The present invention provides a rail vehicle. The rail vehicle includes: an underframe assembly, a side wall assembly, a vehicle roof assembly, and a vehicle end assembly. The underframe assembly includes a primary energy absorption structure and an underframe edge beam which are connected. The primary energy absorption structure has at least two energy absorbing cavities that are set at interval. The lower end of the side wall assembly is connected with the underframe assembly. The upper end of the side wall assembly is connected with the vehicle roof assembly. The vehicle end assembly includes an end energy absorption structure whose lower end is connected with the primary energy absorption structure, and upper end is connected with the vehicle roof assembly. By using the technical solution of the present invention, that is, the primary energy absorption structure of the underframe assembly, the vehicle roof assembly, and the end energy absorption structure which is installed between the vehicle roof assembly and the primary energy absorption structure form the overall energy absorbing structure at the end of the vehicle body structure, there is no need to add an independent energy absorbing component. The present invention improves impact energy absorbing performance of the vehicle without increasing the overall dimension of the vehicle body structure.

Provided are a collision energy absorption structure and a rail vehicle having the same. The collision energy absorption structure includes: a primary energy absorption structure, connected to a chassis boundary beam of a vehicle, the primary energy absorption structure having at least two spaced energy absorption cavities; an end energy absorption structure, the lower end of the end energy absorption structure being connected to the primary energy absorption structure; and a roof structure, the upper end of the end energy absorption structure being connected to the roof structure. The technical solution provided by the present invention can meet requirements of more complex road conditions.

A method for manufacturing a railcar body includes assembling an underframe assembly, side walls, a roof and end walls made from laser cut sheet and plate components where the assemblies made from sheet components are robotically laser welded by solely using melt-through welds and where the assemblies made from plate components are robotically laser welded using solely butt welds.

A method for manufacturing a railcar body includes assembling an underframe assembly, side walls, a roof and end walls made from laser cut sheet and plate components where the assemblies made from sheet components are robotically laser welded by solely using melt-through welds and where the assemblies made from plate components are robotically laser welded using solely butt welds.

A modern scenic passenger railcar system is disclosed. The railcar system incorporates design and safety features of modern freightcars and modern passenger scenic railway cars. The railcar system incorporates a center beam with a square cross section as well as specialized crash posts with its frame. This results in enhanced safety and crashworthiness. The railcar system also incorporates cross members for absorbing and distributing shock and mechanical stress on the railcar system during use, by withstanding torsion and shear forces on the frame. This results in improved mechanical integrity of the frame and the railcar system overall.

An easy-to-maintain frame-type energy-absorption structure, including: a fixing frame, anti-climder which are arranged at the front of the bottom of the fixing frame, energy absorption block which are detachably connected with the fixing frame and the anti-climder respectively, a connecting device for hinging the anti-climder and the fixing frame, and shear pins which are respectively arranged at a junction of the connecting device and the fixing frame, and a junction of the connecting device and the anti-climder. So that changing the traditional whole welded frame type energy absorbing device into an easy-to-maintain frame-type energy-absorption structure, and when a collision occurs, protecting the fixing frame from being damaged, and the energy absorption block can be replaced to achieve reuse it.

A side wall for a rail vehicle body includes an outer skin, an insulating layer adjacent an inner face of the outer skin, a structural layer adjacent an inner face of the insulating layer, a finishing layer adjacent an inner face of the structural layer and a window. The insulating layer provides at least one of a thermal and an acoustical insulation. The structural layer has a longitudinally aligned top door frame member, vertical left and right door frame members and a plurality of diagonal structural members oriented at an angle comprised between 1 degree and 89 degrees from the top door frame member. The plurality of diagonal structural members defines a lattice structure having a plurality of openings there in between. The window covers at least a portion of one of the plurality of openings.

A rail vehicle for transporting passengers includes at least one car body, a passenger compartment situated in the car body, an underfloor region, an inner ceiling region, and a plurality of device containers for receiving vehicle components. The passenger compartment includes a first end wall region and a second end wall region which is situated opposite the first end wall region. In order to enable a great configuration freedom for the passenger compartment, it is provided that each device container of the rail vehicle is disposed in one of the above-mentioned regions.

A rail vehicle for transporting passengers includes at least one car body, a passenger compartment situated in the car body, an underfloor region, an inner ceiling region, and a plurality of device containers for receiving vehicle components. The passenger compartment includes a first end wall region and a second end wall region which is situated opposite the first end wall region. In order to enable a great configuration freedom for the passenger compartment, it is provided that each device container of the rail vehicle is disposed in one of the above-mentioned regions.

A vehicle, in particular a rail vehicle, has cladding modules for cladding a body shell-side vehicle lateral wall and/or vehicle roof. The cladding modules, or at least a majority of the cladding modules of the vehicle, either have a first width or a second width which is smaller than the first width, and the difference between the first and second width corresponds to half of the width of at least one partition module which is mounted in the vehicle and which is mounted between two of the cladding modules or is arranged on an interface between two directly adjacent cladding modules, in particular the partition module is placed in front of the interface when seen in the vehicle transverse direction and covers the interface.