DE2612581B2 - Damping device in a track-bound magnetic levitation vehicle - Google Patents

Description

The invention relates to a damping device in a track-bound magnetic levitation vehicle, in which a chain of superconducting excitation coils is arranged in the vehicle, while In the route guide coils are laid in the form of a closed figure eight, the cross conductor of which is essentially transverse to the direction of travel and their inner and outer longitudinal conductors essentially parallel to the direction of travel run and their inner longitudinal conductors cross each other insulated.

Magnetic levitation vehicles that are driven by synchronous linear motors, for example Support and guide devices proposed that according to the so-called normal flow method, the Work zero flow method or the differential flow method. In a known, according to the differential flow method working guide devices are along the route on both sides of the traction vehicle as Short-circuit coils formed guide coils arranged in the form of a closed figure eight, while the superconducting excitation coils in the traction vehicle have a rectangular shape (US Pat. No. 3,470,828, FIG. 7). In addition to braking forces and load-bearing forces, there are mainly lateral forces that are used to guide the Vehicle can be used, as they act as a restoring device in the event of a lateral deflection of the vehicle Forces work.

In the event of lateral deflections of the vehicle and the action of the electrodynamic differential flow guide device exerted restoring side forces result in horizontal vibrations of the vehicle. It is the task of the present Invention to dampen these horizontal vibrations.

According to the invention it is proposed for this purpose that additional damping coils below the vehicle Excitation coils are arranged, the shape of which corresponds to the shape of the guide coils, and with currents are fed, the current intensity depending on one of the lateral deflection of the vehicle gained size is put. With the help of the damping coils, the flux linkage between the excitation coils and the guide coils changed.

This creates additional side forces that are superimposed on the currents in the damping coils Damping control loop can be controlled. A measured value for the lateral Deflection of the traction vehicle or a lateral

Derivation of the deflection are fed. The damping coils can be designed to be normally conductive will. It can be sufficient if the number of damping coils is less than the number of Excitation coils.

An embodiment of the invention is shown in the drawing and will be described in more detail below described. Show it

F i g. 1 is a schematic representation of a magnetic levitation vehicle with a differential flow guide device,

2 shows a schematic representation of an arrangement of the excitation coil, guide coil and damping coil.
F i g. 1 shows a magnetic levitation vehicle 5 with a differential flux guide device over a route 4. A chain of superconducting excitation coils 2 is arranged in the magnetic levitation vehicle, while guide coils 1 are laid in the route in the form of a closed figure eight. The transverse conductors of the guide coils run essentially transversely to the direction of travel. The outer and inner longitudinal conductors of the guide coils run essentially parallel to the direction of travel. The inner longitudinal conductors of the guide coils cross each other in an electrically insulated manner

F i g. 2 shows a section of an excitation coil 2 above a guide coil 1. Below the excitation coil 2, a damping coil 3 is arranged, which has the same shape as the guide coil 1. the Excitation coil 2 is fed with a current / 2. the

^ o Excitation coil 2 generates the magnetic partial fluxes Φ ₂ ι »and Φ ₂ ιλ in the guide coil 1. If there is no lateral deflection of the excitation coil 2 with respect to the guide coil 1, the two partial flows are equal and stand out because of the different

♦ 5 rotation direction in the reel halves \ a and \ b of the guide reel 1 on each other in their effect. If, on the other hand, the excitation coil 2 is shifted laterally in the Y direction, a flux difference results between the two partial fluxes. This flow difference has the

so desired restoring side force result.

To dampen the restoring side force, the damping coil 3 is supplied with an adjustable current / 3 fed. This calls the additional partial flows Φ31 · and Φ316 are directed in such a way that the from the The flux 21 "originating from the excitation winding and the flux Φ31" originating from the damping coil are in the same direction superimposed, while the flux originating from the damping coil Φ314 that of the excitation winding resulting flux Φ216 is in the opposite direction.

This creates additional damping forces.

The current / 3 in the damping coil 3 is preferably controlled by a damping circuit. Either measured values for the lateral deflection of the traction vehicle or temporal derivatives can be sent to this the lateral deflection, i.e. the lateral deflection speed or the lateral deflection acceleration are fed.

1 sheet of drawings

Claims (2)

Patent claims: 1. Damping device in a track-bound magnetic levitation vehicle, in which the im Vehicle a chain of superconducting excitation coils is arranged while in the route Guide coils are laid in the form of a closed figure eight, the transverse conductor of which is essentially transverse to the direction of travel and their inner and outer longitudinal conductors essentially parallel to the direction of travel run and their inner longitudinal conductors cross each other in isolation, thereby characterized in that in the vehicle (5) additional damping coils (3) below the excitation coils (2) are arranged, the shape of which corresponds to the shape of the guide coils (1), and with currents (73) are fed, the current intensity depending on one of the lateral deflection of the Vehicle gained size is provided. 2. Damping device according to claim 1, characterized in that a damping control loop is provided, which is a measured value for the lateral deflection of the vehicle or a temporal Derivation of the lateral deflection is fed.