A reinforced railcar side stake configured to be mounted to the underframe of a rail car and extend upwardly therefrom, the side stake comprises: a main body which is a U shaped channel that includes a flat back generally parallel to the side wall and a pair of legs extending generally perpendicular to the back and the side wall structures, the legs of the main body having cutouts at a lower portion thereof; a connection plate coupled to the side sill main body within the cutouts wherein the connection plate surface is flush with the upper ends of the legs above the cutouts; and a reinforcing plate within the interior of the main body near the coupling of the side stake to the underframe wherein the reinforcing plate overlaps the area of the connection plate by extending both below and above the cutouts in the legs.

A hybrid cable/rail transportation system comprising: at least one portion of the system configured as a cable transportation system; at least one portion of the system configured as a rail transportation system, a first trolley coupled to the supporting cable and comprising a first coupling device for coupling to the cabin; a second trolley coupled to the rail and comprising a second coupling device for coupling to the cabin; a plurality of transportation units wherein each transportation unit comprises a cabin, each cabin comprising a roof provided with a coupling system configured for coupling the cabin to the first trolley along the system portion configured as a cable transportation system and to the second trolley along the system portion configured as a rail transportation system; wherein the coupling system arranged on the roof of the cabin, the first coupling device of the first trolley and the second coupling device of the second trolley are configured for allowing a progressive passage of the cabin from the first to the second trolley, or vice-versa, without stopping the support.

A levelling system for a vehicle, in particular a rail vehicle, includes at least one levelling cylinder and a levelling piston. The levelling piston is at least partially provided in the levelling cylinder in a movable manner for setting the level of the rail vehicle. Further, the levelling system includes at least one guiding element, which is arranged within the levelling piston and partially protrudes from the levelling piston into at least one recess of the levelling cylinder such that an end stop in a longitudinal direction is provided for the relative movement between the levelling piston and the levelling cylinder.

A levelling system for a vehicle, in particular a rail vehicle, includes at least one levelling cylinder and a levelling piston. The levelling piston is at least partially provided in the levelling cylinder in a movable manner for setting the level of the rail vehicle. Further, the levelling system includes at least one guiding element, which is arranged within the levelling piston and partially protrudes from the levelling piston into at least one recess of the levelling cylinder such that an end stop in a longitudinal direction is provided for the relative movement between the levelling piston and the levelling cylinder.

A vehicle body inclination controller includes an air spring, an air reservoir, valve devices, an acquisition section, and a determination section. The determination section compares, with a predetermined threshold, at least one of a value of a ratio between supply control information of a supply valve and exhaust control information of an exhaust valve in the same valve device among the valve devices, a value of a ratio between pieces of the supply control information of the supply valves of different valve devices among the valve devices, or a value of a ratio between pieces of the exhaust control information of the exhaust valves of different valve devices among the valve devices, and determines that a failure occurs in the same valve device or at least one of the different valve devices when the value of the ratio exceeds the predetermined threshold.

A vehicle body inclination controller includes an air spring, an air reservoir, valve devices, an acquisition section, and a determination section. The determination section compares, with a predetermined threshold, at least one of a value of a ratio between supply control information of a supply valve and exhaust control information of an exhaust valve in the same valve device among the valve devices, a value of a ratio between pieces of the supply control information of the supply valves of different valve devices among the valve devices, or a value of a ratio between pieces of the exhaust control information of the exhaust valves of different valve devices among the valve devices, and determines that a failure occurs in the same valve device or at least one of the different valve devices when the value of the ratio exceeds the predetermined threshold.

A gondola car is made of high strength and high abrasion resistance steel that provides a lightweight structure and that prolongs the useful life of the car. The high strength and high abrasion resistance steel enhances the strength of the gondola car without increasing its thickness. The contemplated railcar positions components (e.g., side posts and cross-bearers) of the railcar away from areas of the railcar that experience high stresses during transport. In this manner, these components can be welded to form the railcar, and the welds will experience less stress during transport resulting in less weld breaks. Additionally, the number of components (e.g., side posts and cross-bearers) may be reduced, which reduces the weight of the railcar.

Disclosed is a method for controlling the position relatively to a platform of a floor of a carriage including a bogie including a chassis, a primary suspension, and a secondary suspension, the method including the steps: measuring the height of the secondary suspension; and adjusting the height of the secondary suspension, according to the height of the platform for positioning the floor at the height of the platform. This method includes a step for estimating the height of the top of the chassis, the adjustment of the height of the secondary suspension being achieved according to the estimated height of the top of the chassis.

Disclosed is a method for controlling the position relatively to a platform of a floor of a carriage including a bogie including a chassis, a primary suspension, and a secondary suspension, the method including the steps: measuring the height of the secondary suspension; and adjusting the height of the secondary suspension, according to the height of the platform for positioning the floor at the height of the platform. This method includes a step for estimating the height of the top of the chassis, the adjustment of the height of the secondary suspension being achieved according to the estimated height of the top of the chassis.

A rail vehicle includes a fuel tank having a tank wall delimiting a tank interior space for storing fuel. At least portions of a first support are connected to the tank wall. A longitudinal support includes first and second longitudinal support portions being offset in longitudinal direction of the vehicle. The fuel tank is disposed in longitudinal direction between the first and second longitudinal support portions. The first support is coupled to the first and second longitudinal support portions. At least portions of the first support are disposed in the tank interior space in the longitudinal direction. The first support running in the longitudinal direction is disposed between the first and second longitudinal support portions. The first support is configured for fully transmitting a force acting between the first and second longitudinal support portions in longitudinal direction of the vehicle.