Railway vehicle shaft box suspension type self-height-adjusting bogie

Abstract

The invention discloses a railway vehicle shaft box suspension type self-height-adjusting bogie. A spring deflection automatic adjusting device is arranged in the middle of a central square frame formed by two ends of a swing bolster of the bogie and a side frame. The device is mainly composed of an inner cylinder body, an outer cylinder body, an inner piston, an outer piston, a push-pull rod, a rubber bearing spring and a bearing top cover. Four hydraulic oil cavities enclose the device. A first one-way valve controlling break-make of a first hydraulic oil cavity and a second hydraulic oil cavity is arranged in an axial through hole of the inner piston. A second one-way valve controlling break-make of the second hydraulic oil cavity and a third hydraulic oil cavity is arranged in a through hole in the side wall of the bottom of the inner cylinder body. A circuit switch device controlling break-make of the first hydraulic oil cavity and a fourth hydraulic oil cavity is arranged at the top of the inner cylinder body. The fourth hydraulic oil cavity is directly communicated with the third hydraulic oil cavity. Through the dynamic balance function of the device in the vehicle body motion vibration process, the height difference between an empty vehicle and a heavy vehicle can be eliminated, working deflection of the bearing spring can be increased, and low power performance between wheel tracks can be improved to a maximum degree. The railway vehicle central suspension type self-height-adjusting bogie is especially suitable for bogies with big axle loads.

Description

Technical field [0001] The invention relates to a railway vehicle bogie, in particular to a railway vehicle axle box suspension type self-adjusting bogie. Background technique [0002] Railway vehicles are operated by the traction and braking adhesive friction generated by the interaction between the wheels on the bogie and the railway track. With the increase in the load of railway vehicles, the axle load of the vehicles also increases correspondingly, which will inevitably lead to an increase in the force between the wheels and the rails, thereby accelerating the wear of the wheels and rails. Practical experience has shown that when the axle load of a vehicle increases, the wheel-rail contact stress increases, and the longitudinal and lateral friction of the wheel tread and the wheel-rail side pressure increase accordingly, causing vertical wear, side wear and plastic flow of the rail. Increase, the wear of the wheel rim and tread also increases accordingly. [0003] In order t...

AI Technical Summary

Problems solved by technology

The three-piece bogie mainly uses the central bearing spring as the secondary suspension system. When the vehicle is running, the mass of the components below the secondary suspension system directly acts on the wheel rails without spring damping, so the distance between the wheel rails The vertical force of the truck is very large, which leads to the defects of such bogies as large unsprung mass, serious wheel and rail wear, and easy breakage of the coupler.

In this way, the action force between the wheel and rail cannot be effectively reduced when the vehicle is running with heavy loads, resulting in increased wear between the wheel and rail, shortening the service life of key components such as bolsters and side frames, and reducing the maintenance workload of the wheel and rail. and maintenance costs increased

At the same time, due to the coupler height difference between empty and heavy vehicles, the coupler is unevenly stressed, which is likely to cause coupler breakage accidents and affect the safety of vehicle operation.

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