EP2870044A2 - Method for controlling a magnetic rail brake device of a rail vehicle - Google Patents

Abstract

The invention relates to a method for controlling a magnetic rail brake device (1) of a rail vehicle, which device contains at least one solenoid (6) of a magnet rail brake (8), said solenoid being fed from an source of electrical energy (2) via an electrical connection (4), wherein upon a magnet rail brake activation signal the electrical connection (4) between the source of electrical energy (2) and the at least one solenoid (6) of the magnet rail brake (8) is established and upon a magnet rail brake de-activation signal same is disconnected, in order to excite the at least one solenoid (6) to generate a magnetic force or de-excite said at least one solenoid (6). According to the invention a) upon the magnet rail brake activation signal, the electrical connection (4) between the source of electrical energy (2) and the at least one solenoid (6) of the magnet rail brake (8), once established, is disconnected and re-established in a fixed sequence of cycles, or b) upon the magnet rail brake de-activation signal, the electrical connection (4) between the source of electrical energy (2) and the at least one solenoid (6) of the magnet rail brake (8), once disconnected, is established and disconnected again in a fixed sequence of cycles.

Description

 Method for controlling a magnetic rail brake device of a rail vehicle

The invention relates to a method for controlling a magnetic rail brake device of a rail vehicle, which includes at least one of an electric power source via an electrical connection solenoid of an electric magnetic brake, wherein the magnetic connection between the electric power source and the at least one magnetic coil of the magnetic track Magnetic rail brake is produced and separated on a Magnetschienenbrems- deactivation signal to energize the at least one magnetic coil for generating a magnetic force, according to the preamble of claim 1 and a magnetic rail brake device of a rail vehicle, which at least one of an electric power source via a electrically connected solenoid coil of an electric magnetic rail brake includes, and an electronic control device, wherein a in the Steuerein direction controlled magnetic rail brake activation signal out the electrical connection between the electrical energy source and the at least one magnetic coil of the magnetic rail brake made and on a controlled in the control device Magnetschienenbrems-

Deactivation signal is disconnected to energize or de-energize the at least one magnetic coil for generating a magnetic force, according to the preamble of claim 9.

 Such a magnetic rail brake device is known for example from DE 101 11 685 A1. The force-generating main component of an electric magnetic rail brake is the brake magnet. He is in principle an electromagnet, consisting of a rail in the direction

Bestätigungskopiel extending, carried by a magnetic coil body and a magnetic coil horseshoe-like magnetic core, which forms the base or carrier body. The horseshoe-shaped magnetic core forms pole shoes on its side facing the vehicle rail. The DC current flowing in the solenoid causes a magnetic voltage which generates in the magnetic core a magnetic flux which shorts across the rail head as soon as the brake magnet rests with its pole pieces on the rail. The located in the space between the pole pieces between bar made of non-magnetic material prevents the magnetic flux already short-circuits on the pole pieces. Due to the short-circuiting of the rail head magnetic flux magnetic attraction between the brake magnet and rail is achieved. Due to the kinetic energy of the moving rail vehicle, the magnetic rail brake is pulled over drivers along the rail. This results from the sliding friction between the brake magnet and rail in conjunction with the magnetic attraction a braking force.

Magnetic rail brakes are brought by switching on the excitation current, ie energized by the solenoid in the active state in which the braking force acts, or by switching off the excitation current, ie brought by the solenoid leakage in the deactive state in which no braking force acts. When the excitation current is switched on or off, the magnetic rail brake abruptly releases the braking force or relieves the rail vehicle abruptly of the braking force, which in each case brings about an undesired brake clamping pressure or brake release pressure. Such a jolt represents a hazard potential for the persons traveling along with the rail vehicle. The invention is based on the object, a method and an apparatus of the type mentioned in such a way that the jerk when turning on or off the magnetic rail brake is minimized.

 This object is achieved by the features of the independent claims 1 and 9.

Disclosure of the invention

 The invention is based on the idea that

 - the magnetic contact between the electric power source and the at least one magnetic coil of the magnetic rail brake in a predetermined sequence of cycles is disconnected and restored to the magnetic rail brake activation signal, as a means against the setting when switching on the magnetic rail brake Bremszuspannruck, or

- Once the separate electrical connection between the electric power source and the at least one magnetic coil of the magnetic rail brake in a predetermined sequence of cycles is made on the magnetic rail brake deactivation signal and disconnected again, as a means against the setting when switching off the magnetic rail brake Bremslöseruck.

A "magnetic rail brake activation signal" should be understood to mean a signal by which the magnetic rail brake is fundamentally engaged, in contrast to a "magnetic rail brake deactivation signal", a signal by which the magnetic rail brake is basically released. The magnetic rail brake deactivation signal can also be formed from the negation of the magnetic rail brake activation signal, ie as soon as the Magnetic rail brake activation signal is no longer pending, the magnetic rail brake deactivation signal is generated or formed for the fundamental release of the magnetic rail brake.

In other words, the excitation current of the magnetic coil or the voltage applied to the magnetic coil in the fundamental change from the activated (magnetic track brake activation signal) in the deactivated state (magnetic track brake deactivation signal) or vice versa controlled by a defined course. This is done in each case by repeated and short-term switching on and off of the excitation current of the solenoid, so that the excitation current and thus the braking force over a certain period of time is reduced from the maximum value to zero. The on / off periods or connection / disconnection periods are in a range that can be achieved with conventional electrical or electronic switches. Due to the slower construction or reduction of the braking force of the magnetic rail brake compared to the prior art, the Bremszuspannruck or Bremslöseruck is reduced, particularly high is the effectiveness of the method when the magnetic rail brake is used until the vehicle is stationary and the stepped shutdown of the excitation current in synchronization with the delay of the rail vehicle until the vehicle is stationary.

While so far due to the jerk when switching on and off the use of a magnetic rail brake when braking to a standstill was problematic, can now be used for braking to a standstill with the help of the invention magnetic rail brakes, either exclusively or in the context of brake blending together with other brakes which leads to a shortening of the braking distance. The measures listed in the dependent claims advantageous refinements and improvements of the invention specified in the independent claims are possible.

In response to a fundamental magnetic track brake deactivation signal, the excitation current is switched off and then switched on again by a switch over a defined time period before the last and final switch-off instant of the magnetic rail brake, in which the rail vehicle has just come to a standstill, the ratio between the Separating periods in which the magnetic coil is de-energized or disconnected from the electrical energy source, and the connection periods in which the solenoid is energized or connected to the electrical energy source, preferably in favor of the separation periods shifts until the excitation current and thus the braking effect practically Value reaches zero.

In other words, as the magnetic rail braking deactivation signal progresses over time, the separation periods in which the electrical connection between the solenoid and the electric power source is disconnected are preferably longer and the connection periods in which this electrical connection is made shorter.

Conversely, on a general magnetic track brake activation signal, as time progresses, the separation periods in which the electrical connection is disconnected are preferably shorter and the connection periods in which the electrical connection is made are preferably longer.

In order to avoid resonances, the period duration of each off / on or connection / disconnect cycle is preferably changed. The number of Cycles is of the inductance of the solenoid and the desired

Time until activation / deactivation dependent.

Particularly preferably, an evaluation of a speed signal representing the speed of the rail vehicle is made as to whether, at the time of generating the magnetic rail brake activation signal or the magnetic rail brake deactivation signal, the speed of the rail vehicle is between a lower limit speed and an upper limit speed, and if so: disconnect and restoring the once established electrical connection between the electrical energy source and the at least one magnetic coil of the magnetic rail brake in the predetermined sequence of cycles, and if not: maintaining the once established electrical connection until at least the rail vehicle is at rest, or manufacturing and re-establishing Separating the once separate electrical connection between the electrical energy source and the at least one magnetic coil of

Magnetic rail brake in the specified sequence of cycles, and if this is not the case: maintaining the separation of once disconnected electrical connection.

In other words, the inventive method is preferably in a speed range between a lower

Limit speed, this can also be equal to the vehicle standstill, and performed an upper limit speed, because on the one hand at higher speeds above the upper limit speed, a rapid onset of the magnetic rail brake is crucial, especially if the magnetic rail brake for an emergency or

Rapid braking of the rail vehicle is used. Then it comes to maximum braking power and the inventive switching on / off of the magnetic rail brake is not performed. On the other hand, at speeds of more than, for example, 50 km / h as the upper limit speed, a switch-on load entering when the magnetic rail brake is activated is relatively weak and therefore has little effect on comfort.

More preferably, the electrical connection once established or the electrical connection once disconnected between the electrical energy source and the at least one magnetic coil of the magnetic rail brake are disconnected and restored or established and disconnected for a predetermined period of time in the predetermined sequence of cycles.

According to a further development, the period of cycles of establishing the electrical connection and the period of cycles of disconnecting the electrical connection are each constant. Alternatively, the period of cycles of establishing the electrical connection and the period of cycles of disconnecting the electrical connection could each be varied, in particular to avoid vibration excitation in the resonance region.

According to a development, the fixed sequence of cycles of disconnecting and restoring the electrical connection is executed only once in response to the magnetic track brake activation signal. Analogously and preferably, the fixed sequence of cycles of recovering and disconnecting the electrical connection is also executed only once, even after the magnetic track brake deactivation signal. The invention also relates to an eddy current braking system of a railway vehicle, which includes a magnetic track brake device as described above.

The magnetic rail brake activation signal is preferably an emergency, rapid, forced or operating signal, ie, that the magnetic rail brake in the context of an emergency, quick or forced or service braking activated (magnetic track brake activation signal) or after such emergency, fast or forced or service braking is disabled (magnetic track brake disable signal).

For executing the method described above, a magnetic rail brake device is proposed, in which in the electrical connection between the electric power source and the at least one magnetic coil of the magnetic rail brake at least one switch is arranged, which is controlled by an electronic control device such that the above-described Behavior of the magnetic rail brake results. Furthermore, at least one speed sensor is provided for controlling a speed signal representing the speed of the rail vehicle in the control device.

The exact sequence of the method according to the invention for controlling a magnetic track brake device or the exact structure of the magnetic track brake device will be apparent from the following description of an embodiment.

drawing

In the drawing shows 1 is a circuit diagram of a magnetic rail brake device according to a preferred embodiment of the invention;

Fig. 2 is a voltage-time diagram showing the time course of a voltage applied to a solenoid of the magnetic rail brake device of Fig. 1;

3 shows a current-time diagram which represents the time profile of the exciter current of the magnetic coil of the magnetic rail brake device of FIG.

Description of the embodiment

The invention is embodied in an electric magnetic rail brake device 1, wherein the force-generating main component is a brake magnet, which is in principle an electromagnet consisting of a extending in the rail direction, carried by a magnetic coil body solenoid 6 and a horseshoe-like magnetic core, the basic or Carrier body forms. The horseshoe-shaped magnetic core forms pole shoes on its side facing the vehicle rail. The DC current flowing in the magnetic coil 6 causes a magnetic voltage which generates a magnetic flux in the magnetic core, which short-circuits over the rail head as soon as the brake magnet rests with its pole shoes on the rail. The intermediate strip of non-magnetic material located in the intermediate space between the pole shoes prevents the magnetic flux from short-circuiting via the pole shoes. Due to the short-circuiting of the rail head magnetic flux magnetic attraction between the brake magnet and rail is achieved. Due to the kinetic energy of the moving rail vehicle, the magnetic rail brake 8 via drivers along the rail drawn. This results from the sliding friction between the brake magnet and rail in conjunction with the magnetic attraction a braking force. The general structure and the general operation of such magnetic rail brake devices are well known, so it should not be discussed further.

1, the magnetic rail brake device 1, therefore, a powered by an electric power source 2 via an electrical connection 4 solenoid 6 a magnetic rail brake 8, and an electronic control device 10. In this case, the electrical connection 4 between the electric power source 2 and the solenoid 6 of the Magnetic rail brake 8 made on a driven in the control device 10 magnetic rail brake activation signal out and disconnected to a controlled in the control device 10 Magnetschienenbrems- deactivation signal to energize the magnetic coil 6 to generate a magnetic force or deenergize. The electrical connection 4 between the electric power source 2 and the magnetic coil 6 of the magnetic rail brake 8 is realized by a corresponding electrical wiring 4.

In this case, in the electrical connection or wiring 4 between the electric power source 2 and the magnetic coil 6 of the magnetic rail brake 8, an electrical or electronic switch 12 is arranged, which of the control device 10 for producing or separating the electrical connection 4 between the solenoid 6 and electrical Power source 2 is controlled. The switch 12 may be, for example, a relay.

Furthermore, at least one speed sensor 14 for the control of one representing the speed of the rail vehicle Speed signal provided in the control device 10. For this purpose, an electrical signal line 16 is pulled from the speed sensor 14 to the electronic control device 10.

The magnetic rail brake activation signal is preferably an emergency, quick, forced or service brake signal, that is to say that the magnetic rail brake is activated or deactivated during emergency, quick, forced or service braking. For this purpose, the electronic control device 10 is connected via a further electrical signal line 18 to a brake control plane 20, which receives the command for activating or deactivating the corresponding type of brake, for example, via a safety loop or a vehicle data bus.

The control routines implemented in a memory of the control device 10 are designed in such a way that the switch 12 arranged in the electrical connection 4 between the electrical energy source 2 and the magnetic coil 6 of the magnetic rail brake 8 is activated in such a way that the magnet rail brake activation signal is produced once electrical connection 4 between the electric power source 2 and the solenoid 6 of the magnetic rail brake 8 is separated and restored in a fixed sequence of cycles.

In other words, the electrical connection 4 is produced by closing the switch 12 and the magnetic rail brake 8 is initially activated or clamped to a basic magnetic rail activation signal, for example in the context of emergency braking. Thereafter, the once established electrical connection 4 between the electric power source 2 and the solenoid 6 of the magnetic rail brake 8 in a predetermined sequence of cycles separated and restored, each by a corresponding control of the switch 12th

On the other hand, in response to a fundamental magnetic track brake deactivation signal, for example, when a once initiated braking or emergency braking is to be canceled altogether, the electrical connection 4 between the power source 2 and the magnetic coil 6 of the magnetic rail brake 8 in a predetermined sequence of cycles made and separated.

In other words, in response to a fundamental magnetic track brake deactivation signal, e.g. to completely dissolve an emergency braking located in the course by opening the switch 12 or disconnecting the electrical connection 4, the magnetic rail brake 8 is first deactivated or released. Thereafter, the once separate electrical connection 4 between the electric power source 2 and the magnetic coil 6 of the magnetic rail brake 8 in a predetermined sequence of cycles is prepared and separated, each by a corresponding control of the switch 12 by the control device 10th

This type of cyclical control of the magnetic rail brake 8 is preferably speed-dependent, i. depending on the speed of the rail vehicle prevailing at the time of the generation of the magnetic rail brake activation signal or magnetic rail brake deactivation signal, wherein the speed sensor 14 of the control device 10 delivers a corresponding speed signal.

The control device 10 is designed to carry out an evaluation of the speed signal as to whether at the time of the generation of the magnetic rail brake activation signal or the Magnetic rail brake deactivation signal is the speed of the rail vehicle between a lower limit speed and an upper limit speed. The upper limit speed is for example 50 km / h.

If this is the case in the context of a pending magnetic track brake activation signal, then the switch 12 is controlled by the control device 10 so that the once established electrical connection 4 between the electric power source 2 and the magnetic coil 6 of the magnetic rail brake 8 in the specified sequence of cycles is disconnected and restored. If this is not the case, the switch 12 is controlled by the control device 10 in such a way that the electrical connection 4 once made is maintained and the magnetic rail brake 8 is thereby kept permanently tensioned, for example until at least the stoppage of the rail vehicle.

If this is the case in the context of a pending magnetic track brake deactivation signal, then the switch 12 is controlled by the control device 10 so that the once separate electrical connection 4 between the electric power source 2 and the solenoid 6 of the magnetic rail brake 8 in the specified sequence of cycles produced and separated again. If this is not the case, the switch 12 is controlled by the control device 10, that the separation of the once separate electrical connection 4 is permanently maintained and the magnetic rail brake 8 remains thereby solved.

Particularly preferably, the electrical connection 4 once made or the once separate electrical connection 4 between the electrical energy source 2 and the magnetic coil 6 of the magnetic rail brake 8 via a predetermined period of time in the specified sequence of cycles separated and restored or manufactured and separated again. This fixed period of time is measured from the time of the generation of the magnetic track brake activation signal or the magnetic track brake deactivation signal.

The cycles of switching off / on or the connection / disconnection can alternatively also be carried out without a time limit such that an average current in a range of 10% to 90% of the rated current of the magnetic rail brake is established. For cycles with no time limit, the duty cycle and the period may preferably vary in relation to each other such that the average current remains constant, but resonance frequencies are avoided.

Furthermore, in response to the magnetic rail brake activation signal, the predetermined sequence of cycles of disconnecting and restoring the electrical connection may be performed only once. Analogously and preferably, the fixed sequence of cycles of recovering and disconnecting the electrical connection is also executed only once, even after the magnetic track brake deactivation signal.

In Figure 2 is a voltage-time diagram is shown, which shows the time course of a voltage applied to the magnetic coil 6 of the magnetic rail brake 8 of Figure 1 voltage when the solenoid 6 is energized or de-energized as described above. 3 shows the corresponding current-time diagram, which represents the resulting temporal course of the excitation current of the magnetic coil 6. As a starting point, it is assumed in this example that the speed of the rail vehicle equipped with the magnetic rail brake device is greater than the lower limit speed of approximately 5 km / h and also greater than an upper limit speed of approximately 50 km / h, so that the speed sensor 14 sends a corresponding signal to the controller 10. Furthermore, the magnetic coil 6 of the magnetic rail brake 8 is de-energized because a Magnetschienenbrems- deactivation signal is present at the control device 10 or so far no magnetic track brake activation signal has been controlled in the control device 10. With reference to the diagrams of FIGS. 2 and 3, this state still exists until shortly before the time t.

If then at the time ti a basic magnetic track brake activation signal is controlled, for example in an emergency braking by a safety loop of the rail vehicle in the control device 10, the switch is controlled by the control device 10 in its closed position and the solenoid 6 of the magnetic rail brake 8 characterized first permanently with the a voltage U of, for example, 110 V applied, as is apparent from Fig.2. This voltage causes in the solenoid 6, slightly delayed, a current I, which during the connection period in which the solenoid 6 is connected through the switch 12 to the electrical energy source 2, ie in the period between ti and t ₂ up to approx 10A, as shown in Fig.3. Since the speed of the rail vehicle at the time ti of the activation of the magnetic rail brake is greater than the upper limit speed, the solenoid 6 is permanently subjected to the voltage U. There is preferably no cyclic timing. It is then assumed that, in the period between ti (activation of the magnetic rail brake) and a time t _2, wherein which is no longer present, the magnetic rail brake activation signal and generating a magnetic rail brake disable signal or formed (deactivation of the magnetic rail brake), the speed of the rail vehicle has fallen to a speed which is between the lower and the upper limit speed, for example at 30 km / h.

The time t ₂ therefore marks the time at which the magnetic rail brake deactivation signal is present or the magnetic rail brake activation signal is no longer present. At time t ₂ , therefore, the magnetic coil 6 is separated from the electrical energy source 2 by the switch 12, which is for this purpose controlled by the algorithm of the control device 10 accordingly.

After a separation time period between t ₂ and t3, the switch 12 is again controlled in the closed position at time t3, which in turn a voltage U preferably at the same level to the solenoid coil 6 during a connection period between t3 and rests. In this way arise cycles of the separation or connection of the magnetic coil 6 from and to the electric power source 2 to a time t ₅ at which the switch is the last time switched to the shutoff position to the magnetic coil 6 final of the electrical energy source 2 to disconnect and thus to de-energize. At time t ₅ , the rail vehicle is then already at a standstill and is held for example by a parking brake in the braked state; why a tensile stress retention of the magnetic rail brake 8 is not necessary. Is in this case are in the time window between t.2 and t ₅ with the lapse of time t is the separation time periods in which the electrical connection 4 between the magnetic coil and electric power source 2 is separated longer and the connection time periods in which this electrical connection 4 is made shorter, as in particular the voltage curve of Figure 2 shows. The temporal current profile is then, characterized by a certain time delay, characterized by a sawtooth profile, as Figure 3 shows.

In this case, the period P _e m of cycles of the production of the electrical connection 4 and the period P _out of cycles of the separation of the electrical connection 4 are preferably each constant and, for example, the same. Alternatively, the period P _e in and the period P _aU s may each be varied, in particular to avoid vibration excitation in the resonance region. The period Pein Paus a connection / disconnection cycle can vary, for example, from 50 to 2000 ms.

In summary, therefore, is out in the example of Fig.2 and Fig.3 to a magnetic rail brake activation signal for connection or switch-on ti and the subsequent Magnetschienenbrems- deactivation signal to the separation or switch-off time t.2 out over a defined period (t ₂ to t ₅ ) until the last and final disconnection or switch-off time t ₅ , in which the rail vehicle, for example, has just come to a standstill, the excitation current through the switch 12 cyclically off, on and off again. As a result, the Bremslöseruck resulting from the fundamental deactivation of the magnetic rail brake 8 on the magnetic rail brake deactivation signal is limited. In the example of Figure 2 and Figure 3, therefore, the case is considered in which the in-motion rail vehicle (also) is braked by the magnetic rail brake 8.

Furthermore, the case is conceivable in which the magnetic rail brake 8 is activated when a vehicle is in motion at a speed greater than the lower limit speed and less than the upper limit speed rail vehicle (magnetic rail brake activation signal), whereby an undesirable brake clamping pressure would arise.

Then, to reduce the Bremszuspannrucks or to avoid the connection between the electric power source and the magnetic coil of the magnetic rail brake 8 is also made in a predetermined sequence of cycles and disconnected again, as already described above. In this case, as the time t exceeds the magnetic track brake activation signal, the separation periods in which the electrical connection 4 between the magnetic coil 6 and the electric power source 2 is separated may be shorter and the connection periods in which this electrical connection 4 is made may be longer fail.

The invention described above is not only applicable to purely electric magnetic rail brakes 8 or magnetic rail brake devices 1. It can also be applied to electrically switchable permanent magnet rail brakes to create a magnetic opposing field to cancel the braking force effect. Magnetic rail brake device energy source

electrical connection

solenoid

Magnetic brake

control device

switch

speed sensor

signal line

signal line

Brake control level

Claims

claims

 1. A method for controlling a magnetic rail brake device (1) of a rail vehicle, which includes at least one of an electrical energy source (2) via an electrical connection (4) fed magnetic coil (6) of a magnetic rail brake (8), wherein on a magnetic rail brake activation signal out electrical connection (4) between the electric power source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) is prepared and separated on a magnetic rail brake deactivation signal to energize the at least one magnetic coil (6) for generating a magnetic force or to de-energize, characterized in that

a) on the magnetic track brake activation signal out the once established electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) is separated and restored in a predetermined sequence of cycles, or

b) on the magnetic track brake deactivation signal out the once separate electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) is made in a predetermined sequence of cycles and disconnected again.

2. The method according to claim 1, characterized by an evaluation of a speed of the rail vehicle representing speed signal in terms of whether at the time of the generation of the magnetic rail brake activation signal or the magnetic rail brake deactivation signal, the speed of Rail vehicle between a lower limit speed and an upper limit speed, and if so:

a) disconnecting and restoring the once established electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) in the predetermined sequence of cycles, and if this is not the case:

Maintaining the once established electrical connection (4) to at least standstill of the rail vehicle, or

b) establishing and reconnecting the once disconnected electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) in the predetermined sequence of cycles, and if not: maintaining the separation of the once separate electrical connection (4).

3. The method according to claim 1 or 2, characterized in that the once established electrical connection (4) or the once separate electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8). separated and restored or made and disconnected again over a predetermined period of time in the specified sequence of cycles.

4. The method according to any one of the preceding claims, characterized in that the period (P _e in) of cycles of the preparation of the electrical connection (4) and the period (P _out ) of cycles of the separation of the electrical connection (4) each set constant becomes.

5. The method according to any one of claims 1 to 3, characterized in that the period (Pein) of cycles of the preparation of the electrical connection (4) and the period (Paus) of cycles of the separation of the electrical connection (4) is varied in each case.

6. The method according to any one of the preceding claims, characterized in that the magnetic track brake activation signal with progressive time (t) the separation periods in which the electrical connection (4) is separated, shorter and the connection periods in which the electrical connection ( 4) is made longer.

7. The method according to any one of the preceding claims, characterized in that on the Magnetschienenbrems- deactivation signal with increasing time (t) the separation periods in which the electrical connection (4) is separated, longer and the connection periods in which the electrical connection ( 4) is made shorter.

8. The method according to any one of the preceding claims, characterized in that the magnetic track brake activation signal is an emergency, rapid, forced, or service brake signal.

Magnetic rail brake device (1) of a rail vehicle, which contains at least one magnetic coil (6) of a magnetic rail brake (8) fed by an electrical energy source (2) via an electrical connection (4), and an electronic control device (10), wherein an in the control device (10) the magnetic connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) is prepared and separated on a in the control device (10) controlled magnetic rail brake deactivation signal is separated the at least one magnetic coil (6) for generating a magnetic force to energize or de-energize, characterized in that in the electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) at least a switch (12) is arranged, which is controlled by the control device (10) such that

a) on the magnetic track brake activation signal out the once established electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) is separated and restored in a predetermined sequence of cycles, or

b) on the magnetic track brake deactivation signal out the once separate electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) is made in a predetermined sequence of cycles and disconnected again.

Magnetic brake device according to claim 9, characterized in that it includes at least one speed sensor (14) for controlling a speed signal representing the speed of the rail vehicle in the control device (10), the control device (10) being designed to evaluate the speed signal to that effect , if at the time of generation of the magnetic rail brake activation signal or the magnetic rail brake deactivation signal, the speed of the rail vehicle is between a lower limit speed and an upper limit speed, and if so:

a) driving the switch (12) by the control device (10) such that the once established electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) in the specified sequence of Cycles are disconnected and restored, and if not: driving the switch (12) by the control device (10) such that the electrical connection (4) once made is maintained until at least the stoppage of the rail vehicle, or

b) driving the switch (12) by the control device (10) such that the once separate electrical connection (4) between the electrical energy source (2) and the at least one magnetic coil (6) of the magnetic rail brake (8) in the specified sequence of Cycles are made and disconnected, and if this is not the case: driving of the switch (12) by the control device (10) such that the separation of the once separated electrical connection (4) is maintained.

11. Magnetic rail brake device according to claim 9 or 10, characterized in that the control device (10) controls the switch (12) such that the once established electrical connection (4) or the once separate electrical connection (4) between the electrical energy source (2 ) and the at least one magnetic coil (6) of the magnetic rail brake (8) over a predetermined period of time in the separated sequence of cycles and restored or manufactured and separated again.

12. Magnetic rail brake device according to one of claims 9 to 1 1, characterized in that the control device (10) controls the switch (12) such that the period (P _e i _n ) of cycles of making the electrical connection (4) and the Period (P _out ) of cycles of the separation of the electrical connection (4) is constant.

13. magnetic rail brake device according to one of claims 9 to 1 1, characterized in that the control device (10) the switch

(12) so as to vary the period (Pein) of cycles of establishing the electrical connection (4) and the period (P _aU s) of cycles of disconnection of the electrical connection (4), respectively.

14. Magnetic rail braking device according to one of claims 9 to 13, characterized in that the control device (10) controls the switch (12) such that the magnetic track brake activation signal with increasing time (t) the separation periods, in which the electrical connection ( 4) is shorter, and the connection periods in which the electrical connection (4) is made longer.

15. Magnetic rail brake device according to one of claims 9 to 14, characterized in that the control device (10) controls the switch (12) such that the magnetic track brake

Deactivation signal with increasing time (t) the separation periods in which the electrical connection (4) is separated, longer and Connection periods in which the electrical connection (4) is made shorter.

16. Magnetic rail brake device according to one of claims 9 to 15, characterized in that the magnetic track brake activation signal is an input into the control device emergency,

Forced, fast or service brake signal is.

17. Magnetic rail brake device according to one of claims 9 to 16, characterized in that the switch (12) is an electrical or electronic switch, which is electrically controlled by the control device.

18. Magnetic rail brake device according to one of claims 9 to 17, characterized in that on the Magnetschienenbrems- activation signal to the control device (10) the predetermined sequence of

Performs cycles of disconnecting and restoring the electrical connection only once.

19. Magnetic rail brake device according to one of claims 9 to 18, characterized in that on the Magnetschienenbrems-

Deactivation signal to the controller (10) performs the predetermined sequence of cycles of recovering and disconnecting the electrical connection only once.

20.Wirbelstrombremssystem a rail vehicle, characterized in that it contains a magnetic rail brake device according to one of claims 9 to 19.