivoting the rail cars by an angle alpha from the track direction at an unloading area, and lowering the front end of the frame to the ground to allow truck access to trailers on the rail car. By utilizing the method, efficient loading and unloading of train involved in intermodal shipments may save considerable time, and thus reduce costs.

A rail-road intermodal freight system. In an embodiment, a conveyor system is provided for placing rail cars in a position for loading shipping containers thereon, while an over-the-road trailer is secured to the rail car. Rail cars have a frame with a front end and a rear end, and a bogie having at least four flanged rail wheels is pivotally mounted to the rear of the frame of the rail car. A method for unloading the rail cars includes lifting the front of the frame of the rail cars and pivoting the rail cars by an angle alpha from the track direction at an unloading area, and lowering the front end of the frame to the ground to allow truck access to trailers on the rail car. By utilizing the method, efficient loading and unloading of train involved in intermodal shipments may save considerable time, and thus reduce costs.

Methods and means for reconfiguring an aircraft assembly plant that receives fuselages or fuselage sections via a public railroad system. In cases where the aircraft assembly plant comprises a first assembly line for installing (i.e., stuffing) equipment inside fuselages or fuselage sections and a second assembly line for installing equipment on exteriors of internally equipped fuselages or fuselage sections, both assembly lines being housed in the same building, the facility can be reconfigured by moving at least one fuselage stuffing operation of the first assembly line to an auxiliary building which overlies a railroad track connected to the public railroad system. The moved fuselage stuffing operations will be performed inside the auxiliary building while each fuselage or fuselage section is supported in an upright position on a respective railroad flat car.

A wind turbine blade has a disassembled condition defined by separated blade sections. Each blade section has a residual leading edge remaining from an original leading edge of the blade, a residual trailing edge remaining from an original trailing edge of the blade, and a residual length delimited by a severed edge of the blade. Blade support fixtures are configured for mounting on a transportation platform at spaced-apart locations. Each fixture has a plurality of blade-receiving seats, and each seat is configured with reference to a residual edge portion of a respective one of the separated blade sections.

A funicular intended particularly for transporting heavy loads between an upstream station (10) and a downstream station (12), comprises a railway track (14) connecting the upstream station (10) to the downstream station (12) and a vehicle (16) running on the track (14) and drawn by at least one towing cable (30). The vehicle comprises a chassis (50) defining a median longitudinal vertical plane that rests on at least one pendulum running gear, comprising two independent lateral pendulum devices (60) situated on either side of the median longitudinal vertical plane, wherein each lateral pendulum device (60) comprises a secondary pendulum (62) articulated in relation to the chassis (50) around a horizontal secondary pivot axis and two primary pendulums, each articulated in relation to the secondary pendulum (62) around a horizontal primary pivot axis, wherein the primary pivot axes of the two primary pendulums are spaced apart from one another longitudinally on either side of the secondary pivot axis, wherein each primary pendulum is associated with at least two support rollers designed to run on the railway track (14), each rotating around a rotation axis parallel to the primary pivot axis of the associated primary pendulum and situated longitudinally on either side of the primary pivot axis of the associated primary pendulum.

A rail-road intermodal freight system. In an embodiment, a conveyor system is provided for placing rail cars in a position for loading shipping containers thereon, while an over-the-road trailer is secured to the rail car. Rail cars have a frame with a front end and a rear end, and a bogie having at least four flanged rail wheels is pivotally mounted to the rear of the frame of the rail car. A method for unloading the rail cars includes lifting the front of the frame of the rail cars and pivoting the rail cars by an angle alpha from the track direction at an unloading area, and lowering the front end of the frame to the ground to allow truck access to trailers on the rail car. By utilizing the method, efficient loading and unloading of train involved in intermodal shipments may save considerable time, and thus reduce costs.