Method for operating an automatic train control system and automatic train control system

Abstract

A method operates an automatic train control system which has an electronic signal box, a balize and a frequency track circuit. To configure the train control system so as to be constructed from components of the European train control system and of the frequency track circuit without substantial additional development effort, the balize is acted upon by indicator messages of a first type of the electronic signal box via an actuation module for modular elements having an addressable memory for the number of currently free block route segments. Indicator messages of a third type are created from indicator messages of a second type. A functional relationship between the addresses of the memory and code information of the frequency track circuit is taken into account during the creation of the third indicator messages. A transmitter of the frequency track circuit is acted upon as a result of the third indicator messages.

Claims

1. A method for operating an automatic train control system containing an electronic interlocking connected to a balise and a frequency track circuit, which comprises the steps of: actuating the balise via an operating module for modular elements by means of pointer telegrams of a first kind, namely first pointer telegrams, of the electronic interlocking, the operating module having an addressable memory for a number of currently clear block sections; creating pointer telegrams of a third kind, namely third pointer telegrams, from pointer telegrams of a second kind, namely second pointer telegrams, of the electronic interlocking, wherein a functional relationship between addresses of the addressable memory and code information of the frequency track circuit is taken in to account for creating the third pointer telegrams; and actuating at least one transmitter of the frequency track circuit via a relay arrangement in response to the third pointer telegrams.

2. The method according to claim 1, which further comprises: providing a Chinese train control system (CTCS) level 2 pointer telegrams as the first pointer telegrams; and providing a European train control system level 2 pointer telegrams as the second pointer telegrams; providing a CTCS balise as the balise; and using a bijective function for creating the third pointer telegrams.

3. The method according to claim 1, which further comprises converting the first pointer telegrams into communications telegrams in a telegram converter.

4. The method according to claim 1, which further comprises feeding the third pointer telegrams to a digital input/output device in which operating signals for the relay arrangement are generated.

5. An automatic train control system, comprising: an electronic interlocking generating pointer telegrams of a first kind, namely first pointer telegrams, and pointer telegrams of a second kind, namely second pointer telegrams; a balise connected to said electronic interlocking; a frequency track circuit connected to said electronic interlocking and having at least one transmitter; an operating module for modular elements connected to said electronic interlocking, said operating module having an addressable memory for a number of clear block sections and having said balise as one of said modular elements; a pointer telegram creator connected to said electronic interlocking, said pointer telegram creator creating the pointer telegrams of a third kind, namely third pointer telegrams taking a functional relationship between addresses of said addressable memory and code information of said frequency track circuit into account; a relay arrangement connected to said at least one transmitter of said frequency track circuit; and a digital input/output device connected to said pointer telegram creator, said digital input/output device generating operating signals for said relay arrangement disposed downstream of said digital input/output device.

6. The train control system according to claim 5, wherein in a case of the first pointer telegrams as Chinese train control system level 2 (CTCS-L2) pointer telegrams and the second pointer telegrams as European train control system level 2 (ETCS-L1) pointer telegrams, said pointer telegram creator is implemented such that the third pointer telegrams are created from the second pointer telegrams according to a bijective function, and said balise is a CTCS balise.

7. The train control system according to claim 5, further comprising a telegram converter, said operating module is connected to said electronic interlocking via said telegram converter.

8. The train control system according to claim 5, wherein the first pointer telegrams are Chinese train control system level 2 pointer telegrams and the second pointer telegrams are European train control system level 2 pointer telegrams.

Description

BRIEF DESCRIPTION OF THE DRAWING

(1) The single FIGURE of the drawing is a block diagram of a train control system according to the invention.

DESCRIPTION OF THE INVENTION

(2) As FIG. 1 specifically shows, the train control system 1 presented has an electronic interlocking 2 which can preferably be the Simis W electronic interlocking by Siemens Aktiengesellschaft designed for the ETCS train control system, as described in a publication Simis W electronic interlocking Safe and economical (2008).

(3) Pointer telegrams of the first kind, i.e. first pointer telegrams ZT1, of the type provided for a balise 3 according to the Chinese CTCS Level 2 are generated by the electronic interlocking 2. In a converter 4 downstream of the electronic interlocking 2 or more specifically in a component known in the industry as UCOM-I for short, the first pointer telegrams ZT1 are converted into communications-type pointer telegrams ZTk, e.g. using ISDN technology. These converted pointer telegrams ZTk are fed to an operating module 5 for modular elements which is termed MSTT in the technical language. The operating module 5 contains an addressable memory 5a (not shown) having addresses provided according to the number of vacant block sections of the balise 3. Depending on the number of currently vacant block sections, the balise 5 is actuated accordingly by the operating module 5.

(4) Disposed downstream of the electronic interlocking 2 in the exemplary embodiment shown is a pointer telegram creator 6 in which pointer telegrams of a third kind, i.e. third pointer telegrams ZT3, are created from pointer telegrams of a second kind, i.e. second pointer telegrams ZT2 generated by the electronic interlocking 2, as will be explained in greater detail below. Disposed downstream of the pointer telegram creator 6 is an input/output device 7 termed UNOM/INOM for short which generates operating signals Sr for a downstream relay arrangement 8 from the digital third pointer telegrams ZT3. Connected to said relay arrangement 8 is a transmitter 9 of a frequency track circuit 10 which generates signals in a state corresponding to the signal state of the balise 3. These signals can be picked off from a track vacancy detection system 11 by a rail vehicle.

(5) Table 1 below shows the relationship between a number of converted pointer telegrams ZTk, a number of addresses Add1 to Add6 of the memory 5a and the meaning of the respective memory location, wherein the table reproduces only one section of a complete table.

(6) TABLE-US-00001 TABLE 1 Addresses of Converted pointer memory 5a Meaning telegrams ZTk Add 1 8 block sections ahead clear Telegram 1 Add 2 7 block sections ahead clear Telegram 2 Add 3 6 block sections ahead clear Telegram 3 Add 4 5 block sections ahead clear Telegram 4 Add 5 4 block sections ahead clear Telegram 5 Add 6 3 block sections ahead clear Telegram 6 . . . . . . . . .

(7) Another Table 2 shows code information L5 to LU for the frequency track circuit 10 of the CTCS Level 2 system and its respective meaning, wherein code information LU2 which stands for two clear block sections ahead is also taken into account.

(8) TABLE-US-00002 TABLE 2 Code information Meaning L5 8 block sections ahead clear L4 7 block sections ahead clear L3 6 block sections ahead clear L2 5 block sections ahead clear L 4 block sections ahead clear LU 3 block sections ahead clear . . . . . .

(9) Comparing the two tables with one another, it can be seen that a comparatively simple functional relationship exists between the addresses of the memory 5a in the operating module 5 for the balise 3 and the code information for the frequency track circuit 10, which relationship can be described by a bijective function. This function is provided by a telegram creator 6 so that, by means of the third pointer telegrams ZT3, the transmitter 9 and therefore also the track vacancy detection system 11 of the frequency track circuit 10 is actuated via the input/output device 7 and the relay arrangement 8 in the same way as the balise 3.

(10) Thus it is therefore possible, by introducing a simple bijective function and using a relay arrangement, to create a CTCS Level 2 system from components of the ETCS system and of a frequency track circuit with relatively little cost/complexity.