EP3105102B1 - Method and device for standstill monitoring in rail vehicles - Google Patents

Description

The invention relates to a method for standstill monitoring in rail vehicles with a train control device and a related device.

Modern train control devices require accurate location information of both parked and moving rail vehicles. Conventional train control systems are increasingly supplemented or superseded by radio-based train control systems. In radio-based train control systems, such. B. ETCS - European Train Control System - Level 2, driving licenses are determined in a trackside control center and the individual rail vehicles transmitted by radio. The driving permit contains, among other information, the speed profile of the route and the distance between the current position and the next monitored stopping place. During the journey, a vehicle device determines the distance traveled and prevents by timely automatic control of the brake exceeding the permissible speed and driving past the monitored stopping place. A prerequisite for the safe operation of these train control systems is that in the trackside control center, the actual current position of the rail vehicle is known so that the distance can be calculated up to the stop for the to be transmitted driving license. The vehicle position is usually determined by means of track-side reference points, for example location balises. A path measuring device of the vehicle continuously determines the relative position of the vehicle to the reference point and transmits the position data to the line center.

So far, however, it is not possible to determine even when the vehicle device is switched off, whether in this operating condition assumed standstill of the rail vehicle was actually complied with. If rail vehicles are completely switched off at the end of operation at parking positions, the exact safety-related traction position is lost for the train control. After restarting the rail vehicle, the safety-technical position of the vehicle is not known and the initialization of the vehicle position can only be determined by driving over at least two location reference points, for example, balises. Only then can the vehicle be put into operation from the train control viewpoint. This means that vehicles in parking positions may not be switched off completely; at least the train control must remain active. The disadvantage is above all the required considerable energy consumption.

Another possibility is that the rail vehicle stores its fuse-technical position before switching off and this position is used after restarting as initialization position. Necessary securing technical condition for the usability of the stored vehicle position is that the vehicle has not been moved when the vehicle equipment is switched off - Cold Movement Detection - CMD. Nevertheless, if a movement of the rail vehicle, for example by towing, the use of the original position for initialization purposes by staff must be prevented. This non-technical solution is often not feasible in reality.

To solve the problem, additional reference points are often installed at the planned depots. These reference points must first be passed to confirm the correctness of the stored position. The disadvantage here is especially the need to keep a considerable track length between the reference point and the actual starting point. Sidings may need to be extended for longer vehicles or the vehicle length may need to be limited. Another disadvantage is that the journey must take place up to the reference point, that is, up to the position detection, under driver responsibility. Only after the passage of the reference point can a driving license due to the position initialization be given by radio, while previously there is no technical backup and the vehicle speed must be very low.

In the EP 2 502 800 A1 and ETCS: "System and requirements and specifications" from the European Rail Research Institute describes rolling stock monitoring of rolling stock.

At ETCS, another trackside solution is the installation of switchable ETCS Level 1 balises. In this case, when entering the balise, the vehicle facility will initially receive an ETCS Level 1 Driving Permit. Subsequently, the radio control center issues an ETCS Level 2 driving license. The disadvantage is above all the considerable expense, since inter alia a balise control unit including cable laying to the balise and a connection circuit for transmitting an optical signal term to the balise control unit are required. In addition, the acceptance of the ETCS in Level 1 configuration is often low for infrastructure managers.

It would be possible to use the GPS - Global Positioning System - to determine the parking place before switching off the vehicle equipment and store retentive and after switching on the current location to determine and compare with the stored location. The problem with this is, however, that in a large number of Abstellorten no sufficiently strong satellite signal is available, for example in maintenance halls and covered or underground stations.

The invention is therefore an object of the invention to provide a method and apparatus for standstill monitoring in rail vehicles, a complete shutdown allow all electrical components of the rail vehicle during the standstill phase, the required security for moving out of the standstill position without staffing or additional landmarks can be guaranteed.

According to the method, the object is achieved by the method according to claim 1, wherein the standstill position of the rail vehicle and switch positions of at least one vehicle-side inertia detector are detected.

The object is achieved according to claim 3, by an apparatus in which the vehicle side an inertia detector is provided which has two consecutively arranged in the direction of travel permanent magnets whose magnetic field in the stationary position of the rail vehicle by means of energizable coils can be compensated, whereby a movable between the permanent magnet metal body a Position between the permanent magnet occupies and is attracted by one of the two permanent magnets during movement of the rail vehicle due to inertia and thereby actuates a switch.

The rail vehicle stores its fuse-technical standstill position before switching off the vehicle device. In addition, the switch positions of the inertial sensor are monitored. After the vehicle device is switched back on, the current switch positions, which depend on whether the metal body has actuated the switch or not, are detected and compared either manually or automatically with the expected value, namely no change in the switch positions. If the latter is the case, during the off state no movement of the rail vehicle has taken place and the stored vehicle position can be used for safety purposes. Consequently, the rail vehicle is already reliably located or initialized before departure, that is to say still at a standstill.

In this way, the stored vehicle position is assessed by an additional criterion fuse technology. Thus, a technical solution is available through which the stored vehicle location can be plausibility check plausibility, so that personnel deployment to ensure safety is not required.

According to the invention it is provided that a movable metal body, which remains at vehicle standstill between two permanent magnets, is attracted to inertia by one of the two permanent magnets during vehicle movement and thereby actuates the switch. By utilizing the inertia of the metal body movably mounted in a detector housing, a permanent registration of a detected movement of the rail vehicle is possible. The metal body is held by one of the two permanent magnets in an end position, wherein the associated switch is actuated. For this registration process no electrical energy is needed. Two permanent magnets are required so that a movement detection in both directions of travel of the rail vehicle is possible.

1. 1. Anhalten des Schienenfahrzeuges an der Stillstandsposition,
2. 2. remanentes Speichern der Stillstandsposition,
3. 3. kurzzeitiges Bestromen zweier den Permanentmagneten zugeordneter Spulen mittels einer Fahrzeugeinrichtung derart, dass der Metallkörper mittig zwischen den Permanentmagneten verharrt,
4. 4. Speichern der Schalterstellungen,
5. 5. Herunterfahren der Fahrzeugeinrichtung,
6. 6. Beenden der Stillstandsphase durch Hochfahren der Fahrzeugeinrichtung,
7. 7. Vergleichen der aktuellen Schalterstellungen mit den gespeicherten Schalterstellungen und
8. 8. Bewerten der gespeicherten Stillstandsposition als gültig bei Gleichheitsfeststellung in Schritt 7 und als ungültig bei Ungleichheitsfeststellung in Schritt 7.

For carrying out the method according to the invention for standstill monitoring of the rail vehicle with inertial utilization, the following steps are provided according to claim 2:

1. 1. stopping the rail vehicle at the standstill position,
2. 2. retentive storage of the standstill position,
3. 3. brief energization of two coils associated with the permanent magnets by means of a vehicle device such that the metal body remains in the middle between the permanent magnets,
4. 4. Save the switch positions,
5. 5. Shutting down the vehicle equipment,
6. 6. ending the standstill phase by starting up the vehicle equipment,
7. 7. Compare the current switch positions with the stored switch positions and
8. 8. Evaluate the stored standstill position as valid for equality determination in step 7 and invalid for inequality determination in step 7.

In particular, for efficient ETCS level 2 operation, it is necessary for the ETCS vehicle unit to be able to determine whether the rail vehicle has been moved since the ETCS vehicle device was turned off. There are very high demands on the security level. Without standstill monitoring, after the ETCS vehicle device has been switched on, the rail vehicle must first drive in driver's responsibility until clear localization of the rail vehicle is possible on the basis of balise information and thus the prerequisite for ETCS level 2 operation is met. A safe operation without Balisenüberfahrt minimizing driver responsibility is possible only by the standstill monitoring invention.

Figur 1

einen Detektor zur Feststellung einer Bewegung und

Figur 2

den Detektor gemäß Figur 1 bei festgestellter Bewegung.

The invention will be explained in more detail with reference to figurative representations. Show it:

FIG. 1

a detector for detecting movement and

FIG. 2

the detector according to FIG. 1 with detected movement.

In the illustrated detector embodiment, a metal body 1 is mounted in a housing 2 such that it is freely movable on a fixed path 3 between two permanent magnets 4. The housing 2 is fixed in or on a rail vehicle, wherein the orientation of the housing 2 allows movement of the metal body 1 parallel to the direction of movement of the rail vehicle. For this purpose, the metal body 1 is attached to a pendulum 5 with pivot point 6. The permanent magnets 4 are each surrounded by a current-carrying coil 7, which is dimensioned so that at current flow, the magnetic field of the permanent magnet 4 is canceled by the magnetic field of the coil 7. The current flow of the coils 7 can be switched on and off by the vehicle device. When energized coil 7 of the metal body 1 is attracted due to the reversed magnetic field of none of the two permanent magnets 4 and thus automatically by gravity into a Central position moves in FIG. 1 is shown. The distance of this central position to the two permanent magnets 4 is so great that the force of the magnetic field of the permanent magnets 4 after switching off the current flow of the coil 7 is not sufficient to move the metal body 1 from the central position. If the rail vehicle is moved in this state of the detector, the inertia initially leads to the metal body 1 in the middle position according to FIG. 1 remains, but at the same time relative to the detector housing 2, a movement of the metal body 1 along the web 3 takes place. As a result, the metal body 1 gets into the magnetic field of one of the two permanent magnets 4 and is attracted and held by this, as FIG. 2 shows. In this position, the metal body 1 actuates a switch 8.

• Nachdem das Schienenfahrzeug die Stillstandsposition erreicht hat, wird die Fahrzeugeinrichtung heruntergefahren. Während des Herunterfahrens speichert die Fahrzeugeinrichtung die Stillstandsposition in einem remanenten Speicher. Außerdem erzeugt die Fahrzeugeinrichtung einen kurzzeitigen Stromfluss durch die Spulen 7 des Trägheitsdetektors, wodurch der Metallkörper 1 eine Mittellage zwischen den beiden Permanentmagneten 4 einnimmt. Nach dem Abschalten des Stromflusses in den Spulen 7 überprüft die Fahrzeugeinrichtung, ob sich der Metallkörper 1 in der vorgesehenen Mittellage befindet, indem die Kontaktlage der Schalter 8 festgestellt wird. Dadurch wird sichergestellt, dass der Metallkörper 1 tatsächlich die Mittelstellung eingenommen hat und somit der Trägheitsdetektor aktiv ist, bevor die Fahrzeugeinrichtung komplett heruntergefahren wird.

The operation of the illustrated inertia detector for standstill monitoring of a rail vehicle is based on the following procedure:

• After the rail vehicle has reached the standstill position, the vehicle device is shut down. During shutdown, the vehicle device stores the standstill position in a remanent memory. In addition, the vehicle device generates a short-term current flow through the coils 7 of the inertia detector, whereby the metal body 1 occupies a central position between the two permanent magnets 4. After switching off the current flow in the coil 7, the vehicle device checks whether the metal body 1 is in the intended center position by the contact position of the switch 8 is detected. This ensures that the metal body 1 has actually taken the middle position and thus the inertial detector is active before the vehicle device is completely shut down.

After completion of the standstill phase, the vehicle device is raised again, the contact position of the switch 8 is detected. Corresponds to the contact position of stored contact position at the beginning of the standstill phase, the remanently stored standstill position is evaluated as a valid position of the rail vehicle. However, the metal body 1 is in an end position, the in FIG. 2 is represented, the remanently stored standstill position is evaluated as invalid.

The vehicle-side inertia detector increases the performance for the initialization of parked rail vehicles, for example in a vehicle depot, since the standstill position can be reliably verified by signal technology so that the rail vehicle can be taken over immediately after startup of the vehicle device in the fully monitored operation. In the standstill position, the rail vehicle can be completely switched off, so that the energy requirement decreases and still immediate fully monitored operation is possible after restarting.

Claims (3)

1. Method for standstill monitoring in rail vehicles with an automatic train control device,
   characterised in that
   the standstill position of the rail vehicle and a switch setting of at least one vehicle-side inertia detector are determined, wherein
   a moveable metal element (1), which remains between two permanent magnets during a vehicle standstill, is pulled due to inertia forces by one of the two permanent magnets (4), when the vehicle moves, and in such a way actuates the switch (8) .
2. Method according to claim 1,
   characterised by
   the following steps:

   1. stopping the rail vehicle at the standstill position

   2. remanent storage of the standstill position,

   3. briefly energising two of the coils (7) assigned to the permanent magnets (4) using a vehicle device, such that the metal element (1) remains centrally between the permanent magnets (4),

   4. storing the switch settings,

   5. shutting down the vehicle device,

   6. terminating the standstill phase by starting up the vehicle device,

   7. comparing the current switch settings with the stored switch positions and

   9. assessing the stored standstill position as valid when consistency is determined in step 7 and as invalid when inconsistency is determined in step 7.
3. Device for standstill monitoring in rail vehicles with an automatic train control device,
   characterised in that
   an inertia detector is provided on the vehicle side, which has two permanent magnets (4) arranged one behind the other in the direction of travel, the magnetic field of which in the standstill position of the rail vehicle can be compensated by means of energisable coils (7), as a result of which a metal element (1) which can be moved between the permanent magnets (4) assumes a position between the permanent magnets (4) and is pulled due to inertia forces by one of the two permanent magnets (4), when the rail vehicle moves, and in such a way actuates a switch (8).

Images