A method for controlling a position of a floor of a carriage of a railway vehicle moving on rails, relative to a platform. The carriage includes a body including the floor, at least one bogie, and at least one suspension interposed between the body and the bogie. The method includes determining a level difference between the actual position of the carriage relative to the platform and an expected position of the carriage relative to the platform, adjusting a height of the suspension for compensating the determined level difference. Determining the level difference includes capturing an image of at least one predetermined pattern comprised on the platform with a camera borne by the body, comparing the captured image with a memorized reference image of the at least one pattern of the platform, and calculating a vertical displacement from the images to determine the level difference.

A method for controlling a position of a floor of a carriage of a railway vehicle moving on rails, relative to a platform. The carriage includes a body including the floor, at least one bogie, and at least one suspension interposed between the body and the bogie. The method includes determining a level difference between the actual position of the carriage relative to the platform and an expected position of the carriage relative to the platform, adjusting a height of the suspension for compensating the determined level difference. Determining the level difference includes capturing an image of at least one predetermined pattern comprised on the platform with a camera borne by the body, comparing the captured image with a memorized reference image of the at least one pattern of the platform, and calculating a vertical displacement from the images to determine the level difference.

An auto-rack railroad car including a frame, a plurality of upright posts supported by the frame, a deck, and a plurality of deck connector assemblies connecting the deck to the upright posts, each deck connector assembly including at least one wedge.

An auto-rack railroad car including a frame, a plurality of upright posts supported by the frame, a deck, and a plurality of deck connector assemblies connecting the deck to the upright posts, each deck connector assembly including at least one wedge.

A modular railcar includes a modular top system that is configured to hold one or more coils of material, and a railcar underframe that supports the modular top system. The modular top system includes a pair of side sills and one or more troughs disposed between the pair of side sills. Each side sill of the pair of side sills extends a longitudinal length of the modular top system. Each trough of the one or more troughs is configured to hold a coil of the one or more coils of material. The underframe includes one or more coupling apparatuses that are configured to detachably engage the modular top system when the modular top system is positioned on top of the underframe.

A modular railcar includes a modular top system that is configured to hold one or more coils of material, and a railcar underframe that supports the modular top system. The modular top system includes a pair of side sills and one or more troughs disposed between the pair of side sills. Each side sill of the pair of side sills extends a longitudinal length of the modular top system. Each trough of the one or more troughs is configured to hold a coil of the one or more coils of material. The underframe includes one or more coupling apparatuses that are configured to detachably engage the modular top system when the modular top system is positioned on top of the underframe.

A method comprises removing a first deck of a plurality of decks and a second deck of the plurality of decks from an autorack. The method further comprises removing one or more of a plurality of posts of the autorack and coupling a cross-brace assembly to one or more of the plurality of posts, wherein the cross-brace assembly is coupled to the one or more of the plurality of posts at a location above an existing brace bay of the autorack. The method also comprises coupling the second deck of the plurality of decks to the autorack at a location above or below the cross-brace assembly.

A method comprises removing a first deck of a plurality of decks and a second deck of the plurality of decks from an autorack. The method further comprises removing one or more of a plurality of posts of the autorack and coupling a cross-brace assembly to one or more of the plurality of posts, wherein the cross-brace assembly is coupled to the one or more of the plurality of posts at a location above an existing brace bay of the autorack. The method also comprises coupling the second deck of the plurality of decks to the autorack at a location above or below the cross-brace assembly.

A multi-rail express transit system for allowing the passengers to travel at desired speed/distance, is disclosed. The system comprises a centralized control system, at least three closed loop parallel rails, and at least three sequence of transit cars. Each sequence of transit car is supported by the respective rail. The transit cars are configured to move in same direction at different speeds. The control system is configured to synchronize the speed of transit cars at desired point to allow transference of passengers. A bellow assembly is disposed around an exterior side of a door of each transit car. The bellow assembly is configured to form an airtight passageway between at least two transit cars. Each transit car comprises a movable floor. The movable floor of one transit car is extendable to a floor of an adjacent transit car to facilitate passenger transference on forming the airtight seal.

A multi-rail express transit system for allowing the passengers to travel at desired speed/distance, is disclosed. The system comprises a centralized control system, at least three closed loop parallel rails, and at least three sequence of transit cars. Each sequence of transit car is supported by the respective rail. The transit cars are configured to move in same direction at different speeds. The control system is configured to synchronize the speed of transit cars at desired point to allow transference of passengers. A bellow assembly is disposed around an exterior side of a door of each transit car. The bellow assembly is configured to form an airtight passageway between at least two transit cars. Each transit car comprises a movable floor. The movable floor of one transit car is extendable to a floor of an adjacent transit car to facilitate passenger transference on forming the airtight seal.