A bogie for a train vehicle includes two side frames, each side frame including two axle openings, each axle opening disposed on a corresponding end of the respective side frame, each side frame further forming a central slot disposed between the two axle openings; two wheelsets, each wheelset including an axle passing through two opposing axle openings between the two side frames; and a central beam having two ends, each end being slidably disposed within a corresponding central slot such that the central beam is disposed generally parallel to the axles of the two wheelsets and is slidable towards or away either of the two wheelsets.

A bogie, including a frame (1) and a bolster (2), the frame (1) including two parallel side beams (11), and a cross beam (12) coupled to the middle of the side beams (11), wherein a primary suspension is arranged between an end of the side beam (11) and an axle box (31), a secondary suspension is arranged between the below of the bolster (2) and the cross beam (12), and a tertiary suspension coupled to a vehicle body is arranged above the bolster (2). By including a bolster and an extra suspension on the basis of the conventional two suspensions, the disclosed bogie can achieve separation of the functions, so that the tertiary suspension only handles the transverse displacement, and the secondary suspension only handles the rotation, thereby further increasing the relative displacement and rotation angle between the vehicle body and the bogie when the vehicle negotiates a curve.

A bogie, including a frame (1) and a bolster (2), the frame (1) including two parallel side beams (11), and a cross beam (12) coupled to the middle of the side beams (11), wherein a primary suspension is arranged between an end of the side beam (11) and an axle box (31), a secondary suspension is arranged between the below of the bolster (2) and the cross beam (12), and a tertiary suspension coupled to a vehicle body is arranged above the bolster (2). By including a bolster and an extra suspension on the basis of the conventional two suspensions, the disclosed bogie can achieve separation of the functions, so that the tertiary suspension only handles the transverse displacement, and the secondary suspension only handles the rotation, thereby further increasing the relative displacement and rotation angle between the vehicle body and the bogie when the vehicle negotiates a curve.

Disclosed is a bolster of a bogie, wherein a secondary suspension connected with a transverse beam of the bogie is arranged below the bolster, and a third suspension connected with a vehicle body is arranged above the bolster. The bolster of the bogie of the present invention realize a functional separation by adding a suspension between the bottome of the bolster and the transverse beam to make the frame and the vehicle body be connected through a two-stage suspension, so that the third suspension above the bolster is only used to undertake a transverse displacement function, and the secondary suspension under the bolster is only used to undertake a rotation function, thereby further increasing displacement and relative rotation angle between the vehicle body and the bogie when the vehicle passes through a curve, and improving curve passing capability of the vehicle.

A wear liner installs into a bolster center bowl without the need for welding. The wear liner includes an annular wall forming an open-ring shape that defines a gap between two edges of the wall. The wear liner has one or more protrusions that extend outwardly from the annular wall. The protrusions are sized to engage with a corresponding recess in the center bowl. The wear liner is compressible by drawing the annular wall toward a closed-ring configuration so that the wear liner can be inserted into the center bowl while exerting an expansive, radially outward force. Upon expanding, and the protrusions engage with the recess or recesses in the peripheral wall of the center bowl. This engagement, along with the expansive pressure of the wear liner against the peripheral wall of the center bowl secures the wear liner in place.

A wear liner installs into a bolster center bowl without the need for welding. The wear liner includes an annular wall forming an open-ring shape that defines a gap between two edges of the wall. The wear liner has one or more protrusions that extend outwardly from the annular wall. The protrusions are sized to engage with a corresponding recess in the center bowl. The wear liner is compressible by drawing the annular wall toward a closed-ring configuration so that the wear liner can be inserted into the center bowl while exerting an expansive, radially outward force. Upon expanding, and the protrusions engage with the recess or recesses in the peripheral wall of the center bowl. This engagement, along with the expansive pressure of the wear liner against the peripheral wall of the center bowl secures the wear liner in place.

A system and method for manufacturing and/or reconditioning side frames and bolsters for railway cars includes at least one robot adapted to access positions along the length of the part. A map of the part dimensions, which may be obtained by a probe or scanner on the robot(s), allows a processor to determine where welding and machining are required to meet certain dimensional tolerances, leveraging novel reference surfaces on the part which cannot be leveraged using conventional gauges. The robot(s) may locate and mount welding and material removal tools to carry out the welding and material removal operations determined by the processor.

A suspension system for a railway vehicle includes a hub assembly configured to travel along a track, a suspension element coupled to the hub assembly and configured to provide a suspension force, a regulator coupled to the suspension element and configured to selectively adjust the suspension element, and a processing circuit. The processing circuit is configured to determine a target configuration for the suspension element using a characteristic of the track at a target position, the target position selected based on a location of the railway vehicle, and engage the regulator based on the target configuration such that the suspension force applied by the suspension element is based on the location of the railway vehicle and the characteristic of the track.

A suspension system for a railway vehicle includes a hub assembly configured to travel along a track, a suspension element coupled to the hub assembly and configured to provide a suspension force, a regulator coupled to the suspension element and configured to selectively adjust the suspension element, and a processing circuit. The processing circuit is configured to determine a target configuration for the suspension element using a characteristic of the track at a target position, the target position selected based on a location of the railway vehicle, and engage the regulator based on the target configuration such that the suspension force applied by the suspension element is based on the location of the railway vehicle and the characteristic of the track.

A railway truck to railway car body interface is provided. The railway truck is comprised of a bolster supported between two sideframes. The truck bolster includes a center bowl, and the car body includes a body bolster opening. A center plate is placed between the truck bolster center bowl and the car body bolster opening. A wear liner, usually comprised of an elastomeric material, is provided between the sides of the center bowl and the center plate.