A system for maintaining a minimum clearance between a locomotive and a railway infrastructure is provided. The system includes at least one rollable and compressible device configured to be affixed or otherwise provided on a side of a locomotive or portion of a train. Each rollable and compressible device includes bi-directional rolling element and is configured to allow movement of the roller between a non-rolling state and a rolling state and between an uncompressed state and a predetermined maximum compressed state.

A railway car hatch cover assembly is provided comprising an outer hatch cover, and a gasket retainer. A venting gasket is provided comprised of mesh venting material, and a hydrophobic coating is applied to the mesh venting material. The venting gasket forms a seal with the outer hatch cover and the hatch ring coaming. The hydrophobic coating is usually applied to an outer surface of the mesh venting material. The mesh venting material allows the passage of air therethrough, while providing a barrier to the passage of dirt or similar debris.

A sealing system can be mounted between a body of a vehicle and a box fastened to the body. The body and the box include a first opening and a second opening, respectively, opposite each other. The sealing system surrounds the passage and includes a bellows having a first end in contact with the body so as to surround the first opening, and a second end in contact with the box so as to surround the second opening. The sealing system comprises a compression spring. Each end of the spring acts on one of the two ends of the bellows so that the spring moves the two ends of the bellows away from each other.

A sealing system can be mounted between a body of a vehicle and a box fastened to the body. The body and the box include a first opening and a second opening, respectively, opposite each other. The sealing system surrounds the passage and includes a bellows having a first end in contact with the body so as to surround the first opening, and a second end in contact with the box so as to surround the second opening. The sealing system comprises a compression spring. Each end of the spring acts on one of the two ends of the bellows so that the spring moves the two ends of the bellows away from each other.

An overhead transport vehicle includes a vibration-proof portion disposed between a belt and a lift device. The vibration-proof portion includes a first connection mechanism disposed on a side where a first load acts in a width direction perpendicular or substantially perpendicular to both a travelling direction and a lifting direction of the lift device, and a second connection mechanism disposed on a side where a second load larger than the first load acts in the width direction, and which has a larger repulsive force than that of the first connection mechanism.

An overhead transport vehicle includes a vibration-proof portion disposed between a belt and a lift device. The vibration-proof portion includes a first connection mechanism disposed on a side where a first load acts in a width direction perpendicular or substantially perpendicular to both a travelling direction and a lifting direction of the lift device, and a second connection mechanism disposed on a side where a second load larger than the first load acts in the width direction, and which has a larger repulsive force than that of the first connection mechanism.

A rail vehicle has a bogie, which is covered in such a way that a bogie cavity exists, which is formed in the under floor region of the rail vehicle by a cover assembly and walls adjacent to the bogie. A device for producing pressurized air is connected, with respect to flow, to an air inlet device in the walls of the bogie cavity in such a way that the air can be blown into the bogie cavity.

A rail vehicle has a bogie, which is covered in such a way that a bogie cavity exists, which is formed in the under floor region of the rail vehicle by a cover assembly and walls adjacent to the bogie. A device for producing pressurized air is connected, with respect to flow, to an air inlet device in the walls of the bogie cavity in such a way that the air can be blown into the bogie cavity.

A carbody of a railcar includes an underframe, a side bodyshell, and a roof bodyshell. At least one of the underframe, the side bodyshell, and the roof bodyshell includes: an outer plate portion facing a car outside; and a reinforced portion joined to an inside surface of the outer plate portion and forming at least one internal space between the reinforced portion and the outer plate portion. At least one sound absorbing hole communicating with the internal space is formed on the outer plate portion.

A rail vehicle includes a car body having both a passenger space and a stowage space that is provided with a controller and at least one station for accommodating light electric vehicles. The stations have a chassis, a holding structure, a locking mechanism, and a power outlet. The holding structure can hold the light electric vehicle stationary. The locking mechanism can retain the light electric vehicle in the holding structure. The power outlet can deliver electrical power to a battery of the light electric vehicle when the light electric vehicle is secured in the holding structure and connected to the power outlet. The power outlet can be connected to an electrical power network of the rail vehicle. The controller can selectively send a release signal to the locking mechanism, so as to release the locking mechanism, and to selectively operate the power outlet so as to deliver the electrical power.