Hybrid braking excitation structure for maglev train

Abstract

The invention discloses a hybrid braking excitation structure for a maglev train. Magnetic poles formed by electromagnets and permanent magnets are arranged along the rail direction and are installed on the bottom of the maglev train right over rails. Each magnetic pole comprises a core, an armature coil, and a permanent magnet. The cores are arranged at intervals along the rail direction. The horizontal periphery of each core is wrapped in the armature coil provided with exciting current. The top of each core is equipped with the corresponding permanent magnet such that the magnetic poles are formed. The top of the permanent magnets are equipped with a magnet yoke along the rail direction. The bottoms of the cores are equipped with a wearing plate. By means of the adjustment of exciting current in an exciting coil, a dynamic maglev train braking process is achieved. By means of reverse excitation, a braking system is simply repositioned. The magnetic force of the permanent magnets enhances eddy current braking control and friction braking effects. The hybrid braking excitation structure reduces the heating of the system, achieves an energy-saving effect and heat management of the system, and is provided with a braking operation mode with safe fault guidance.

Description

technical field [0001] The invention relates to a train braking structure, in particular to a hybrid braking excitation structure for a magnetic levitation train. Background technique [0002] As a new type of ground transportation, the maglev train has the advantages of fast speed, stable operation, low noise, and small environmental impact. Because of its high speed, the braking system of maglev trains is more complicated and important than that of ordinary trains. At present, maglev trains generally adopt a combination of dynamic braking, mechanical friction braking and eddy current braking. The dynamic braking method, that is, electric braking, changes the current phase sequence of the motor, so that the original motor output force is reversed into a braking force. It has the advantages of energy saving, environmental protection, and good control performance. However, due to capacity limitations, Safety considerations and requirements for trailer braking, emergency bra...

AI Technical Summary

Problems solved by technology

This kind of excitation structure uses the excitation current to perform braking control during the entire braking process, so the energy loss will be too high due to excessive excitation power, and the resulting heating of the excitation coil will affect the braking effect.

Secondly, when the power supply is cut off when the train is parked, the natural eddy current braking system cannot work

In addition, when the magnetic levitation train has some bad working conditions and the excitation circuit system loses power, the ordinary eddy current braking system will completely fail due to the lack of excitatio

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