EP2160301A2

EP2160301A2 - Rail vehicle with a wagon body and method for protective grounding of such a wagon body

Info

Publication number: EP2160301A2
Application number: EP08774225A
Authority: EP
Inventors: Andreas Kitzmüller; Rüdiger Polley; Franz-Josef Weber; Stefan Zebunke; Markus Matthias Gaudenz
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2007-06-28
Filing date: 2008-06-23
Publication date: 2010-03-10
Also published as: DE102007029850A1; RU2010102767A; CN101687466B; WO2009000809A2; AU2008267285B2; CN101687466A; US20100102643A1; WO2009000809A3; RU2465154C2; US7952849B2; AU2008267285A1

Abstract

The invention relates, inter alia, to a rail vehicle (10) with a wagon body (60) and with contact means (20, 30, 40, 50) which are connected to the wagon body and which remain in contact with at least one rail (15) on the track side during operation of the rail vehicle, wherein the wagon body and at least one of the contact means are connected to each other through an electrical resistance device (70). According to the invention, the resistance device (70) has a greater electric resistance (R1) in a voltage region (dU1) with low voltage than in a voltage region (dU2) with comparatively higher voltage.

Description

description

Rail vehicle with a car body and method for protective earth of such a car body

The invention relates to a rail vehicle with a car body and with the car body related contact means, such as wheels or wheelsets, which are in operation of the rail vehicle with at least one track side rail in contact, wherein the car body and at least one of the contact means an electrical resistance device are connected together.

Earthing concepts of today's electric and diesel-electric rail or railway vehicles must equally both the requirements of a trouble-free operating current feedback in the rail - so the operating grounding - and the requirements for effective contact protection - so the protective ground - account.

The contact protection requires the lowest possible possible connection of all metallic parts of the car body, which could be under tension in case of failure, with the Bahnerde, d. H. for example, the rails. Such an error case could be, for example, that a contact wire of a catenary of the route breaks and comes into contact with the car body. In such a case, namely, the car body would be under high voltage, if there is no efficient protective grounding.

A protective earthing is realized in prior art rail vehicles, for example via earth cables, which are connected to Radsatzkontakten the rail vehicle.

The invention has for its object to provide a rail vehicle, which has an even better grounding behavior than previous rail vehicles. This object is achieved by a rail vehicle with the features of claim 1. Advantageous embodiments of the rail vehicle according to the invention are specified in subclaims.

Thereafter, the invention provides that the resistance device in a voltage range with low voltage has a greater electrical resistance than in a voltage range with the other hand, higher voltage.

A significant advantage of the rail vehicle according to the invention is to be seen in that the resistance device has two different areas or operating modes, namely an operating range with a high electrical resistance and an operating range with a comparatively lower resistance. In normal operation of the rail vehicle, so if there is no high voltage applied to the car body, a very low protective grounding of the car body is not required and sometimes detrimental to the performance of the rail vehicle. Namely, if the electrical resistance between the car body and ground or the rails is too low, it may lead to the ingress of electrical parallel currents from the track, for example, currents of other rail vehicles, which are located in the same track circuit. Such a coupling of parallel currents will occur, in particular, when the electrical resistance of the track-side rails is greater than the electrical resistance of the rail vehicle or its car body thereon; because the electric current will divide according to the partial resistances in car body and rail. To avoid such intrusion of unwanted current into the car body, the earthing resistance should be as large as possible to ground the car body; At the same time, the earthing resistance between the car body and the track-side rails must of course not be too large, since otherwise in the case of a high voltage on the car body, no efficient protective grounding would take place. would be because the voltage drop across a high resistance grounding resistor would be too large.

At this point, according to the invention, provision is made for interposing a resistance device with a non-linear behavior between the car body and the track-side rails, which has two different electrical resistances or resistance ranges, namely a high-impedance resistor for the normal operation of the Rail vehicle and a low-resistance area in the event of a high-voltage accident.

Particularly in the case of long rail vehicles, the described resistance device is advantageous, because there the problem of coupling in parallel currents into the vehicle body occurs or can occur very frequently. By "long" rail vehicles, for example, rail vehicles are to be understood which have a length of more than 15 m, in particular more than 20 m Such rail vehicles can be formed, for example, by longer individual vehicles, by multiple units or by "normal" trains, which are electrically interconnected Have wagons and thus form a - seen electrically - uniform rail vehicle.

The contact means with which the rail vehicle makes an electrical contact with the track-side rails can be formed, for example, by wheels, wheel sets, chassis or bogies of the rail vehicle.

The resistance device is preferably dimensioned such that at voltages below a predetermined first limit voltage, in particular below 100 volts peak value, an electrical resistance between 33 mΩ and 100 mΩ occurs and that at voltages corresponding to the operating voltage of the rail vehicle, an electrical resistance of maximum 10 mΩ occurs. The resistance device can be formed in a particularly simple manner and thus advantageously by an ohmic resistance and a non-linear element connected electrically in parallel therewith. Such a nonlinear element can be formed, for example, by a voltage absorber, in particular a spark gap, which is triggered or ignited when a predetermined minimum voltage or ignition voltage is applied.

Alternatively or additionally, the resistance device may also comprise a varistor which has a lower electrical resistance at higher voltages than at low electrical voltages.

It is also possible that the resistance device a

Semiconductor circuit which turns on when applying a voltage to external terminals of the semiconductor circuit, when the voltage exceeds a predetermined breakdown voltage, while their resistance between see their outer terminals reduced.

As already stated above, the large electrical resistance is used at small car body voltages or in normal operation to avoid coupling of parallel currents. For this reason, it is considered to be particularly advantageous if at least in the central region of the rail vehicle, a corresponding non-linear resistance device is connected to the car body; because the coupling of parallel currents is particularly relevant for longer electrical distances in the car body, unless such a coupling is prevented by a correspondingly large ohmic resistance between the car body and rails.

Particularly preferably, all contact means which produce an electrical contact to the rails are connected to the car body by a corresponding resistance device with non-linear behavior. The invention further relates to a method for protective earthing a car body of a rail vehicle, in which the vehicle body is geer det via at least one electrical contact means with at least one track-side rail.

In order to ensure a secure protective grounding and at the same time to ensure that a coupling of parallel currents from a track-side rail in the car body prevented, at least minimized, is provided according to the invention that the protective earth at least one resistance device is used, which between the car body and the at least one contact means is connected and which has a greater electrical resistance in a voltage range with a lower voltage than in a voltage range with a higher voltage.

With regard to the advantages of the method according to the invention, reference is made to the above statements in connection with the rail vehicle according to the invention, since the advantages of the rail vehicle according to the invention substantially correspond to those of the method according to the invention.

The invention will be explained in more detail with reference to exemplary embodiments; thereby show by way of example

Figure 1 shows an embodiment of a rail vehicle according to the invention in longitudinal section on a track-side rail, Figure 2 shows an example of the electrical behavior of a resistance device of the rail vehicle according to Figure 1 and

3 shows the rail vehicle according to Figure 1 in cross section in a schematic representation.

For the sake of clarity, the same reference numerals are always used in FIGS. 1 to 3 for identical or comparable components. FIG. 1 shows a rail vehicle 10 which is located on rails 15 of a track bed 18. The rail vehicle 10 has wheels 20, 30, 40 and 50, which make an electrical contact to the rails 15 of the track bed 18.

In order to enable protective grounding of a car body 60 of the rail vehicle 10, individual or all wheels 20, 30, 40 and 50 are electrically connected to the car body 60.

Now flows an electric current through the rails 15 of the track bed 18, as indicated in Figure 1 by the reference numeral Ig, so a part II of this stream via the front wheels 20 and 30 in the car body 60 einkoppeln and again on the rear Pair wheels 40 and 50 back into the track bed 18. A current component II of the total current Ig would thus flow in the car body 60, parallel to the partial flow 12 flowing in the rails 15 of the track bed 18. It applies here:

Ig = Il + 12

The lower the electrical resistance of the car body 60 of the rail vehicle 10 compared to the electrical resistance of the rail 15, the greater the proportion of current Il relative to the current component 12 will be.

In order to keep the current component II in the car body 60 as low as possible, at least one of the wheels of the rail vehicle 10, more preferably each wheel, each connected via an electrical resistance device 70 to the car body 60, which has a "nonlinear behavior" and in one Voltage range with low voltage has a greater electrical resistance than in a voltage range with contrast higher voltage. The resistance device 70 ensures that during normal operation of the rail vehicle 10, a relatively large electrical resistance between the respective associated wheel and the car body 60 is caused, so that the total electrical resistance of the rail vehicle 10 is relatively large and the current component II relative to the current component 12th remains relatively small. Nevertheless, the resistance device 70 ensures efficient protective earthing of the car body 60, namely, in the case of a high voltage on the car body 60, this is efficiently forwarded via the resistance device 70 to the rails 15 and thus into the track bed 18. Such a high voltage could occur, for example, when a contact wire 80, shown only schematically in FIG. 1, of a catenary falls onto the rail vehicle 10 and thus puts the vehicle body 60 under high voltage.

FIG. 2 shows an exemplary embodiment of the electrical behavior of the resistance device 70 according to FIG. Shown is the electrical profile of the electrical resistance R over the voltage drop across the outer terminals of the resistance device 70 U. It can be seen that in a lower voltage range dUl below a voltage Us a relatively large electrical resistance Rl occurs; in a higher voltage range dU2 above a threshold voltage Us, the resistance reduces to a value R2.

Suitable ranges of values for Us, R1 and R2 are, for example:

dUl: 0 volts to 100 volts dU2: 100 volts to 100 kV

Rl: 33 mΩ to 100 mΩ

R2: 0 Ω to 10 mΩ Us: between dUl and dU2

An electrical behavior, as shown in Figure 2, for example, by an ohmic resistance Rl can be achieved, in which a non-linear element RnI, such as a surge arrester or a spark gap is connected in parallel (see Figure 3). Alternatively, such a resistance device 70 may also comprise a varistor or a corresponding semiconductor circuit which causes the correspondingly described electrical behavior.

In FIG. 3, the rail vehicle 10 according to FIG. 1 is shown by way of example in cross section. One recognizes the driving wire 80, with which either one of the two pantographs 90 can be brought into contact, which enable operation of the rail vehicle 10 either in alternating current operation or in DC operation.

With the two pantographs 90 is a drive circuit

100, which is housed in an electrically shielded container 110. The drive circuit 100 includes, for example, a four-quadrant controller 120, a drive controller 130, and a pulse inverter 140.

As can be seen in Figure 1, the container 110 is electrically connected to the car body 60 of the rail vehicle 10; from the car body 60, only one base plate is shown by way of example in FIG. The connection between see the car body 60 and the container 110 via a grounding line 150th

The car body 60 is connected via a pivot 160 to a bogie 170, in which a traction motor 180 is accommodated. The housing of the drive motor 180 is connected via a grounding line 185 to the bogie 170.

The bogie 170 is mechanically, but electrically isolated, supported by two wheels 20 and 20 'connected by an axle 190. The axle 190 is connected via a gear 200 and a clutch 210 to the traction motor 180, wherein the housing of the traction motor 180 is isolated via electrically insulated bearings 220 of the drive branch. In FIG. 3, electrically insulated bearings are marked by a thicker line than electrically non-insulated bearings. Incidentally, conductive material is hatched and non-conductive material 225 is marked black.

In addition, FIG. 3 shows a brake control unit 230, which is connected to a speed sensor 240, which measures the speed of rotation of the axis 190 and emits corresponding signals. Via a grounding line 250, the brake control unit 230 is electrically connected to the car body 60.

FIG. 3 also shows an exemplary embodiment of the resistance device 70 according to FIG. 1. It can be seen that the resistance device 70 is electrically connected between the vehicle body 60 and the axle 190 or the two wheels 20 and 20 '. The resistance device 70 comprises an ohmic resistor Rl and a non-linear resistor RnI connected in parallel thereto, which is formed, for example, by a spark gap.

During normal operation of the rail vehicle 10, the resistance device 70 has a relatively high electrical resistance R 1, so that an undesired flow of current through the wheels 20 and 20 'or the axis 190 through the resistance device 70 into the vehicle body 60 is avoided.

In the event of a high voltage on the car body 60, as might occur, for example, when the trolley wire 80 falls on the car body 60 of the rail vehicle 10, the high voltage is nevertheless efficiently dissipated by the resistance device 70, because this is at high electrical Strains over the spark gap RnI is low impedance in a sparkover and the high voltage via the wheels 20 and 20 'and in the rails 15 of the track bed 18 derived.

Claims

claims

A rail vehicle (10) having a car body (60) and contact means (20, 30, 40, 50) communicating with the car body and in contact with at least one track side rail (15) during operation of the rail vehicle, the car body and at least one of the contact means are connected to one another by an electrical resistance device (70), characterized in that the resistance device (70) has a greater electrical resistance (Rl) in a voltage range (dU1) with a low voltage than in a voltage range (dU2) In contrast, higher voltage.

2. Rail vehicle according to claim 1, characterized in that the at least one contact means is formed by a wheel, wheelset, chassis or bogie.

3. Rail vehicle according to one of the preceding claims, characterized in that the resistance device is dimensioned such that at voltages below 100 volts, an electrical resistance of at least 33 milliohms occurs and that at voltages corresponding to the operating voltage of the rail vehicle, an electrical resistance of maxi - times 10 mΩ occurs.

4. Rail vehicle according to one of the preceding claims, characterized in that the resistance device comprises an ohmic resistor (Rl) and a parallel thereto electrically nonlinear element (RnI).

5. Rail vehicle according to claim 4, characterized in that the non-linear element has a surge arrester, in particular a spark gap, which activates or activates upon application of a predetermined activation voltage.

6. Rail vehicle according to one of the preceding claims, characterized in that the resistance device comprises a varistor.

7. Rail vehicle according to one of the preceding claims, characterized in that the resistance device comprises a semiconductor circuit which turns on when a voltage is applied to external terminals of the semiconductor circuit above a predetermined turn-on voltage and reduces their Wi resistance between these outer terminals.

8. Rail vehicle according to one of the preceding claims, characterized in that at least one located in a central region of the rail vehicle contact means is electrically connected by a resistance device to the car body.

9. Rail vehicle according to claim 8, characterized in that the contact means located in the middle region of the rail vehicle is a middle wheel, wheel set, chassis or bogie.

10. Rail vehicle according to claim 9, characterized in that all wheels, wheelsets, chassis or bogies of the rail vehicle by one or more resistance means are electrically connected to the car body in connection.

11. Method for protective earthing a car body (60) of a rail vehicle (10), in which the vehicle body is grounded via at least one electrical contact means (20, 30, 40, 50) with at least one track side rail (15), characterized in that at least one resistance device (70) which is connected between the vehicle body (60) and the at least one contact means and which has a greater electrical resistance (R1) in a low-voltage voltage range (dU1) than in one is used Voltage range (dU2) with higher voltage.

12. The method according to claim 11, characterized in that at least one located in a central region of the rail vehicle contact means, in particular wheel, wheelset, chassis or bogie, is earthed.

13. The method according to claim 12, characterized in that all wheels, wheelsets, chassis or bogies of the rail vehicle by one or more resistance devices (70) are earthed.