The present invention relates to the field of transport mechanical engineering. Objectimprove performance and operational reliability of a friction shock absorber. The friction shock absorber (FIG. 2) comprises housing (1), whose walls form orifice (2), and bottom (4) that is in contact with return-and-retaining device (5) contacting a friction assembly that consists of the following elements fitted out with friction surfaces (f1-f10): supporting plate (10), pressure wedge (6), stay wedges (7), and reverse-U-shaped movable plates (9) fitted out with side shelves (14) that cover guide plates (8) and are located on supporting plate (10). Return-and-retaining device (5) is available between the guide plates. Additional return-and-retaining device (11) is available between the pressure wedge and the supporting plate. Recesses for the return-and-retaining device and hard lubricant inserts are available on the guide plates; Movable plates may be partially T-shaped forming side shelves that are located on the supporting plate. Hooks (15, 16) are available on the pressure wedge and stay wedges, located so as to enable a mutual contact during the back stroke of the pressure wedge.

The present invention relates to the field of transport mechanical engineering. Objectimprove performance and operational reliability of a friction shock absorber. The friction shock absorber (FIG. 2) comprises housing (1), whose walls form orifice (2), and bottom (4) that is in contact with return-and-retaining device (5) contacting a friction assembly that consists of the following elements fitted out with friction surfaces (f1-f10): supporting plate (10), pressure wedge (6), stay wedges (7), and reverse-U-shaped movable plates (9) fitted out with side shelves (14) that cover guide plates (8) and are located on supporting plate (10). Return-and-retaining device (5) is available between the guide plates. Additional return-and-retaining device (11) is available between the pressure wedge and the supporting plate. Recesses for the return-and-retaining device and hard lubricant inserts are available on the guide plates; Movable plates may be partially T-shaped forming side shelves that are located on the supporting plate. Hooks (15, 16) are available on the pressure wedge and stay wedges, located so as to enable a mutual contact during the back stroke of the pressure wedge.

A cushioning apparatus for a railway car employs a shortened yoke with a reduced-width tail for placement between stops in a conventional railway car sill. A first stack of rigid plates with elastomeric pads is provided between the straps of the modified yoke behind the coupler follower, and a second stack of plates and elastomeric pads is positioned in the sill behind the modified yoke to absorb buff loads on the coupler. In embodiments, the entire assembly may be placed in a sill having forward stops, intermediate stops, and rear stops, adapted to house a hydraulic cushioning unit.

A cushioning apparatus for a railway car employs a shortened yoke with a reduced-width tail for placement between stops in a conventional railway car sill. A first stack of rigid plates with elastomeric pads is provided between the straps of the modified yoke behind the coupler follower, and a second stack of plates and elastomeric pads is positioned in the sill behind the modified yoke to absorb buff loads on the coupler. In embodiments, the entire assembly may be placed in a sill having forward stops, intermediate stops, and rear stops, adapted to house a hydraulic cushioning unit.

An absorbing apparatus includes a shock-absorbing unit that includes a front plate, a rear plate and a shock-absorbing core arranged between the front plate and the rear plate. The apparatus also includes a base connected to the rear plate of the shock-absorbing unit and having a rear plate, and a side shield surrounding at least partially the shock-absorbing core. One end of the side shield is connected to the front plate or the rear plate of the shock-absorbing unit, while the other end of the side shield is spaced-apart from the other of the front plate or the rear plate of the shock-absorbing unit. The base includes an energy absorbing element connected to the rear plate of the shock-absorbing unit and mounted in the rear plate of the base, while the rear plate of the base includes a cutting unit for cutting a surface of the energy absorbing element.

A collision energy absorption apparatus for a rail vehicle, including a connection member, a base, and an energy-absorption splitting tube provided on the outer side in the radial direction of the connection member. The inner wall and outer wall of the energy-absorption splitting tube includes one or more pairs of slits having radial positions corresponding to each other. Each pair of slits includes an inner slit and an outer slit. Each slit is a non-closed linear slit. The slit has a width of 0.05-0.8 mm. The sum of the depths of each pair of slits is less than the wall thickness of the energy-absorption splitting tube.

A collision energy absorption apparatus for a rail vehicle, including a connection member, a base, and an energy-absorption splitting tube provided on the outer side in the radial direction of the connection member. The inner wall and outer wall of the energy-absorption splitting tube includes one or more pairs of slits having radial positions corresponding to each other. Each pair of slits includes an inner slit and an outer slit. Each slit is a non-closed linear slit. The slit has a width of 0.05-0.8 mm. The sum of the depths of each pair of slits is less than the wall thickness of the energy-absorption splitting tube.

A mounting interface for attaching supporting components to a buffer of a rail vehicle. The interface has a mounting body with a component fastening region and an attachment region that is different therefrom. The component fastening region is equipped with fastening elements and/or holes for attaching the components. The attachment region is formed in such a way that it can be fastened to at least two fastening points at the rear side of a buffer flange using buffer screws. There is also described a buffer system and a rail vehicle with such a mounting interface.

A mounting interface for attaching supporting components to a buffer of a rail vehicle. The interface has a mounting body with a component fastening region and an attachment region that is different therefrom. The component fastening region is equipped with fastening elements and/or holes for attaching the components. The attachment region is formed in such a way that it can be fastened to at least two fastening points at the rear side of a buffer flange using buffer screws. There is also described a buffer system and a rail vehicle with such a mounting interface.

A mounting interface for attaching supporting components to a buffer of a rail vehicle. The interface has a mounting body with a component fastening region and an attachment region that is different therefrom. The component fastening region is equipped with fastening elements and/or bores for attaching the components. The attachment region is formed in such a manner that it can be fastened to at least one fastening point at a front side of a buffer flange using screws. There is also described a buffer system and a rail vehicle with such a mounting interface.