EP3580114A1

EP3580114A1 - Method and apparatus for setting at least one route for a railway installation

Info

Publication number: EP3580114A1
Application number: EP18702058.1A
Authority: EP
Inventors: Andreas Schallenberg; Uwe Eckelmann-Wendt; Stefan Gerken
Original assignee: Siemens Mobility GmbH
Current assignee: Siemens Mobility GmbH
Priority date: 2017-02-07
Filing date: 2018-01-08
Publication date: 2019-12-18
Anticipated expiration: 2038-01-08
Also published as: PL3580114T3; DE102017201892A1; EP3580114B1; CN110505993A; CN110505993B; WO2018145835A1; ES2874522T3

Abstract

The invention relates to a method for setting at least one route for a railway installation that has at least one signal box device (S1, S2) and a multiplicity of track-side control elements (2) connected to the signal box device. The method involves the signal box device (S1, S2) ascertaining at least one control element (2) required for the route from the multiplicity of control elements and ascertaining at least one functional job to be performed by the ascertained control element to set the route and informing the control element about the ascertained job, and involves the control element ascertaining at least one control measure to be performed by the control element to perform the job.

Description

description

Method and device for adjusting at least one route of a railway installation

For the operation of railway technical systems, these interlocking devices and control elements along the routes. For a safe driving operation must

Control elements verifiable in predetermined states. Control elements are, for example, switches, light signals,

Train detection systems, and the like. For example, certain points monitored and closed end positions must he rich ^¬ before a vehicle is allowed to pass them. Light signals must show certain monitored signal images.

The planned for a train movement and then reserved available infrastructure is referred to as a route. The necessary and reserved for a route elements can be referred to as claimed. The routes must be set so that mutual exclusions are given with other routes. Furthermore, for example, an edge protection, anti-collision protection and collision protection must be ensured. In addition, the status of the control elements, which are defective or not yet in the correct position, for example, must be at a stress of the

Tracks are considered by a driveway. ^¬ closing Lich also peculiarities of the trains have to be considered partly because, for example, a freight train otherwise be ^¬ acts is as a passenger train.

The interlocking devices, which can also be referred to as interlocking logic, are responsible for locating, checking and setting up (also called commissioning) and also the subsequent dissolution of the routes. The individual control elements are connected to an interlocking device and are commanded by this. The interlocking devices work either on the lock principle or the track plan principle. In the closure principle, the possible driving Streets are known in advance and will be tested in the construction of the interlocking facility on mutual exclusion. In the track plan principle, the routes are calculated dynamically by the interlocking device, the so-called route search. In the track plan principle, logic rules on the control elements and track sections during the operating time of the interlocking device cause the exclusion.

Since railway technical systems can be very large and provided with many control elements, the system is usually divided into several control ranges. Stellbereiche are geographical regions of the railway technical system, which include a certain set of control elements, which are controlled by an interlocking device.

However, the setting of a route becomes more complex due to the different setting areas. For the course of a route through multiple parking areas a variety of rules is necessary, which can make the operation of the railway technical complex complicated.

In particular, when converting interlocking equipment or commissioning new interlocking equipment, the system must be completely switched off or complex rules for the maintenance of safety necessary.

It is therefore the object of the railway technical system to provide a method and a device for adjusting at least one route of a railway installation, by which the operation of the railway installation is simplified.

The object is achieved by a method for adjusting at least one route of a railway technical plant-ge, having at least one interlocking device and a multi ^¬ plurality of trackside associated with the interlocking device setting elements, wherein the required part of the interlocking device at least one for the driveway Royal actuator is determined from the plurality of control elements and determines at least one of the determined Stellele ^¬ ment for setting the route to be realized functional order and the actuator is informed about the determined order and at the Stellelement- side at least one for the realization of the order of Control element to be performed control measure is determined.

Furthermore, the object is achieved by a device for setting at least one route of a railway technical system, with at least one interlocking device and with a plurality of connected to the interlocking device track-side control elements, said at least one interlocking device for determining at least one required for a route actuating element and WE ^¬ a to be implemented for setting the route from the determined actuator functional order is formed nigstens and the adjusting elements are each designed for determining at least one adjustment measures to be taken for the realization of the order detected for them.

The solution according to the invention has the advantage that it is separated between the determination of the functional order for an actuating element and the determination of the necessary corrective action. So is a distribution on interlocking equipment and

Actuator possible. The interlocking device determines the required for the driveway control element and the functional order to be realized by this, but passes this to the actuator for further processing. The actual control action to be performed by the control element is subsequently determined by the control element itself. This allows the actuator to compare the order with other already ^¬ taken earlier orders of the actuating element and choose from several possible measures most appropriate. Thus, a total of more orders can be executed, as if the interlocking device would determine the control measures for the element itself. The interlocking equipment may not be aware of other tasks of the elements. The inventive solution can be realized more on ^¬ sluggish and routes are set. Furthermore, control ranges can be increased and several

Stellwerkseinrichtungen be operated, whereby the operation is greatly simplified. Also, reconstruction measures are easier to implement.

The inventive solution can be developed further by favorable Fully ^¬ staltungen that are loading inscribed below.

Thus, alternate element side at least one information output bezüg ^¬ Lich the realization of the contract to the interlocking means. This has the advantage that the adjusting factory device gets a response from the actuator when the order was realized by the actuator or when the order can not be accepted. Alternative, weakened jobs can also be reported back. In an advantageous embodiment, the feasibility of the job can be checked on the actuating element side. This has the advantage that, on the actuating element side, a conflict with other orders of the actuating element can be determined, which may not be known to the interlocking device. When testing the feasibility of further functional on to the actuating element for the setting of further DRIVEWAY ^¬ KISSING be considered example of other interlocking devices ^¬ sluggish. In addition, at least one alternative functional order for adjusting the route can be determined on the actuating element side if the test does not give any feasibility, and information about the alternative functional order is output on the actuating element side. Thus, more intelligence is shifted on the part of the adjusting element, takes over the tests and even proposes modified orders, if this is a Realisie ^¬ tion of the route is possible to take on Stellelementseitig on ^¬ sluggish from various interlocking devices. To avoid deadlocks or conflicts in the concurrent formation of partial routes can be processed by the interlocking several orders for different control elements in a predetermined order. For example, the control elements can always be assigned to rising ^¬ based on their identifier.

Also, several orders for the same che actuating element in a predetermined order can be abgear ^¬ beitet actuator side.

In a further advantageous embodiment, information can, in particular information on the at least one functional order and its realization, are transmitted between the at least one interlocking device and the adjusting elements, wherein the information comprises a Wenig ^¬ least one the sender of the information uniquely iden ^¬ Rende marking. This has the advantage that the sender is always clearly identified in the communication between different partners such as interlocking devices and control elements. For example, orders from various interlocking facilities can be easily managed and edited, such as in a specific order. For example, a UUID (Universally

Unique Identifier). The orders can also be transmitted coded between the interlocking device and the control element in order to reduce the size of the data and to avoid misunderstandings that would endanger the security.

In order to increase flexibility within the technical railway system, the orders of several ^¬ ren interlocking devices can be processed Vice element side. This results in the great advantage that, for example, when converting ^¬ th an interlocking system can be easily replaced by another interlocking system and can remain in function from the reconstruction of unaffected control elements. In an advantageous embodiment of the inventive device for adjusting at least a traveling road, the device may at least comprise two interlocking devices up, both of which are at least partially connected to the same actuating ^¬ elements, wherein the adjusting elements are adapted to Reali ^¬ Sieren of orders of the two interlocking means. This has the part already described above ^¬ part, that control elements can be commissioned by several interlocking devices and thereby a greater flexibility ^{¬ it is} possible within the railway technical system.

In the following the invention will be explained with reference to the attached drawing.

The sole FIGURE shows an exemplary embodiment of a device according to the invention for adjusting at least one route of a railway installation. The figure shows a schematic representation of an off ^{¬ section of} a railway technical system 1 with tracks A, B and C. The tracks A, B, C are connected to each other via the switches Wl, W2, W3. On the tracks A, B, C further light signals F, P and another light signal LS2 are arranged net. Furthermore, the railway technical system includes 1

Interlocking devices Sl and S2. The switches Wl, W2, W3 and the light signals P, F, LS2 are control elements 2, which are signal-technically connected to the interlocking devices Sl, S2. In the case of the exemplary embodiment shown in the figure, the railway technical installation 1 also comprises a control station 3, which, for example, orders a route from a starting point to a destination at the interlocking devices S1, S2. The figure shows a Stell ^¬ plant area 4, to which all actuators 2 belong and which is controlled by the interlocking devices Sl, S2. The interlocking devices Sl, S2 are shown here only schematically as boxes. You can also include, for example, a signal box and / or more interlocking logic. In the following, the route inventive formation will be described with reference to the illustrated in the figure exemplary exporting ^¬ approximately of the invention.

First, the control center 3 instructs, for example, the

Signaling device Sl with a driveway from a start to a destination (not shown). As usual, specifications, for example mandatory elements to be passed, such as platforms or the like, can be specified by the control station 3. Subsequently, the interlocking device Sl searches for a guideway taking into account all specifications of the control center 3. As soon as a guideway is found, the interlocking device S1 determines the control elements 2 along this guideway. Furthermore, the interlocking device S1 determines functional orders which the adjusting elements 2 have to realize for adjusting the route.

The determined orders are transmitted from the interlocking device Sl to the respective control elements 2. This over ^¬ mediation can be done for example via a wiring or alternatively wirelessly such as via WLAN.

The mandates are, for example, in the path befind ^¬ union turnout Wl, W2, W3 commissioned as actuators 2 with certain input and output legs. Light signals F, P, LS2 in the guideway can be instructed for example as adjusting elements 2 with the capabilities for necessary signal images. Switches Wl, W2, W3 and light signals F, P, LS2, which are off the track, are optionally commissioned as protective elements with a specific protective function. The adjusting elements are claimed when the Stellwerksein ^¬ direction Sl has transmitted the individual orders to the control elements 2. Subsequently, the control elements 2 check their new orders and their compatibility with old already accepted orders. If this compatibility exists 2 accept the data received from the interlocking device ^¬ Sl new order the actuators. If this compatibility is not given, the adjusting elements 2 can optionally weaken an old order in the responsible interlocking devices Sl, S2, if this would lead to a compatibility of all orders in the event of success. If the weakening succeeds, the new order can also be accepted. The exact execution of the attenuation will be explained later. Furthermore, instead of accepting the new order, the adjusting elements 2 can also offer this new order in a weakened form of the interlocking device S1.

Finally, the control elements 2 can reject an order, of course, if this is incompatible with the existing orders or if, for example, a defect state of the control element 2 is present.

Is a driveway of the interlocking device Sl can not be formed because control elements have rejected 2 orders, the interlocking device Sl, S2 can search for alternatives, for example by means of so-called backtracking or other known measures. Subsequently, it is attempted to form the ^¬ al ternative driveway. Only after the alternatives have been exhausted must the control center 3 be notified of the impossibility of the requested route.

When weakening an old order, the respective actuating element 2 inquires at the ordering interlocking device S1, S2 of the old order whether a certain weakening is accepted. This attenuation is transmitted as an alternative to ^¬ transfer from actuator 2 to the interlocking system Sl, S2. The interlocking device Sl, S2 of the old order checks and instructs optionally other control elements 2 with additional support orders. The Stellwerksein- direction Sl, S2 of the old order tells the actuator 2, which has proposed the attenuation, the result of the test. This result is that the mitigation is accepted or not. Even after a route is set, the control device must ^¬ factory Sl, S2 tions on change requests as slow-down or eighth reinforcement of the control elements. 2 Resulting new orders and order releases of further elements must be checked, optionally a variant selected and realized and the anfra ^¬ ing actuator 2, the result will be communicated. In the following, an exemplary route setting will be described with reference to the exemplary embodiment shown in the figure. In this case, the light signals F, P

Main signals and the light signal LS2 a dwarf signal. For routes along the tracks A, C, the switch W2 can not provide flank protection at the same time.

The interlocking device Sl would like to form a route along track A from light signal F in the direction of west W for a freight train (not shown). For this purpose, the light signal F with the signal images stop and drive, where it is initially in stop, instructed by the interlocking device Sl. The switch Wl is commissioned with a driveway from the top to the right thigh. For a flank protection against track B, the switch W2 would receive a corresponding order from the interlocking device S1, which calls for the unavailability of the left switch leg, which could be realized, for example, by the switch W2 in the legal position. The track sections of light signal F to the switch Wl and of the switch Wl west W would be claimed for the track, the track section between the switches Wl and W2 for the shelter. The audit of these contracts by the elements 2 shows that the control elements 2 take their orders Kings ^¬ nen.

In addition, a train route for a passenger train of light signal P along track C in the east direction is then commissioned in the interlocking device S2. The light signal P, the diverter W3, the track sections between light signal P and diverter W3 and diverter W3 east 0 would be commissioned as a guideway. The shunt W3 would require the track sections ver ^¬ bind. The track section from the switch W3 to the switch W2 would be needed as a shelter. Now there would be a problem with the turnout W2. The order of the interlocking device S2 is to provide protection for the driveway bereitzustel ^¬ len. Now the switch W2 has previously received the order from the interlocking device Sl and accepted. This old order from the interlocking device Sl is in conflict with the new order from the interlocking device S2, since the switch W2 must go to the left for the old order flank protection of the interlocking device Sl in the right position and for the new order from the interlocking device S2.

According to the method according to the invention, the diverter W2 can now request a weakening of the order in the case of the interlocking device S1. The turnout W2 offers here so-called iron protection. For a passenger train this loud, here, for example, adopted German operating regulations is absolutely necessary, therefore, the switch W2 can not make a weaker offer to the interlocking S2. However, so-called light protection would be sufficient for a freight train, ie protection by stop light signal. Therefore asks the switch W2 at the interlocking device Sl, whether it may control its point of the switch and whether the Stell ^¬ factory device Sl can instruct the light signal LS2 with light protection. The interlocking device Sl then asks the light signal LS2 for light protection. The light signal LS2 accepts this order because nothing speaks against it. Subsequently ^¬ ßend the interlocking system Sl reduces the protection order in the shunt W2. Thus, the switch W2 may now go to the left. Thus, the conditions for accepting the order from the interlocking device S2 are met and the switch W2 reports this also to the interlocking device S2 back. Consequently, the interlocking device S2 can now also realize its route. The route is also resolved by the inventive method again. If, for example, the passenger train has cleared the switch W3, then behind him the cleared shelter is successively dismantled by the interlocking device S2 again. The track section from the switch W3 to the east 0, the switch W3 itself, the track section between the switch W2 and the switch W3 and the switch W2 are again released from their orders. For the diverter W2, this means that it can now again offer iron protection for the order of the adjusting workstation S1. This can now report the switch W2 to the interlocking device Sl. The interlocking device Sl can then cause the Auftragände ^¬ tion at the switch W2. The interlocking device Sl can then also release the light signal LS2 again from his job. Through this sequence, the ^white W2 would run again in legal position.

In the inventive commissioning of the control elements 2 by the interlocking devices Sl, S2, the purpose is advantageously contained as further information in the orders. For example, this may be the information that flank protection must be given for a freight train.

Furthermore, the commissioning of the control elements 2 by all interlocking devices Sl, S2 of the railway technical system 1 can be done in a particular order. This has the advantage that conflicts in the route formation can be excluded ^¬ . For this purpose, all control elements 2 and interlocking devices Sl, S2 are provided with a unique identifier, such as a UUID. For example, to specify an order, the order may be made in ascending order of the numerical value of the UUID. As a result, the interlocking device S 1, S 2, which has first successfully commissioned, has no future collision with other route layouts to fear. This automatically results in a prioritization of the routes. In any case, the predetermined order of all interlocking devices Sl, S2 must be complied with. In an error case of an actuator 2, such as ^¬ example, a defect or a communication failure, the actuator 2 must automatically assume a safe state. For light signals this is for example the indication of a stop signal. For points this may be the whereabouts in a previously taken over monitored Endlagenenzustand. As an example of attenuation of light signals, the following:

A light signal is to be instructed to indicate for the execution of a train ride and stop. However, it has no way to display driving, for example, by the construction ^¬ form or due to a defective bulb, and therefore offers the display stop and a driving concept with reduced speed as a weakened order of the interlocking device.

An example of simultaneous orders to an actuator:

A driveway is to be realized by two partial driveways of two interlocking devices. The first adjusting workstation instructs as a control element a light signal for a train X as a target signal. The signal concept should be stop. The second interlocking device instructs the same light signal for the same train X as a start signal. The Sig ^¬ nalbegriff should also be stop. The light signal can accept both jobs and shows stop. If the route is formed, the light signal can merge the information of the two orders. Here is the chaining of partial routes to a total road only due to the Eigenintelligenz of the actuator possible without the Stell- Werkseinrichtungen must be involved.

An example for the conversion of a parking area: In this example, an adjustment area is extended by one track. For this it will be necessary to lock some existing switches and light signals. In preparation ^¬ the first new interlocking devices placed einge- into the system. This corresponds, for example, to starting new software. The interlocking devices then have a reduced set of available control elements, because the non-usable control elements are removed. As soon as a previously existing interlocking device with a full range of actuating elements is idling (ie, at the moment not realizing a route), it is switched off. If this is done with all previous interlocking devices, so the lahmzulegenden for the conversion control elements are no longer used. Now the extension work can be done. When they are finished, they will be new again

Stellwerkseinrichtungen started and turned off the previous when reaching idle. The new Stellwerksein ^¬ directions now also have the control elements of the new track in their connection plan. At no time during this conversion was the operation on the unaffected parts of the railway system affected. The update of interlocking devices can also be done successively in this way. The new interlocking system is started in parallel and only then is the previous interlocking device switched off.

An example of overlapping of interlocking areas:

The previous separation in interlocking areas can according to the invention be omitted in the previously known manner. It is possible to operate or partition large areas contiguously, with no need to prioritize the topology and geography. Thus, interlocking devices can also be created according to other criteria, eg interlocking devices that are only responsible for transits or interlocking facilities that are responsible for individual Rangierbereiche. The division into ranges can also over the time (eg after times of day or load situations). Actuators can only be virtual. In order to function according to the method described, no trackside physi ^¬ cal expression is necessary. A software component running in the system can represent a virtually existing control element.

Claims

claims

1. A method for adjusting at least one driveway of a railway technical installation (1), which has at least one adjusting works device (S1, S2) and a plurality of track-side adjusting elements (2) connected to the interlocking device,

in which on the part of the interlocking device (Sl, S2) at least one required for the route actuating element (2) from the plurality of control elements (2) is determined and determined at least one of the determined control element (2) for setting the route to be realized functional order and the control element (2) is informed about the determined order and

in the actuating element side, at least one control measure to be carried out by the actuating element to realize the job is determined.

2. The method according to claim 1,

d a d u r c h e c e n c i n e s that

On the actuating element side, at least information relating to the realization of the order is output to the interlocking device (S1, S2).

3. The method according to claim 1 or 2,

d a d u r c h e c e n c i n e s that

on the actuating element side, the feasibility of the order is checked.

4. The method according to claim 3,

d a d u r c h e c e n c i n e s that

when checking the feasibility further functional orders of the control element (2) are considered for the setting of other routes.

5. The method according to claim 3 or 4,

d a d u r c h e c e n c i n e s that

on the actuating element side, at least one alternative functional one Order for the setting of the route is determined if the test does not give feasibility, and on the part of the side information about the alternative functional order is issued.

6. Method according to one of the above-mentioned claims, in which a

Information, in particular information on the at least one functional order and its implementation, between the at least one interlocking device (Sl, S2) and the control elements (2) are transmitted, the information ^NEN each have at least one the sender of the information uniquely identifying label.

7. The method according to any one of the above claims, d a d u c h e c e n e c e s in that e

on the part of the interlocking device (S1, S2) several orders for different control elements (2) are processed in a predetermined order.

8. The method according to any one of the above claims, d a d e r c h e c e n e c e s in that e

adjusting element side, the orders of several Stellwerksein ^¬ directions (Sl, S2) are processed.

9. Device for adjusting at least one route of a railway installation (1),

with at least one interlocking device (S1, S2) and with a plurality of track-side actuating elements (2) connected to the interlocking device (S1, S2),

wherein the at least one interlocking means (Sl, S2) for determining at least one required for a route control element (2) and to be implemented by at least one of the A ^¬ provide the route from the determined adjusting element (2) functional order is formed, and the actuating elements (2) are each designed to determine at least one to be performed for the realization of the order determined for them Stellmaßnahme.

10. Device according to claim 9,

d a d u r c h e c e n c i n e s that

the device comprises at least two interlocking devices (Sl, S2), both of which are at least partially connected to the same control elements (2), wherein the control elements (2) are designed to realize orders of both interlocking devices (Sl, S2).