DE102010004653A1 - Control method for rail vehicle, involves controlling automatic drive control to manual remote-drive control during transition of rail vehicle from free railway track to track close area - Google Patents

Abstract

The control method involves controlling an automatic drive control to a manual remote-drive control during a transition of a rail vehicle (S) from a free railway track (G) to a track close area (B). The controlling of the manual remote-drive control is switched on the automatic drive control during a transition of the rail vehicle from a track close area to a free railway track. An independent claim is also included for a control arrangement for a rail vehicle.

Description

The invention relates to a control method for a rail vehicle and to a control arrangement for carrying out such a method. There are already known control methods for rail vehicles, which allow a driverless rail traffic. Such a rail transport is especially desirable because cost savings for a rail vehicle operator can result from reduced personnel costs and weight savings on the rail vehicle by eliminating the control cabin. The latter aspect also makes it possible to increase the passenger capacity of the vehicle.

Examples of new rail vehicle systems already set up for driverless operation include the Transrapid in China, a Metro line in Paris and several other subway projects. However, the solutions described there are not suitable for retrofitting already existing rail vehicles, as used in nationwide regional and long-distance transport.

Proceeding from this, the present invention seeks to provide a control method and a control arrangement for a rail vehicle, which allow at least partially a driverless rail traffic. In addition, a simple conversion of existing rail vehicles for at least partially driverless traffic should be possible.

• – bei einem Übergang des Schienenfahrzeugs von einer freien Gleisstrecke zu einem Bahnhofsbereich die Steuerung von einer automatischen Fahrsteuerung zu einer manuellen Fern-Fahrsteuerung und
• – bei einem Übergang des Schienenfahrzeugs von einem Bahnhofsbereich zu einer freien Gleisstrecke die Steuerung von der manuellen Fern-Fahrsteuerung auf die automatische Fahrsteuerung umgeschaltet wird.

This object is achieved with respect to the control method by a control method for a rail vehicle, in which

• In a transition of the rail vehicle from a free track to a station area, the control of an automatic driving control to a manual remote driving control and
• - When a transition of the rail vehicle from a station area to a free track section, the control of the manual remote driving control is switched to the automatic driving control.

In this approach, the overall control method is divided into operating periods where there is automatic control and operating periods where manual control is selected and performed by remote control. The automatic driving control is established on the rail vehicle itself, while the manual control is made on a fixed location remote from the rail vehicle.

In the case of the automatic control system, a continuous monitoring of a travel path located in front of the rail vehicle is preferably carried out and, upon detection of an obstacle, switched over to the manual remote driving control. This takes into account the fact that unforeseen obstacles can occur even on free tracks between stations. In these cases, the automatic driving control is regularly not suitable to cope with the resulting driving situation. For this reason, it switches to the manual remote driving control. In a further continuation of this embodiment of the invention, a braking operation can be triggered upon detection of an obstacle by the automatic driving control for the rail vehicle.

The continuous monitoring of the lying in front of the rail vehicle route can be advantageously carried out with the help of a radar device. In this case, the automatic driving control evaluates the signals obtained from the radar device for any obstacles and causes a switch to the manual driving control upon detection of an obstacle.

The manual driving control of the rail vehicle is preferably carried out remotely from the rail vehicle on a virtual driver's cab and on the basis of up-to-date data representing a current driving situation of the rail vehicle and transmitted via a communication link to the virtual driver's cab. This means that the manual driving control, as required for example when entering a station area, away from the rail vehicle is feasible, so that can be dispensed with the equipment of the rail vehicle with a conventional cab.

In order to allow a driver who operates the virtual cab to perform the manual driving control, the current driving data is required, which are obtained on the rail vehicle itself. In this case, the data preferably contain image data from an environment of the rail vehicle, which are obtained from, with respect to the rail vehicle, outward-facing cameras. In this way, provided on the rail vehicle, typically predominantly forward-facing cameras replace the visual perception of a driver in conventional rail vehicles. If necessary, with the aid of suitable image processing software, these cameras can also assume the task of the radar described above for detecting unusual driving situations.

In addition, image data can be obtained from a camera which is equipped with a zoom Function is equipped. This embodiment is particularly important in cases in which the continuous monitoring of the lying in front of the rail vehicle route has resulted in an obstacle, so that was switched from the automatic to the manual driving control. In order to allow the driver on the virtual cab to accurately assess the driving situation, the camera equipped with the zoom function is used. It allows the driver to get an accurate picture of the detected obstacle.

To reproduce the current driving situation of the rail vehicle, it is advantageously possible to use two-dimensional or three-dimensional representations, which are designated, for example, by "virtual reality". This promotes an as realistic as possible reproduction of the driving situation in which the controlled rail vehicle is currently located for the driver who is located at the virtual driver's cab.

Preferably, the manual remote cruise control manually switches to the automatic cruise control. For example, if the driver on the virtual cab detects that a previously detected obstacle has safely passed, he switches to automatic driving control. This is typically transmitted by means of a suitable communication link to the rail vehicle. However, it is not excluded that the manual remote driving control is automatically ended.

• – einer auf dem Schienenfahrzeug angeordneten, automatischen Fahrsteuervorrichtung für eine freie Gleisstrecke und
• – einer entfernt von dem Schienenfahrzeug angeordneten manuellen Fahrsteuervorrichtung für einen Bahnhofsbereich, die einen virtuellen Führerstand umfasst, mit dem auf der Basis aktueller Daten, welche eine aktuelle Fahrsituation des Schienenfahrzeugs wiedergeben und über eine Kommunikationsverbindung von dem Schienenfahrzeug an den virtuellen Führerstand übermittelt werden, eine manuelle Fernsteuerung des Schienenfahrzeugs durchführbar ist.

With regard to the control arrangement, the above object is achieved by a control arrangement for a rail vehicle, with

• - An arranged on the rail vehicle, automatic driving control device for a free track and
• A manual travel control device for a station area arranged remote from the rail vehicle, comprising a virtual driver's cab, with which a manual transmission is made on the basis of up-to-date data representing a current driving situation of the rail vehicle and being transmitted via a communication link from the rail vehicle to the virtual driver's cab Remote control of the rail vehicle is feasible.

Such an arrangement is suitable for carrying out the control method previously explained in various embodiments. Preferred embodiments of the control arrangement result from the claims 11 to 16.

The arrangement may be further developed in that a passenger cabin of the rail vehicle is equipped with at least one emergency switch, the operation of which causes a manual changeover from the automatic to the manual control. This can be particularly useful when passengers recognize dangerous situations through windows of the rail vehicle.

The above-described procedures for establishing a control method for a rail vehicle provide a way to inexpensively and timely retrofitting existing, previously man-controlled rail systems for at least partially driverless traffic. Since manual remote drive control is provided for a vehicle Variety of rail vehicles can be provided at a central location, resulting in significant savings in the equipment of each rail vehicle. So can be dispensed with a variety of facilities that belong to the equipment package of a conventional cab. Even with additional installation of image data acquisition devices, which are conducive to the implementation of the control method, there are still significant cost savings.

In addition, the control of a rolling stock fleet is more efficient. For example, in the event that no unusual driving situations are detected, only as many vehicle drivers are required at one or more virtual control stations, as are necessary for a complete coverage of all concurrent station entrances. In this case, however, a personnel reserve would have to be provided for coping with unusual driving situations which require switching to manual control. By saving the cab, the passenger capacity of a rail vehicle increases. Also, the weight of the rail vehicle can be reduced, so that drive energy is saved.

An embodiment of the invention will be explained in more detail with reference to the drawings. The single figure shows a schematic representation of a rail vehicle in combination with a virtual cab.

The schematic representation of the figure shows a rail vehicle S, which is located in the illustrated driving situation just on a free part of a track G. A radar device R is used to monitor a driving route lying in front of the rail vehicle S. This radar device is designed, for example, to detect an obstacle H, as shown schematically in the figure.

As long as the rail vehicle S is on a free track and a Monitoring the track track lying ahead shows no obstacles, the rail vehicle is automatically controlled, with the help of a provided on the rail vehicle S automatic control device AS. In this case, predefined suitable driving parameters can be defined for predefined driving distances of the rail vehicle S, for example the vehicle speed.

The automatic control device AS is in a signal connection with the radar device R. As soon as the radar device R detects the obstacle H, the automatic control device AS triggers a braking process for the rail vehicle S.

Since hereby a driving situation has occurred, which is no longer manageable by the automatic control device AS, the control of the rail vehicle S is now switched to a manual control.

Since the rail vehicle is designed for predominantly automatic control, it has no driver's cab, as used in conventional rail vehicles. Rather, the data required for a manual vehicle control using a three-part in the present embodiment camera system K (A camera can be equipped with zoom function for optical reproduction of obstacles in detail.) And other detection devices for data, as are common in a rail vehicle , collected and transmitted via a wireless communication link V to a remote virtual cab F, with the aid of a vehicle-side antenna A1 and an antenna A2, which is provided on the virtual cab F. The virtual driver's cab F is designed in such a way that a vehicle driver located there using two- and / or three-dimensional image representations finds essentially the same work situation as if he were in the driver's cab of a rail vehicle. For these purposes, display instruments u. a. m. provided that allow it to manually control the rail vehicle S on the virtual cab F, again via the typical multi-channel communication link V.

As soon as a driving situation occurs, in which it is possible to dispense with the manual control and switch back to the automatic control, this is done, for example, manually by the vehicle driver on the virtual driver's cab F.

As soon as the rail vehicle S approaches a station area, it is also necessary to switch from the automatic control to the manual control with the aid of the virtual cab F.

The triggering event for the changeover to the manual control can result from a position monitoring of the rail vehicle in conjunction with a plan of the route network. The position of the vehicle is then constantly aligned with specified safety zones around stations. When a rail vehicle of a zone designated as "station" in the automatic driving control software approaches less than a predetermined distance of, for example, 600 m, the manual remote control is switched.

• a) Die Position des Schienenfahrzeugs wird per Satelliten-Ortung (GPS) erfasst.
• b) Zur Ortung des Schienenfahrzeugs werden bereits bestehende Positionsbestimmungssysteme für Schienenfahrzeuge genutzt, beispielsweise Gleisfreimeldesysteme.
• c) Eine Positionsbestimmung für das Schienenfahrzeug wird per Geschwindigkeits-Integral berechnet, wenn beispielsweise GPS-Daten aufgrund von Empfangsstörungen des Satellitensignals nicht zur Verfügung stehen. Bei dieser Variante zur Positionsbestimmung des Schienenfahrzeugs wird ausgenutzt, dass bei der automatischen Steuerung des Schienenfahrzeugs aufgrund von Sensoren ständig die Geschwindigkeit des Schienenfahrzeugs bekannt ist. In Verbindung mit einer digital vorliegenden Karte des Streckennetzes inklusive der oben beschriebenen Sicherheitszonen lässt sich mit Hilfe eines in der Fachwelt bekannten Geschwindigkeits-Integrals stets die aktuelle Position errechnen.

The position monitoring of the rail vehicle can be done in many ways. By way of example, three different methods are presented below:

• a) The position of the rail vehicle is detected by satellite positioning (GPS).
• b) For locating the rail vehicle already existing positioning systems are used for rail vehicles, such as train detection systems.
• c) A position determination for the rail vehicle is calculated by velocity integral, if, for example, GPS data is not available due to interference of the satellite signal. In this variant for determining the position of the rail vehicle is exploited that in the automatic control of the rail vehicle due to sensors constantly the speed of the rail vehicle is known. In conjunction with a digitally available map of the route network including the security zones described above, the current position can always be calculated using a speed integral known in the art.

In the manner already described above, after switching to the manual control, entry into the station B, stopping and exiting from the station B takes place with the aid of manual control of the virtual driver's cab F. After leaving the station B again switching to automatic control using the automatic control device AS.

In order to increase the safety of the overall "rail vehicle" system, the introduction of emergency switches in a passenger cabin of the rail vehicle is conducive. With the aid of the emergency switches, passengers can request a switch from automatic to manual control if, for example, they recognize dangerous situations through windows of the rail vehicle.

Claims (17)

Control method for a rolling stock (S), in which - In a transition of the rail vehicle (S) from a free track (G) to a station area (B), the control of an automatic driving control to a manual remote driving control and - When a transition of the rail vehicle (S) from a station area (B) to a free track (G), the control of the manual remote driving control is switched to the automatic driving control. Control method according to claim 1, wherein in automatic driving control continuous monitoring of a lying in front of the rail vehicle (S) driving route is made and is switched upon detection of an obstacle (H) to the manual remote driving control. Control method according to claim 2, wherein upon detection of an obstacle (H) of the automatic driving control for the rail vehicle, a braking operation is triggered. Control method according to one of Claims 2 or 3, in which the continuous monitoring of the route ahead of the rail vehicle (S) is carried out with the aid of a radar device (R). Control method according to one of claims 1 to 4, in which the manual driving control of the rail vehicle (S) from the rail vehicle (S) is carried out remotely on a virtual driver's cab (F) and on the basis of current data representing a current driving situation of the rail vehicle (S ) and transmitted via a communication link (V) to the virtual driver's cab (F). A control method according to claim 5, wherein the data includes image data from an environment of the rail vehicle (S) obtained from outward cameras (K) with respect to the rail vehicle (S). The control method according to claim 6, further comprising obtaining image data from a camera (K) equipped with a zoom function. Control method according to one of Claims 5 to 7, in which two-dimensional or three-dimensional representations ("virtual reality") are used to reproduce the current driving situation of the rail vehicle (S). A control method according to any one of claims 1 to 8, wherein the manual remote driving control is manually switched to the automatic driving control. Control arrangement for a rail vehicle (S), with - One on the rail vehicle (S) arranged, automatic driving control device (AS) for a free track (G) and - A remote from the rail vehicle (S) arranged manual driving control device (AS) for a station area (B), which includes a virtual cab (F), with the on the basis of current data representing a current driving situation of the rail vehicle (S) and be transmitted via a communication link (V) of the rail vehicle (S) to the virtual cab (F), a manual remote control of the rail vehicle (S) is feasible. Control arrangement according to claim 10, wherein the automatic drive control device (AS) for continuous monitoring of lying in front of the rail vehicle (S) driving route has a monitoring device and is designed for automatic switching from the automatic control device to the manual control device upon detection of an obstacle (H). Control arrangement according to Claim 11, in which, when an obstacle (H) is detected, the automatic control device (AS) triggers a braking operation for the rail vehicle (S). Control arrangement according to one of Claims 11 or 12, in which a radar device (R), which is in a signal connection with the automatic control device (AS), is provided for the continuous monitoring of the route ahead of the rail vehicle (S). Control arrangement according to one of claims 10 to 13, in which, with respect to the rail vehicle (S), outwardly directed cameras (K) are provided for detecting image data from an environment of the rail vehicle (S). Control arrangement according to claim 14, wherein additionally a camera (K) is provided, which is equipped with a zoom function. A control arrangement according to any one of claims 10 to 15, wherein the manual control device (AS) comprises manual switching means for switching from the manual control device to the automatic control device. Control arrangement according to one of claims 10 to 16, wherein a passenger cabin of the rail vehicle has at least one emergency switch whose operation causes a changeover from automatic to manual control.

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