A floor structure of a rail vehicle car body includes a supporting structure having a left and a right longitudinal beams and a plurality of transverse structural members using a low-heat welding process. A floor panel is directly and releasably attached atop the supporting structure using and a plurality of non-permanent, pressure interlocking fasteners.

Disclosed is railway vehicle coach, including a chassis and a bogie arranged below the chassis in a vertical direction. The coach includes a thermally insulating screen, arranged between the chassis and the bogie, above the bogie in the vertical direction.

Disclosed is railway vehicle coach, including a chassis and a bogie arranged below the chassis in a vertical direction. The coach includes a thermally insulating screen, arranged between the chassis and the bogie, above the bogie in the vertical direction.

A railway vehicle car includes a lower level and an upper level that are separated by an intermediate floor. The intermediate floor defines an opening emerging on the upper level and on the lower level, and also defines a bridge extending at least partially along the opening. The bridge connects a first longitudinal end and a second longitudinal end of the car on the upper level. The circulation of passengers is blocked on the lower level at least at one of the first longitudinal end and the second longitudinal end.

A railway vehicle car includes a lower level and an upper level that are separated by an intermediate floor. The intermediate floor defines an opening emerging on the upper level and on the lower level, and also defines a bridge extending at least partially along the opening. The bridge connects a first longitudinal end and a second longitudinal end of the car on the upper level. The circulation of passengers is blocked on the lower level at least at one of the first longitudinal end and the second longitudinal end.

The present invention provides a Descending Mechanised Access Ramp (D-MAR) system for providing independent access for persons between a floor of a train and a station platform, the D-MAR system including a substantially planar casing box mountable to the floor of the train; a hinged jointed sliding ramp, installed inside the substantially planar casing box; a plurality of side wheels installed on sides of the hinged jointed sliding ramp, adapted to allow the hinged jointed sliding ramp to be slidably moveable inside the substantially planar casing box; a remote-controlled deployment mechanism configured to automatically deploy the hinged jointed sliding ramp between a stand-by position within the casing box on the floor of the train and a fully deployed position, such that a nose of the hinged jointed sliding ramp is slidably engaged with the station platform; and wherein, at least two mobile protection walls are positioned on the station platform and comprise tactile push buttons that are configured to trigger flashing lights installed on top of the at least one bollard on two mobile protection walls and to activate the remote controlled deployment mechanism of the D-MAR.

According to some embodiments, a refrigerated railcar comprises a pair of side walls, a roof, a floor, and a refrigeration unit. The floor comprises a bottom structure comprising a plurality of channels for return air flow from an interior of the railcar to the refrigeration unit. The floor further comprises at least two top plates coupled to the bottom structure (e.g., via a pivot rod). Each of the top plates extends longitudinally along the bottom structure and is configured to rotate up and away from the bottom structure proximate one of the side walls of the pair of side walls. Lifting an edge of a top plate opposite the edge of the top plate pivotally coupled to the bottom structure causes the top plate to rotate to an upright position exposing the plurality of channels of the bottom structure.

According to some embodiments, a refrigerated railcar comprises a pair of side walls, a roof, a floor, and a refrigeration unit. The floor comprises a bottom structure comprising a plurality of channels for return air flow from an interior of the railcar to the refrigeration unit. The floor further comprises at least two top plates coupled to the bottom structure (e.g., via a pivot rod). Each of the top plates extends longitudinally along the bottom structure and is configured to rotate up and away from the bottom structure proximate one of the side walls of the pair of side walls. Lifting an edge of a top plate opposite the edge of the top plate pivotally coupled to the bottom structure causes the top plate to rotate to an upright position exposing the plurality of channels of the bottom structure.

A railroad tank car may have external fittings, such as brake fittings. A low mount brake fitting is located in a recess formed in the end sill of the car or in the side sill of the car between the main bolster and the end sill. Where an end sill installation is used, the end sill may be asymmetric, with the recess being formed to one side of the center sill. Alternatively, the end sill may be offset longitudinally away from the striker, and a spacer inserted.

A railroad tank car may have external fittings, such as brake fittings. A low mount brake fitting is located in a recess formed in the end sill of the car or in the side sill of the car between the main bolster and the end sill. Where an end sill installation is used, the end sill may be asymmetric, with the recess being formed to one side of the center sill. Alternatively, the end sill may be offset longitudinally away from the striker, and a spacer inserted.