DE102005042218A1 - Railway collision warning system, carried in the rail vehicle, has a transceiver to transmit and receive data packets of other trains for the control unit to determine collision risks together with its own data unit - Google Patents

Abstract

The warning system (1) for a railway collision, carried in the rail vehicle, has a control unit (2) linked to a detection unit (3), which determines the actual position and speed and direction of travel in combination with a unit (5) to detect the rail track road. A transceiver (4), linked to the control, transmits and receives data packets with the train identity together with data relating to other trains moving on the rail network. The control unit is structured to process the data to determine the possibility of a collision from its data and the data relating to other trains. The control unit acts on the train controls if a collision is imminent.

Description

The The invention relates to a railway collision warning device for Installation in railway vehicles.

The Controlling and securing the train traffic takes place today on the one hand with guidance and control equipment, which are essentially centrally managed by signal boxes. there is a setting and assignment of so-called driveways to a exactly defined train made with the help of the signal boxes and it are all track field elements, such as points, etc., put in the right position and locked. Then be put the signals on "drive".

In Train vehicles are often fitted with train protection systems, for example, when driving past signals that are not on "ride", automatically trigger a braking.

From the EP 1 232 926 A1 a train protection system is known in which balise groups are arranged at route points of the track. The balises are active or passive transponders, which are excited when crossing a railway train and then send messages to the railway vehicle. While fixed data balises transmit a fixed data set, transparent or switchable balises are coupled to a signal source and transmit different data sets depending on the applied signal. In the described method, the speed of the railway vehicle is determined and compared with a maximum permissible speed from the detected reception times of two telegrams transmitted at a known distance one behind the other. If the maximum permissible speed is exceeded, a warning signal or emergency braking is triggered.

Furthermore, for example, from the DE 199 50 395 A1 a locating system for rail vehicles on a rail network, in which the spatial position of the rail vehicle is determined by the rail vehicle with the aid of sensors and transmitted to a central office.

The Safety of these known centralized methods depends both from the correct operation of the interlocking as well as the zugseitigen Backup system.

One based on the ETCS (European Train Control System) standard Train control system is described in US 2004/0267415 A1, are also used in the trackside balise information. From the railway vehicles are the location position, the speed and, if applicable, further information about a specific railway mobile network (Global System for Mobile Communications Railways - GSM-R) transferred to a signal box. The supervision and control of the railway vehicles is done centrally.

In the DE 198 40 715 C2 is a rail vehicle control device for the so-called radio-driving operation FFB described in the control computer in the railway vehicles each have a Streckenatlas with information of the route network. Individual track sections are then centrally assigned by a train safety device via radio at most one vehicle in order to avoid collisions in this way.

In the DE 198 47 292 A1 is described a communication system for such a radio driving operation, in which the radio connection for data transmission between the subsystems is centrally communicated via a gateway computer.

To safeguard air traffic, for example, the "Traffic Alert and Collision Avoidance System" (TCAS) is known, in which transponders of other aircraft in the surrounding airspace are queried.The position and course information obtained by the transponders are evaluated with regard to possible collision courses The TCAS system issues a Traffic Advisory TA (Resolution Advisory TA) or a Resolution Advisory RA (RA), and if two aircraft collide, the TCAS systems in the two aircraft will coordinate with each other The TCAS system is for example in the EP 0 905 528 A2 described.

In shipping, the so-called AIS traffic alert system (Automatic Identification System) is known in the equipped with an AIS transponder ships in the broadcast method time-cyclical navigation information with information about position, course and status of the ship send out. The sent out Data can be received by all other ships and also on land and evaluated, for example, to warn of collisions. The AIS system is for example in the DE 100 28 927 A1 described.

Out Martin Strohbach, Hans Werner Gellersen, Gerd Kortuem and Christian Kray: Cooperative Artefacts: Assessing Real World Situations Embedded Technology, in: Ubi Comp 2004, Lncs 3205, pp. 250-267 is describes a system for securing the danger, with the help of of near-field radio frequency controllers and a rule-based one Knowledge base possible hazardous situations reported by incompatible dangerous goods become.

outgoing It is an object of the present invention to provide an improved Railway collision warning device for installation in railway vehicles to create that without complex infrastructure on the driving route can be operated and a sufficiently reliable collision monitoring allowed.

• – eine Steuerungseinheit,
• – eine mit der Steuerungseinheit verbundene Fahrtermittlungseinheit zur Bestimmung einer die aktuelle Fahrzeugposition, die Fahrzeuggeschwindigkeit und die Bewegungsrichtung enthaltenen Fahrtinformationen,
• – eine Funksende- und Empfangseinheit, die mit der Steuerungseinheit zum Aussenden von einer Fahrzeugkennung und aktueller Fahrtinformationen des Fahrzeugs enthaltenen Datenpaketen und Empfangen von Datenpaketen mit Fahrtinformationen anderer auf dem Eisenbahnnetz befindlicher Eisenbahnfahrzeuge und deren Fahrzeugkennungen verbunden ist,

wobei die Steuerungseinheit zur Kollisionsüberprüfung durch Abgleich der Fahrtinformationen des eigenen Fahrzeugs mit den von anderen Fahrzeugen oder anderen mit solchen Geräten ausgestatteten Hindernissen empfangenen Fahrtinformationen eingerichtet ist.The object is achieved with the railway collision warning device of the type mentioned, which has:

• A control unit,
• A travel detection unit connected to the control unit for determining a travel information including the current vehicle position, the vehicle speed and the movement direction,
• A radio transmitting and receiving unit, which is connected to the control unit for transmitting data packets contained by a vehicle identification and current travel information of the vehicle and receiving data packets with travel information of other railway vehicles located on the railway network and their vehicle identifications,

wherein the collision check control unit is arranged by matching the travel information of the own vehicle with the travel information received from other vehicles or other obstacles equipped with such devices.

in the Difference to the well-known central monitoring and control systems is proposed that the railway vehicles constantly in regular or irregular intervals driving information send by radio within a certain range of Any other vehicle can be received, located in the radio reception area located.

there become the positions and motion vectors of the railway vehicles evaluated to detect whether there is a risk of collision.

in the Difference to ship and air traffic, the problem arises that the motion vectors of rail vehicles perfectly regular each other may show. Then would already when coupling half-trains and trailing Zugteilen a conflict detected. Also on the "flying" overtaking and dodging High-speed lines such a situation is allowed. Even the motion vectors of moves encountered at a high Relative speed only a few meters past each other. In curves the distance to the part is further reduced.

by virtue of of the deterministic driving behavior of railway vehicles these permissible Situations but all recognizable and classifiable, so without central support a reliable one collision monitoring but possible is.

to increase accuracy in determining the vehicle position, it is advantageous if the trip detection unit with a track identification unit is connected to the track used by the railway vehicle to determine. This track track can then, for example, with a corresponding identification number transmitted as travel information with and evaluated. For example, to track track identification railways provided on the track are to be read out.

Especially It is advantageous if the control unit has access to has a digital railroad ticket and to the projection of the determined vehicle position on a track track using the railway line map is set up. Such digital route maps are often present in modern railway vehicles, especially in railway trains, the according to the European Train Control System (ETCS) in the European Rail Transport Management System (ERTMS).

Often lies in an electronic book timetable with a directory of slow driving (EBULA) the entire planned route of a train in non-signaling safe form. In addition, a reliable statement about the planned route is often available on the Zugside for the next 5 to 30 kilometers. Thus, a topological route vector describing the planned route can be extracted from the available information and transmitted as part of the trip information to other railway vehicles and evaluated such topological route vectors of other railway vehicles for collision monitoring. Thus, a collision warning message can already be issued if the topological route vector does not coincide with the current motion vector of the railway vehicle.

For the determination The direction of movement and / or the busy track track can also curves estimated be by the lateral acceleration of the railway vehicle with an acceleration measuring unit is determined.

to Determining the location of the railway vehicle, for example a known and often in railway vehicles anyway existing satellite positioning receiver for satellite-based position determination be used. To also find a location in shaded areas, especially tunnels, to allow can if necessary, further locating methods known per se are used such as balises, mobile phone tracking, etc.

If the control unit continues to send further vehicle-specific Information is set up as trip information, such as information about loading gauges and exceeding prescribed loading gauges as well as over Type and load of the railway vehicle, in particular of dangerous goods identification, An extended collision check can be carried out. For example, if the load is exceeded, for example otherwise permissible Oncoming traffic can be prevented. In addition, with the help of dangerous goods identification can Prevents trains with incompatible dangerous goods draw closer or the route for a dangerous goods transporter is kept completely free.

Next the collision check based the travel information exchanged between the railway vehicles it is advantageous if in addition Route information is evaluated for collision monitoring, emitted by the radio side mounted radio transmission units become. Such route information can be, for example, the state be the clearance of level crossings. The route information can also to announce dangerous situations on the track, which with the help of on Track or sensors installed in preceding trains such as floods, avalanches, obstacles on the track etc.

The Result of the collision check can through the railway collision warning device be issued visually or acoustically to the engine driver. Especially It is advantageous if the control unit for emitting a Warning signal over the radio transmission unit is set up if there is a risk of collision was detected. Thus, those in the vicinity of a threatening Collision hazard of railway vehicles and, where appropriate the closest Signal box warned, so that from there countermeasures are initiated can.

Farther it is advantageous if the control unit for engaging in the Vehicle control is set up when a collision hazard detected has been. Such an intervention can be, for example, emergency braking or a deceleration. In the sense of vehicle control is but also understood that with appropriate equipment of the vehicle control trackside infrastructure, such as switches or signals, can be made.

The The invention will now be described by way of example with reference to an embodiment with the accompanying drawings explained in more detail. It demonstrate:

1 Block diagram of a railway collision warning device;

2 a) - e) - sketches of two trains with possible collision scenarios.

The 1 shows a block diagram of a railway collision warning device 1 recognize for installation in railway vehicles. The collision check hereby becomes decentralized in the railway vehicle itself with the aid of a control unit 2 performed with a trip detection unit 3 connected to the determination of trip information. With the help of the trip detection unit 3 the current vehicle position, the vehicle speed and the direction of movement are determined. This can be done for example with the aid of a satellite positioning receiver for satellite-based position determination.

The control unit 2 is still with a radio transmitter and receiver unit 4 connected to transmit the current trip information along with a vehicle identifier by radio on a suitable radio channel. In this way, the travel information and vehicle IDs of other vehicles in the reception area of the radio transmitter and receiver unit 4 received and evaluated for collision check, if they have a corresponding railway collision warning device 1 feature. The control unit 2 For this purpose, it is set up for this purpose, for example by suitable programming, in such a way that the travel information of the own vehicle is compared with the travel information received from other vehicles in order to derive a statement about the danger of collision.

The trip detection unit 3 can with a track gauge identification unit 5 be connected to identify the track used by the railway vehicle and thereby allow a more accurate vehicle position and improved collision monitoring.

For example, the track gauge identification unit 5 additionally be a transponder reading unit for reading track mounted balises.

With this railway collision warning device it is possible to get information about position, Velocity vector and other important values from certain moving railway vehicles and, where appropriate, infrastructure units radiate. This information can then be obtained from other railway vehicles in the region are evaluated for critical information Conditions, Suggested solutions and disruptive interventions derive.

The radio transmission can take place with common communication systems, in particular those with concurrent access to the same frequency. Such methods are, for example, TDMA (Time Division Multiple Access), CDMA (Code Divison Multiple Access), OFDM (Orthogonal Frequency Division Multiplexing) or MC-CDMA (Multi-Carrier Code Division Multiple Access) method. Optionally, the synchronization of the access can also take place via positioning satellite systems, for example by deducing the time slots to be used from the geographical position. The time slots can also be calculated using the hash function from the train identifier (RCAS-ID). With the same transmission method, a conflict resolution instruction can also be transmitted to the other participating rail vehicles, if only one railroad collision warning device 1 has recognized a potential danger.

Tabelle einer beispielhaften Datenstruktur des RCAS-Telegramms An exemplary structure of the data structure is shown below:

Table of an exemplary data structure of the RCAS telegram

The 2 allows sketches of conceivable conflict situations to be recognized.

In the 2 a) is a situation in which two railway vehicles train 1 , Train 2 drive on different tracks in the opposite direction. Although the motion vectors are parallel to each other, they do not face each other as the railway vehicles train 1 , Train 2 drive on different tracks. Therefore, no collision is detected. The adjustment of the travel information takes place taking into account the four-dimensional space, ie the time and the three spatial axes x, y, z. Depending on the Distance, remaining time, speed, etc. can then be triggered in case of danger, a reaction that can range from an audible and / or visual warning to emergency braking.

The 2 b) indicates a situation where two railway vehicles are approaching each other on the same track. The motion vectors therefore point directly to each other.

The 2 c) indicates a situation where two railway vehicles drive one behind the other. In this so-called following run on the same track, the motion vectors point in the same direction, with the motion vector of the following move pointing to the previous move. From the vehicle speed of the previous and subsequent train then a risk of collision can be derived.

The 2 d) indicates a possible flanking situation where a first railway vehicle is on the track 2 and a second railway vehicle on the track 1 drive in the opposite direction. The track 1 is over a turnout with the track 2 connected, which may be placed so that the second railway vehicle train 2 head-on to the first railway vehicle train 1 on the track 2 is directed. Such a risk of collision can be recognized in particular with the aid of a railway line map and with a topological line vector for the description of the planned route of the railway vehicles.

The 2 e) indicates a situation in which a collision can not be ruled out safely and flank travel with appropriately set points 1 and 2 is possible, although both railway vehicles as in the 2 a) drive on different tracks. Again, if necessary, a warning message can be issued.

to Securing trips with load crossings it is advantageous if as driving information in addition transmit corresponding vehicle-specific information and evaluated. With that you can Railway vehicles approaching on the neighboring track also Trigger braking so as to reduce the consequences of a collision.

• A: Lademaßüberschreitung LÜ ohne Einschränkung auf dem Nachbargleis (Lademaßüberschreitung nach oben).
• B: Normale Fahrt oder Lademaßüberschreitungs-Fahrt vom LÜ-Typ A oder B auf dem Nachbargleis möglich. Begegnungsverbot mit LÜ-Typ C oder D.
• C: Normale Fahrt oder Lademaßüberschreitungsfahrt vom LÜ-Typ A auf dem Nachbargleis ist möglich. Begegnungsverbot mit LÜ-Typ B, C oder D.
• D: Keine Fahrt auf dem Nachbargleis ist möglich. Sperrung erforderlich.

According to the Group guideline 408 "Trains driving and shunting (driving service regulations)" of Deutsche Bahn AG, the following four types of LÜ-types can be distinguished:

• A: Load excess LÜ without restriction on the neighboring track (charge overflow upwards).
• B: Normal drive or load overshoot possible from LÜ type A or B on the neighboring track. Non-meeting with LÜ-type C or D.
• C: Normal drive or load excess crossing of LÜ type A on the neighboring track is possible. Meeting ban with LÜ type B, C or D.
• D: No ride on the neighboring track is possible. Blocking required.

It there are others, too the loading mass exceedance LÜ beyond Dangers that may arise from the loading of trains. These include the Example certain chemical substances that are not stored side by side and / or allowed to be transported because they react with each other. By sending dangerous goods notes with the railway collision warning device and evaluation of the same, can other trains with "incompatible" dangerous goods in the environment over the potential danger be informed so that they are able to take appropriate action to take.

• a) Bahnübergang gesichert und Freiraum frei ⇒ Fahrt
• b) Bahnübergang gesichert und Freiraum durch sich bewegendes Objekt belegt ⇒ Warnung
• c) Bahnübergang gesichert und Freiraum durch stehendes Objekt belegt ⇒ Gefahr
• d) Der Status des Bahnübergangs ist unsicher.

A significant proportion of collisions are collisions with motor vehicles on level crossings without restriction or with half barriers. The railway collision warning device can be extended to also transmit and evaluate route information about the state of the clearance of level crossings. For this purpose, detection of irregular occupancies of the danger area, for example by magnetic field, infrared, video, weight measurement, etc., is performed at the level crossings with suitable sensors. This status of the level crossing BÜ is transmitted, for example, as follows:

• a) Railroad crossing secured and clearance clear ⇒ drive
• b) Secured level crossing and clear space occupied by moving object ⇒ Warning
• c) Level crossing secured and clear space occupied by stationary object ⇒ Danger
• d) The status of the railroad crossing is uncertain.

Furthermore, "soft" collision hazards can be monitored and evaluated on the track such as snow or water in places known for such disturbances. For this purpose, suitable sensors are installed on the routes and equipped with a radio transmission system. As soon as a danger has been detected, it is broadcast as so-called route information and evaluated with the railway collision warning device in the railway vehicles.

By Inclusion of a communication connection to the signal box result further possibilities to resolve a recognized conflict. Thus, the travel service provider in the signal box also has the option through timely change the switch setting on the part of the infrastructure, for example by Redirecting a train on a "safe" track a collision or to prevent a collision, provided the route topology this allows. Such a semiautomatic or automatic reaction to one of transmitted to a railway collision warning device Danger situation only requires a corresponding radio receiving unit with signal evaluation and display unit.

Claims (12)

Railway collision warning device ( 1 ) for installation in railway vehicles, characterized by - a control unit ( 2 ), - one with the control unit ( 2 ) associated driving detection unit ( 3 ) for determining the current vehicle position, the vehicle speed and the direction of travel contained travel information, - a radio transmitter and receiver unit ( 4 ) connected to the control unit ( 2 ) for transmitting a vehicle identification and current travel information of the vehicle contained data packets and receiving data packets with travel information of other railway vehicles located on the railway network and their vehicle identifiers is connected, wherein the control unit ( 2 ) is set up for collision checking by matching the travel information of the own vehicle with the travel information received from other vehicles. Railway collision warning device ( 1 ) according to claim 1, characterized in that the travel detection unit ( 3 ) with a track-track identification unit ( 5 ) is connected to determine the track used by the railway vehicle. Railway collision warning device ( 1 ) according to claim 2, characterized in that the track track identification unit ( 5 ) is designed for reading out of track provided balises. Railway collision warning device ( 1 ) according to one of the preceding claims, characterized in that the control unit ( 2 ) has access to a digital railway line map and is set up to project the determined vehicle position onto a track track using the railway line map. Railway collision warning device ( 1 ) according to one of the preceding claims, characterized in that the control unit ( 2 ) is set up for transmission and evaluation of a topological route vector of the planned route as part of the trip information. Railway collision warning device ( 1 ) according to one of the preceding claims, characterized in that the travel detection unit ( 3 ) is connected to an acceleration measuring unit for determining the lateral acceleration of the railway vehicle and is set up to estimate curves for determining the direction of movement and / or the track track being traveled. Railway collision warning device ( 1 ) according to one of the preceding claims, characterized in that the travel detection unit ( 3 ) is connected to a satellite positioning receiver for satellite position detection. Railway collision warning device ( 1 ) according to one of the preceding claims, characterized in that the control unit ( 2 ) is set up for the transmission of further vehicle-specific information as journey information, in particular exceeding of prescribed load dimensions, vehicle condition and / or dangerous goods identifications, and evaluation of the vehicle-specific information of other vehicles for extended collision check. Railway collision warning device ( 1 ) according to one of the preceding claims, characterized in that the control unit ( 2 ) continue to be evaluated by the radio receiver unit ( 4 ) is set up for collision monitoring. Railway collision warning device ( 1 ) according to claim 9, characterized in that route information reproduce the state of the free space of level crossings and / or with sensors installed on the track sensors detected dangerous situations. Railway collision warning device ( 1 ) according to one of the preceding claims, characterized in that the control unit ( 2 ) for emitting a warning signal via the radio transmitter unit ( 4 ) is set up if a collision hazard has been detected. Railway collision warning device ( 1 ) according to one of the preceding claims, characterized in that the control unit ( 2 ) is set up to intervene in the vehicle control when a collision hazard has been detected.