EP0794888A1

EP0794888A1 - Automatic train running control system

Info

Publication number: EP0794888A1
Application number: EP95938358A
Authority: EP
Inventors: Hans-Arnim Lange
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 1994-11-30
Filing date: 1995-11-22
Publication date: 1997-09-17
Also published as: WO1996016854A1; CN1171760A; DE4444518A1

Abstract

A line control device (SG) only supplies every second (1, 3, 5) or third section of a line conductor with data which are significant for the further travel of trains. In this way, longer line conductor regions can be controlled by a single line control device. The trains update the data transmitted thereto according to the distance they have travelled since receiving these data. To this end, when there is no call from the line control system, all trains which are suitable for continuous automatic train-running control and so equipped, are able to further process a predetermined distance by means of the very latest data received whose validity has been acknowledged.

Description

description

Train control device

The invention relates to a train control device according to the preamble of claim 1. Such a train control device is known from DE-AS 20 01 321. In this DE-AS, a device for train protection with line-shaped signal transmission between train and route for section areas divided into sections is reported, in which each train or vehicle determines its location from the LZB sections it has traveled through and / or by means of a path measurement determined and in which a route center assigned to the route area elaborates driving commands for the trains and transmits these to the trains in a location-selective manner via a line conductor laid in the track. For this purpose, the line conductor divides the route into individual sections by crossing his forward and return conductor. At the address of these sections, the route control center transmits the travel commands it has worked out to the trains, and the trains determine which travel commands are intended for them from the knowledge of the sections they are traveling on. In contrast to other similar facilities (DE-PS 11 76 698), in which the route control center only calls up the sections reported as occupied in a previous query cycle and supplies them with data that is important for the further travel of the trains, the route control center supplies the Device known from DE-AS, irrespective of the route occupancy, cyclically follows all sections of the route area with information. The reason for this is that these routes are also or only used by trains that are not set up to inform the route center of their respective destination.

The information that can be transmitted from the route control center represents driving commands and each includes one Section identifier, among other things, an identifier for a target speed related to the end of the respective section. With less intensive route-side data processing, it would also be possible to transmit the trains in the individual sections a target speed and their respective distance to this target; The trains then use the transmitted data to determine the driving speeds to be observed at their respective travel location and adapt their actual advancement speeds to the target speeds determined in this way. Antenna arrangements and devices for receiving and evaluating this data are provided on the vehicles for the transmission of data to the vehicles; data transmission takes the form of data telegrams.

In addition to railway lines that are fully equipped with facilities for line-shaped signal transmission between train and route, there are also railway tracks in which only very specific, shorter route areas are provided with such facilities. Such devices are used, for example, to inductively transmit the signal concept connected to a light signal to a train approaching the light signal. If a route control center or a route device supplies such a train with driving commands that apply to the individual sections and the train provides them

Can assign driving commands to the individual sections, there is the possibility of highly precise automatic or manual braking to the target signal or another waypoint.

Because of the cyclical supply of all sections of a line conductor and because of the minimum telegram sequence time required for the control of the trains, the number of line conductor sections to be supplied by a line device is limited. This can result in the case that the line conductor length available for the transmission of travel commands, what is meant is the number of sections, shorter than the braking distance of a train. This means that a further line device has to be provided to support a further line conductor that is limited to the first line conductor.

It is an object of the present invention to provide a train influencing device according to the preamble of patent claim 1, with which it is possible to travel on routes traveled by trains that are not or not all equipped with devices for transmitting their respective travel location to one Control center are set up to transmit important information for the continued travel of the trains to them in a location-selective manner, and to make available only a single route device for this even with longer braking distances.

The invention solves this problem by the characterizing features of patent claim 1.

The particular advantage of the train protection device according to the invention lies in the fact that all vehicles which are set up to inform a control point of their respective place of travel and which are then usually supplied with travel commands in a location-selective manner in each section reported by them, including these for only can record and process every second or third section of transmitted data without the need for any hardware or software adjustments on the vehicles.

Advantageous refinements and developments of the train control device according to the invention are specified in the subclaims.

The invention is explained below with reference to an embodiment illustrated in the drawing. The drawing shows in 1 shows a line area provided with a line conductor in front of a light signal, and FIG. 2 shows a diagram to illustrate the mode of operation of the invention.

FIG. 1 shows a track G which is traversed by a train Z from left to right in the direction of travel. Next to the track is a light signal S, which, for. B. shows the stop signal concept. Using a line device L beginning with the light signal and extending against the direction of travel over a predetermined length with the sections 1 to 6, route commands developed there from a line device SG for braking the train to target the light signal are to be transmitted to the approaching train. The longitudinal extension of the line conductor L should correspond at least to the braking distance of the train from a maximum advance speed to the stop at the signal. In addition to this data, which each refer to the end of a section defined by an intersection, further data can be transmitted, such as B. Track slopes and slow speed points. All this information is fed into the line conductor via the schematically indicated route device SG, the data applicable to the individual sections being given an identifier which denotes the section to which the data apply; in the case of single-track routes, identifiers must also be transmitted which allow the trains to select the data intended for their direction of travel.

According to the teaching of the present invention, the route device SG transmits to the train Z advancing to a destination the data important for its onward journey not necessarily for each individual section, but at least outside the vicinity of the destination point S, for example, only in every second section, that is to say in the sections in the present case 1, 3 and 5. The train itself measures that of it in the individual 5 sections covered route and uses this to determine its respective distance from the destination point in a manner known per se. In accordance with this distance, the train modifies an advancing speed that has been communicated to it and applies to the section in question, in a manner known per se, by building up a braking curve that is scanned depending on the path. The inventive finding is that in the event that it does not receive any data such as target speed, target distance and / or advancement speed that is important for its further travel, for example for track section 4, the train continues to accept the data received for the previous section 3 and this according to the route he has traveled since then. For the illustrated embodiment, this means that the train reduces the distance value x3 transmitted to it when traveling in section 3 by the travel distance xZ since then and thus determines its current distance to the signal showing the stop. Details can be found in the diagram in FIG. 2, in which the target speeds applicable for the beginning of LZB sections 1, 3 and 5 are particularly marked. The

When updating the last transmitted travel commands, train Z can also synchronize its vehicle-side displacement measuring devices at the line conductor crossing point between sections 3 and 4 and thus take the travel path xZ * into account when determining its actual travel location.

All trains that are supplied with location commands on conventional LZB routes are already set up for the intended updating of data by the software that is stamped on them, because there too, updating of data if a line crossing point is not recognized and / or if a section that has not been called is recognized is provided; According to today's rules, vehicles for LZB use on routes with vehicle location are set up to prevent the loss of LZB signals on a loop. length of 300 m = 3 sections tolerated. The advantage of the train control device according to the invention lies in the utilization of this behavior of LZB-compatible trains in connection with line conductor areas in which the transmission of location reports to a route device or a control center is not mandatory. The further great advantage of the train control device according to the invention is that a route device can now supply a much larger route area with driving commands than on routes on which each individual section is to be supplied with location-selective data.

Deviating from the exemplary embodiment explained above, it can make sense not to supply data in principle to every second or third section, but rather, if appropriate, also to provide several sections which follow one another directly. This can be provided, for example, in the vicinity of the respective target point in order to be able to carry out highly precise target braking there. For the illustration in FIG. 1, this would mean that in addition to sections 1, 3 and 5, the line device also includes, for. B. section 6 is supplied with data that are then recorded and evaluated by the train in a location-selective manner.

The train control device according to the invention can not only be used with advantage in the close range of light signals or slow speed points, but can of course also be used for other LZB route areas. Here, too, it is possible to supply data from a track unit to a region that is twice or three times as long as in

Installations in which data is to be transmitted for each section. The length of a line conductor to be supplied from a line device and thus the number of LZB sections to be supplied with data depends on the maximum possible interpolation path defined in the train control system and the minimum follow-up time of telegrams.

Claims

claims

1. Train control device for section areas divided into sections with a line conductor laid in the track for the location-selective transmission of data important for the continuation of the trains / vehicles to them and with a route device for the cyclical location-selective supply of the sections with data, characterized in that the route device (SG) at least outside the near range of a destination (S) only supplies data to every second (1, 3, 5) or third section and that the trains (Z) / vehicles when traveling to a section not supplied with data contain the data applicable to this section determine in a manner known per se from the data transmitted for the previous section or the previous sections by updating according to the distance traveled (xZ) since the previous section was penetrated.

2. Train control device according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the data transmission takes place telegrams with the assignment of a section identifier.

3. Train control device according to claim 1 or 2, characterized in that the line conductor is designed as a line extension of limited extent for transmitting travel commands of the signal signal connected to a light signal (S) lying ahead, together with at least the end of the individual sections (1 , 3, 5) related distance information (xl, x3, x5) to the light signal to an approaching train / vehicle.