EP3176049A1 - Device and method for the control and/or monitoring of decentralised intelligent functional units in a rail traffic network - Google Patents

Abstract

The present invention has for its object to provide a device and method for controlling and / or monitoring arranged in a rail network decentralized functional units that are compared to the existing facilities easier and cheaper to operate and, if necessary. Also have a lower footprint. This object is achieved according to the invention with a device and a method for controlling and / or monitoring decentralized functional units arranged in a rail transport network, comprising: a) a higher-level control system (30) which exchanges information with the decentralized functional units (DFE, EC, C1 to C4) by means of data telegrams (DT), b) a data transport network (TN) with a number of network access points (2 to 16), wherein the higher-level control system (30) via at least one network access point (2, 4) is coupled to the data transport network (TN); c) communication units (18 to 28), which are connected to a network access point (6 to 16) and provide access to the data transport network (TN) to the decentralized functional units (DFE, EC, C1 to C4), and d) the decentralized functional units (DFE, EC, C1 to C4) automatically execute and / or manage control, monitoring and locking functions and, according to a track plan principle, with the respectively adjacent decentralized functional unit (DFE, EC, C1 to C4) according to the track plan principle are logically connected and directly communicate with these data to perform the control and / or monitoring and / or locking functions. In this way, the interlocking functionalities can be partially or even completely outsourced from a central indoor plant in the decentralized functional units, which has the consequence that the indoor facilities either drastically reduced or even completely dissolved.

Description

The present invention relates to a device and method for controlling and / or monitoring decentralized functional units located in a rail transport network.

Such decentralized functional units are used in rail transport networks, where they are used to control vehicle influencing and / or vehicle monitoring units and to monitor functionality and to record process data and back to a central control and / or monitoring center, such as a To report to the control center. As Zugbeeinflussende units that give instructions to the driver or even make direct intervention in the vehicle control or directly set a safe track, for example, signals, points, balises, line conductors, track magnets and the like, as well as sensors for detecting process variables of the moving train, such as power consumption, speed and the like. As train and track section monitoring units can also balise and line conductors, but also axle and track circuits and other train detection systems are called.

In railway traffic, it is usually the case that these decentralized functional units are controlled by an interlocking or a remote interlocking computer. For the data transfer between the interlocking and the functional units in the track area today standardized copper cables are usually provided, for their classical travel distances because of the physical transmission parameters, the cable coverings (RLC), at 10 km in practice is the upper limit. With certain types However, for functional units, this upper limit can only be at a maximum of 6.5 km.

Today, however, data networks are already being used by railways, which are used e.g. To exchange data under adjacent signal boxes or interlockings and control technology. They are also used to control and monitor train-influencing and / or train-monitoring functional units, thereby enabling bridging of almost any distance. These networks are of the data transport network (DTN) type, e.g. an optical transport network, and are used for the transmission of data for the operational level of operation and the like.

• der Festlegung der Position der Kopplungspunkte für den Anschluss von Stellwerk- und Leittechnikanlagen oder Teilen davon und somit dessen Aufstellungsorte,
• der angewandten Übertragungs-Verfahren und der Distanzen der Kommunikation unter verschiedenen Anlagenteilen.

Diese Datennetzwerke ermöglichen so mitunter eine wesentliche Verbesserung beim Preis/Leistungsverhältnis und dennoch ein hoch zuverlässiger und entsprechend sicherer Datenaustausch der Eisenbahnsicherungseinrichtungen entlang von Gleisanlagen (der dezentralen Funktionseinheiten.Such data networks allow a much higher number of degrees of freedom

• the determination of the position of the coupling points for the connection of interlocking and control systems or parts thereof and thus its sites,
• the applied transmission methods and the distances of the communication under different plant parts.

These data networks thus sometimes enable a significant improvement in the price / performance ratio and yet a highly reliable and correspondingly secure data exchange of the railway safety devices along track systems (the decentralized functional units.

The construction of technical facilities in the rail infrastructure is designed for robustness and reliability due to the more than 100 years of railway history. So today, all interlocking functions in a centralized indoor system, usually in a separate signal box building executed. The actual signal boxes are based today in the Usually on the track plan or shutter-board principle. Very often, the adjustment of the routes according to the track plan principle and the monitoring and verification of the set routes to the track plan principle is made to achieve the required safety or vice versa.

Today relay interlockings as well as electronic interlockings operate either according to the track plan principle or according to the closing plan principle (also called shutter-board principle). Mechanical interlockings work according to the closure plan principle. An operator brings a signal lever, and thus a signal, only in the driving position when the conditions according to the closure plan are met. As conditions for the signal travel position, the correct position of the points in the guideway is listed in the closing plan, the required position of the edge protection points, etc. In the relay interlocking these conditions are no longer realized by pure mechanical closures, but by interrupted by relay contacts current paths. With the relay interlockings, the track plan principle was born. In relay interlockings according to the track plan principle, the corresponding relay circuit is installed in the interlocking for each decentralized functional unit in the track system. The track system object imaging relay circuits are connected in accordance with the course of the track or the itineraries shown on the track cable in the so-called track plan. If, for example, the turnout 1 follows the turnout 2, the relays of the turnout 1 are connected via the toe cable to the relay of the turnout 2. In order for the signal of a driveway to drive, no decentralized functional unit lying in the driveway or in the lane may interrupt the current path required for the driveway via its relay contacts. Only when all lying in the road elements of the driving position of the signal agree, the signal can change to the driving position.

The advantage of the track plan principle is that regardless of the adjacent object of the switch 1 (signal, switch, block), the relay of the switch 1 are always connected to the neighboring element exactly the same way over the standard track cable. The size of the interlocking is theoretically unlimited. Stellwerke according to the plan of closure plan can be built only up to a certain size, eventually the (in mechanical and electromechanical interlockings in the form of closure registers or locking rods realized) closure plan is just too big and no longer manageable.

Electronic interlockings according to the closure plan principle often work with matrices. Electronic signal boxes according to the track plan principle still know traces, but these are no longer rungs, but virtual data tracks between adjacent elements. The information is transmitted in the form of telegrams. Only in the case that a track is distributed over several computers of the interlocking system, these telegrams can also be tracked at the interfaces of the computer with each other.

• Stellwerkinnenanlage (in der Regel in einem Rechnerraum untergebracht)
  • Verwaltung der Verschlussfunktionen
  • Schutz gegen Gegenfahrten
  • Schutz vor unzeitigem Weichenumlauf
  • Bereitstellen der Schnittstelle zu einem Fahrdienstleiter (dispositives Leitsystem)
• Aussenanlage mit den dezentralen Funktionseinheiten
  • Ansteuern der dezentralen Funktionseinheiten, wie Weiche, Signallampen usw.
  • Überwachen der dezentralen Funktionseinheiten, wie z.B. auf die Weichenendlage, das Fliessen des Lampenstroms usw.

The control data for the decentralized functional units in the outdoor plant are still transmitted today either in the form of energy signals or in the form of data telegrams. Basically, however, the following function distribution persists:

• Interlocking indoor unit (usually housed in a computer room)
  • Administration of the lock functions
  • Protection against counter drives
  • Protection against untimely switch circulation
  • Providing the interface to a dispatcher (dispatching control system)
• Outdoor facility with the decentralized functional units
  • Control of the decentralized functional units, such as switches, signal lamps, etc.
  • Monitoring the decentralized functional units, such as on the Weichenendlage, the flow of the lamp current, etc.

Basically, therefore, the actual logic of the train driving is still centrally located in the interlocking indoor system. There, for example, control cabinets are provided with signal and switch assemblies that control the signals and the switches in the outdoor system and monitor the correct current flow in the lamp circuit and the correct power consumption during the Weichenumlauf and the correct reaching the turnout end position. Therefore, such interlockings are relatively large and must be maintained accordingly and adjusted in accordance with climatic conditions. Thus, for example, especially for the operating conditions, no other parameters apply than those also apply to computer rooms in data centers.

The present invention is therefore based on the object to provide a device and method for controlling and / or monitoring arranged in a rail network decentralized functional units, which is compared to the existing facilities easier and cheaper to operate and, if necessary. Also has a lower footprint.

1. a) ein übergeordnetes Steuerungssystem, wie z.B. ein dispositives Leitsystem, das mit den dezentralen Funktionseinheiten mittels Datentelegrammen Informationen austauscht,
2. b) ein Datentransportnetzwerk mit einer Anzahl von Netzzugangspunkten, wobei das übergeordnete Steuerungssystem über mindestens einen Netzzugangspunkt an dem Datentransportnetzwerk angekoppelt ist;
3. c) Kommunikationseinheiten, die an einem Netzzugangspunkt angeschlossen sind und den dezentralen Funktionseinheiten den Zugang zu dem Datentransportnetzwerk bereitstellen, und
4. d) die dezentralen Funktionseinheiten selbsttätig Steuerungs-, Überwachungs- und Verschlussfunktionen ausführen und/oder verwalten sowie gemäss einem Spurplanprinzip mit dem jeweils gemäss dem Spurplanprinzip nächst benachbarten dezentralen Funktionseinheit logisch verbunden sind und mit diesen Daten zur Ausführung der Steuerungs- und/oder Überwachungs- und/oder Verschlussfunktionen direkt austauschen.

According to the invention, this object is achieved with a device for controlling and / or monitoring decentralized functional units arranged in a rail transport network, comprising:

1. a) a higher-level control system, such as a dispositive control system, which exchanges information with the decentralized functional units by means of data telegrams,
2. b) a data transport network having a number of network access points, wherein the higher-level control system is coupled to the data transport network via at least one network access point;
3. c) communication units which are connected to a network access point and provide access to the data transport network to the decentralized functional units, and
4. d) the decentralized functional units automatically perform control, monitoring and locking functions and / or manage and logically connected according to a track plan principle with the next according to the Spurplanprinzip decentralized functional unit and with this data to perform the control and / or monitoring and / or directly exchange locking functions.

1. a) Bereitstellen eines übergeordnete Steuerungssystems, z.B. ein dispositives Leitsystem, das mit den dezentralen Funktionseinheiten mittels Datentelegrammen Informationen austauscht,
2. b) Bereitstellen eines Datentransportnetzwerks mit einer Anzahl von Netzzugangspunkten, wobei das übergeordnete Steuerungssystem über mindestens einen Netzzugangspunkt an dem Datentransportnetzwerk angekoppelt ist;
3. c) Bereitstellen von Kommunikationseinheiten, die an einem Netzzugangspunkt angeschlossen sind und den dezentralen Funktionseinheiten den Zugang zu dem Datentransportnetzwerk ermöglichen, und
4. d) selbstätiges Ausführen von Steuerungs-, Überwachungs- und Verschlussfunktionen und ggfs. von Verwaltungsfunktionen durch die dezentralen Funktionseinheiten, wobei die dezentralen Funktionseinheiten gemäss einem Spurplanprinzip mit dem jeweils gemäss dem Spurplanprinzip nächst benachbarten dezentralen Funktionseinheit logisch verbunden sind und mit diesen Daten zur Ausführung der Steuerungs- und/oder Überwachungs- und/oder Verschlussfunktionen direkt austauschen.

With regard to the method, this object is achieved according to the invention by a method for controlling and / or monitoring decentralized functional units arranged in a rail transport network, comprising the steps:

1. a) providing a higher-level control system, for example a disposable control system, which exchanges information with the decentralized functional units by means of data telegrams,
2. b) providing a data transport network having a number of network access points, wherein the higher-level control system is coupled to the data transport network via at least one network access point;
3. c) providing communication units that are connected to a network access point and the decentralized functional units allow access to the data transport network, and
4. d) selbstätiges running control, monitoring and locking functions and, if necessary. Of administrative functions by the decentralized functional units, the decentralized functional units are logically connected according to a track plan principle with the next according to the track plan principle adjacent decentralized functional unit and with these data to execute the control - and / or monitor and / or lock functions directly exchange.

In this way, the interlocking functionalities can be partially or even completely outsourced from a central indoor plant in the decentralized functional units, which has the consequence that the indoor facilities either drastically reduced or even completely dissolved.

In appropriate manner for the environment of rail transport, the decentralized functional units can control and / or monitor traffic-monitoring and traffic-controlling units, in particular signals, switches, axle counters, track circuits, point and line-shaped train control elements. Accordingly, the higher-level control system can then comprise an interlocking and / or a control system. It should be noted that a possibly existing interlocking is constructed slimmer compared to a signal box of conventional design, because in particular the previously seen by a signal box extremely important and safety-critical closure functions have been outsourced to the decentralized functional units. In a complete implementation of the present invention, however, it even leads to a disappearance of the computer space of the interlocking.

Further advantageous embodiments of the present invention can be taken from the remaining subclaims.

Figur 1

in schematischer Ansicht den Aufbau einer Einrichtung zur Steuerung und/oder Überwachung von entlang eines Eisenbahnnetzwerkes angeordneten dezentralen Funktionseinheiten; und

Figur 2

in schematischer Ansicht eine Topologie eines dezentralen Stellwerks.

Advantageous embodiments of the present invention will be explained in more detail with reference to the drawing. Showing:

FIG. 1

a schematic view of the structure of a device for controlling and / or monitoring distributed along a railway network decentralized functional units; and

FIG. 2

a schematic view of a topology of a decentralized interlocking.

FIG. 1 shows a schematic view of the structure of a device E for controlling and / or monitoring along a railway network (not shown here) arranged decentralized functional units DFE1A to DFEnA, DFE1B to DFEnB, etc. (hereinafter also called element controller EC). Should not be meant a particular functional unit, the decentralized functional units are hereinafter referred to as DFE or EC. Such decentralized functional units DFE are used to control and monitor train-influencing and / or train monitoring units. As zugbeeinflussende units, for example, signals, switches, balises, line conductors, track magnets and the like may be mentioned. Train monitoring units can also include balises and line conductors, as well as axle counters and track circuits. By way of example, a signal S is controlled and monitored by the decentralized functional unit DFE1C. The decentralized functional unit DFE1C controls the display of the signal terms and executes respectively assists in monitoring functions, such as monitoring the lamp current in the signal circuit.

Each distributed functional unit DFE or the unit it controls / monitors has a unique address throughout the network, such as an IP address or a MAC address.

The device E further comprises a data transport network TN with a number of network access points 2 to 16. At a portion of these network access points 6 to 16 communication units 18 to 28 are connected. The data transport network TN is designed here as a highly available network. Such highly available structures can arise on the one hand by a redundant design of the network itself and / or on the other hand by a clever re-organization of the network in the event of failure of a connector.

In addition, the device E comprises a higher-level control system 30 which, in addition to other components not further listed here, comprises a control center LT and a service / diagnosis unit SD which are connected to the data transport network TN via the network access points 2 and 4 by means of Ethernet connections.

Like in the FIG. 1 As shown, the decentralized functional units DFE must be coupled to the transport network TN via one of the communication groups 18 to 28 and the corresponding network node 6 to 16 and can thus receive or exchange data telegrams via this. The decentralized functional units DFE are combined to subgroups a, b, c, d and e, each with its own subnetwork NA, NB, NC, ND and NE. Subgroup a becomes, for example, the decentralized functional units DFE1A, DFE2A, DFE3A to DFEnA educated. The subgroups a to e are always connected at their two ends to one of the communication groups 18 to 28 and a network access point 6 to 16. Each decentralized functional unit DFE is also a switching computer SU or SCU, which may alternatively be integrated directly into the decentralized functional unit DFE, upstream, which provides the connection to the subnetwork for the decentralized functional units DFE, so that each decentralized functional unit DFE in case of failure of a communication group can be addressed by a second redundant communication group 18 to 28.

Each subnetwork (NA to NE) is thus made up of a number of point-to-point connections of logically adjacent distributed functional units (DFE). In this case, a point-to-point connection is formed as an autonomous transmission path within the subnetwork, for example as an ISDN transmission path or as an xDSL transmission path or fiber optic transmission path. Thus, a single subnetwork can be constructed, so to speak, of individual transmission cells, which in turn always only have to master the transmission from point to point. In other words, for example, from simple, rather short-range transmission techniques, a much longer and more complex subnetwork can be put together. For this reason, it is convenient to terminate the point-to-point connection at each end with a switching module (SU), which even gives the chance to change the cell-to-cell point-to-point transmission technique and so on to select the most suitable transmission technology. A suitable switching module (SU) may for this purpose be designed such that it provides a number of point-to-point transmission techniques and self-organizing depending on the circuitry provides certain point-to-point transmission technique through the circuitry.

• Realtime Telegramme: Nutzdatentelegramme vom Stellwerk zu den DFE's als spezielle TCP/IP-Telegramme, spezieller Ethernet-Frametyp;
• Nicht-Realtime Telegramme: normale TCP/IP-Telegramme, keine Nutzdatentelegramme.

In order to meet the performance requirements and to be able to work with simple transmission means, such as ISDN, xDSL, SHDSL, the telegrams within the subnetworks a to e can be distinguished in real-time and non-real-time telegrams:

• Real-time telegrams: user data telegrams from the signal box to the DFEs as special TCP / IP telegrams, special Ethernet frame type;
• Non-realtime telegrams: normal TCP / IP telegrams, no user data telegrams.

Unlike in the prior art, the decentralized functional unit DFE here are logically coupled according to the track plan principle. The track plan principle - as discussed further in the introductory part - has the effect that each decentralized functional unit is logically connected to its next neighbor required for the construction of a road. Since the decentralized functional units DFE now also perform shutter functions, it is sufficient if the closure of the traffic-monitoring and / or traffic-controlling units controlled by the respective decentralized functional unit is forwarded according to the path of the track plan during the construction of a driveway. In other words, this means that, for example, a turnout 2 can only be closed off by the lock when, for example, the turnout 1 previously arranged turnout 1 has been locked in the same way. Locked in the interlocking means that the position of the switch is frozen and it is thus impossible that the turnout sealed switch can be made available to another route. Only after a successful driving on the road or by intentional intervention of the dispatcher from the control system LT out the Setting a route canceled and the closure of the traffic monitoring and / or traffic control units according to the logical arrangement for this road in the track plan starting at the beginning of the traveled / affected road can be canceled.

By way of example for the logical combination of decentralized functional units DFE according to the track plan, a dashed line L is shown, which connects the decentralized functional units DFE1D and DFE3C. According to the arrow direction of the dashed line L, therefore, the closure of decentralized functional unit DFE3C must first be reported to the decentralized functional unit DFE1D, before the latter also closes the traffic-monitoring and traffic-controlling unit controlled by it.

FIG. 2 now shows a schematic example of an exemplary topology for the device E with a decentralized virtual interlocking. The term "virtual" is used deliberately here because the actual interlocking system is no longer existent. The backup functionality, which is still perceived in this device E, is now decentralized to the decentralized functional units, here simplified drawn as a controller C1 to C4, distributed and logically interconnected according to track-plan principle.

During configuration, each controller C1 to C4 is now communicated to its controllers C1 to C4, which are adjacent in the track plan, for example in the form of an IP address or a Mac address. Some controllers C1 to C4 still have to take on additional tasks whose distribution can be determined by the configuration. Thus, the two controllers C2 and C4 take over the communication to a neighboring STW interlocking station (virtual or central with indoor installation available). But this communication could also be routed via the data network NT to the neighboring interlocking.

The actual track topology comprises three track sections G1 to G3 and a turnout W1 with a turnout drive WA1 and three light signals S1, S2 and S4. The controllers C1 to C4 also manage the closures and the track vacancy message GF for their respective assigned track sections G1 to G3. The higher-level control system 30 is shown here in the form of a cloud, in which the functionality of the disposable control system LT and the service / diagnosis unit SD are executed.

An example procedure for the setting of a route is explained below; the route to be set includes the track sections G1 and G2.

The route setting begins with a request of the route by the dispositive control system LT. It should therefore be driven via the signal S1 and the switch W1 from the track section G1 in the track section G2. The controller C1 now receives this request directly from the control system LT. The controller C1 forwards this command to the switch controller C3. The point controller C3 checks with the track release message GF, such as an axle counter controller, track circuit controller, whether the switch W1 is free. In the presence of this track release message, the switch controller C3 controls the switch W1 to the left by activating the switch drive WA1 and sets after acknowledgment of the correct turnout end position (eg by a switch blade control linkage) a closure for the switch W1. Subsequently, the points controller C3 forwards the originally received command for route setting to the controller C2. The controller C2 now checks whether, for the track section G2 monitored by it, the message that the track G2 is free (Track vacancy GF = FREE). In addition, the controller C2 communicates this route request to the neighboring STW interlocking, because of course from the track section G2 will then be retracted in a track controlled by the neighboring station track section. The controller C2 now forwards the information that the tests for the track section G2 which it controls have been successfully completed to the controller C3. The controller C3, in turn, forwards this information to the controller C1 upstream of it in the track plan. At this time, both the switch 1 and the signal S2 are now locked in the appropriate setting (closed). The controller C1 now turns on the green signal lamp of the signal S1 and closes this setting. Thus, the controller C1 can now report to the control system that the requested road is now set and locked in the closed position. A train / rail vehicle can safely leave this road now, which is also displayed in the control system LT on the magnifying glass images of the Dispatcher accordingly.

The structure of the road is therefore also in this device E according to the regular rules (eg according to the driving regulations of the FOT / EBA) and the prescribed there rules of the track plan principle. A particular advantage of this solution consists in the fact that in the event of failures then usually only the affected decentralized functional unit fails and not, as today unfortunately usually in a fault, the entire interlocking. In addition, the process information about the closure status of individual decentralized functional units is available directly in the outdoor plant, so that, for example, there is also the possibility of connecting a mortuary warning system. By a consistent structure of the network topology according to the above pattern, the control system LT can be executed as a real cloud solution. For diagnoses can be at any decentralized functional element Network connections are provided. Remote diagnostics are also made easier and access protection can be improved. For example, safety-relevant diagnostic functions can only be provided locally.

Claims (6)

Device (E) for controlling and / or monitoring decentralized functional units (DFE, EC, C1 to C4) arranged in a rail network, comprising: a) a higher-level control system (30) which exchanges information with the decentralized functional units (DFE, EC, C1 to C4) by means of data telegrams (DT), b) a data transport network (TN) with a number of network access points (2 to 16), wherein the higher-level control system (30) via at least one network access point (2, 4) is coupled to the data transport network (TN); c) communication units (18 to 28), which are connected to a network access point (6 to 16) and the decentralized functional units (DFE, EC, C1 to C4) provide access to the data transport network (TN), and d) the decentralized functional units (DFE, EC, C1 to C4) automatically execute and / or manage control, monitoring and locking functions as well as logically according to a track plan principle with the next adjacent decentralized functional unit (DFE, EC, C1 to C4) according to the track plan principle are connected and directly communicate with these data to perform the control and / or monitoring and / or locking functions. Device (E) according to claim 1,
characterized in that
the decentralized functional units (DFE, EC, C1 to C4) control and / or monitor traffic-monitoring and traffic-controlling units, in particular signals (S), switches (W1), axle counters, track circuits, point and line-shaped train control elements. Device (E) according to claim 1 or 2,
characterized in that
the higher-level control system comprises an interlocking and / or a control system (LT). Method for controlling and / or monitoring decentralized functional units (DFE, EC, C1 to C4) arranged in a rail network, comprising the steps: a) providing a higher-level control system (30) which exchanges information with the decentralized functional units (DFE, EC, C1 to C4) by means of data telegrams (DT), b) providing a data transport network (TN) with a number of network access points (2 to 16), wherein the higher-level control system (30) via at least one network access point (2, 4) is coupled to the data transport network (TN); c) providing communication units (18 to 28), which are connected to a network access point (6 to 16) and the decentralized functional units (DFE, EC, C1 to C4) allow access to the data transport network (TN), and d) selbstätiges running control, monitoring and locking functions and, if necessary, the management of these functions by the decentralized functional units (DFE, EC, C1 to C4), wherein the decentralized functional units (DFE, EC, C1 to C4) according to a track plan principle with are each logically connected according to the track plan principle next adjacent decentralized functional unit (DFE, EC, C1 to C4) and directly communicate with these data to perform the control and / or monitoring and / or locking functions. Method according to claim 4,
characterized in that
the decentralized functional units (DFE, EC, C1 to C4) traffic-monitoring and traffic-controlling units, in particular signals (S, S1, S2, S4), points (W1), Axle counter, track circuits, point and line train control elements, control and / or monitor. Method according to claim 4 or 5,
characterized in that
the higher-level control system comprises an interlocking and / or a control system (LT).

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