The invention is based on a priority application 03291782.5 which is hereby incorporated by reference.
Track clear signalling devices are among the basic devices in railway signalling. These devices ascertain the occupancy status of successive individual sections of a length of track, on the basis of which signalling is carried out to trains entering or passing through this length of track.
Track clear signalling is performed increasingly by means of so-called axle counting systems, in which the axles of trains entering and exiting are counted at individual counting points and these results are compared with one another in a suitable manner. To determine the occupancy of a track section, the axles of a train entering and exiting are counted at certain points at the start of the section by means of a counting-in point and at the end of the section by means of a counting-out point. By forming the difference between the axles counted in and counted out it can be determined whether the track section is clear or occupied, i.e. one of the states “clear” or “occupied” can be assigned to the track section.
In the modern multiple section axle counters from Alcatel SEL AG, for example, the axles are counted in microcontroller-based counting points on the track and the track clear signalling for all track sections is determined in the axle counter evaluation devices in the signal box.
The disadvantage compared with track circuits, in which the track clear signalling is determined by ascertaining the electrical resistance between the rails of a track along the entire track section, is that following a restart of an axle counter it cannot be established initially whether a train is located in the pertinent track section.
Following a restart of an axle counter, a manual reset of the track sections is thus necessary. The reset is relevant to safety and must therefore be carried out with the utmost care. To do this, the following procedures can be executed:
In a first type of reset, the train controller alone assumes full responsibility for carrying this out, once he has satisfied himself visually or by enquiry that the pertinent track section is clear.
In a second type of reset, the train controller likewise assumes responsibility, but to support him a train passes “to order” through the section with caution to ensure that the pertinent track section is clear.
In both the aforementioned types of reset, after it has been ensured that there is no train in the sections under consideration, a manual entry has to be made in the track clear signalling device, with which the pertinent counters or storage devices are then finally reset.
Since the security of the track clear signalling system against malfunctions is indispensable, all faults in the track clear signalling system must be detected and a secure shutdown must ensue as soon as a malfunction is detected. In the case of axle counter evaluation devices with a 2-computer architecture common in safety engineering, this results in a shutdown as soon as one of these computers fails. For routes with a high traffic volume, e.g. main Deutsche Bahn routes, evaluation devices are therefore executed in so-called 2 out of 3 computer technology, in which the failure of one computer can be tolerated and due to which the reliability and availability of the evaluation device and thus of the axle counter system as a whole is markedly increased.
However, in spite of the use of highly reliable computer systems, for example based on the previously mentioned 2 out of 3 computer technology, failures of the system can continue to occur if for example the transmission between one of the counting points and the axle counter evaluation device fails.
A restart of the axle counter system is also always necessary if there is a change in planning data or a software update of the axle counter evaluation device. In all these cases, a time-consuming manual reset that hinders operation continues to be required, as described above.
The object of the invention is to create a method and suitable means that facilitate an automatic reset in the event of a restart of an axle counting system.
This object is achieved according to the invention by a method for determining the occupancy status of a track section, in particular following a restart of an axle counting system, in which a counting-in axle counting point is provided at the start and a counting-out axle counting point at the end of the track section, and wherein the occupancy status is determined by a comparison of the counting values currently ascertained by these axle counting points. An counting point with a counting point logic, which has a counter for counting the currently passing axles of a traction vehicle and with a transmitting device for transmitting counter values, wherein a receiving device for receiving a storage command and at least one storage device for storing a current counting value are present, and evaluation device for determining the occupancy status of at least one track section with a receiving device for receiving counter values from at least two corresponding counting points and an evaluation logic for evaluating these counter values, wherein a transmitting device is present for transmitting a storage command to the counting points to store the current counter value in each case.
The fundamental idea of the invention is that even during the failure of the axle counting system or of a transmission section in the axle counting system, the counting points continue to operate independently and information, in particular counting values relating to the status prior to the failure, is saved securely in signalling terms. Following a restart of the axle counting system, this saved information is linked with the current counting values transmitted by the counting points to the evaluation device, in order to regenerate the current occupancy status of the track sections.
When determining the occupancy status of this track section afresh, a difference in the saved values and a difference in the current counting values are formed respectively. The track section (A1) is only clear if both differences are identical.
The axle counting system advantageously comprises a central axle counting evaluation device, which is connected to the counting points. When the track section becomes clear, the axle counting evaluation device transmits a command to save the current counting value in each case to the counting point counting in and the counting point counting out. Each counting point transmits its last stored value together with the currently determined counting value to the evaluation device.
Each counting point according to the invention contains for this purpose a counting-in storage device and a counting-out storage device, in each of which an axle number can be stored, as well as two further storage devices respectively, a status storage device for the counting-in storage device, in short counting-in status storage device, and a status storage device for the counting-out storage device, in short counting-out status storage device, for storing respectively a digital status value of the counting point as a counter-in and counter-out; which assume respectively the meaning “current” or “not current”.
Following starting of a counting point, the status values are set initially to “not current”. Furthermore, the counting points set the status storage devices to “not current” if:
As also known from the prior art, the central evaluation device determines the track clear signalling for a section by processing the currently ascertained and transmitted axle numbers of those counting points that delimit this section. As soon as a section assumes the status “clear”, it transmits a command to these counting points with which the respectively current counting value is to be saved n their counting-in storage device and their counting-out storage device. The status value is set by the pertinent counting point to “current” in this case and filed in the pertinent counting-in status storage device and counting-out status storage device respectively. Thus the axle numbers that have resulted in the clear signalling of this section are filed in the counting points of a section.
The counting points signal respectively the counting values stored in the counting-in and counting-out storage devices as well as the contents of the status storage devices to the evaluation device. These messages can be sent cyclically or following a request by the evaluation device. These contents of the counting and status storage devices are preferably transmitted together with the current counting values to the evaluation device, so that they can be used there if necessary for regeneration without the counting points having to be informed of a failure.
Due to this, as described at the beginning, the occupancy status on a section of line can be determined directly following a restart, even if train movements have taken place in the meantime or new counting information could not be received for a certain time. Following restoration of a failed data transmission between a counting point and the evaluation device, the track free signalling of the sections affected by this can be restored. Following a change in the planning data of the axle counter evaluation device, the track clear signalling can be restored for those sections for which the configuration has not changed.
The evaluation device can perform regeneration for a line section if the status storage devices of all counting points of this section are signalled as “current”. If this is not the case, the pertinent section is regarded initially as “disrupted” following a restart. If applicable, it is also possible to bring several track sections together first of all so that only counting values of counters with currently signalled counting storage devices are required.
The method according to the invention has the advantage compared with manual and conventional methods that following a restart of the evaluation device, for example as a result of maintenance work, repair or a software update of the evaluation device, the track clear signalling of all sections can be regenerated automatically and without any significant loss of time. The method according to the invention can be used with any computer architectures of the evaluation device, for example with a 2 out of 3 or 2 out of 2 computer configuration.
The method according to the invention is explained further below on the basis of a simple example with reference to the drawings:
The counting points ZP1, ZP2 and ZP2 each consist according to the prior art of an axle detector device, which is attached at a suitable spacing and a suitable height next to the rail. Each axle detector device has a transmitting coil, which generates an electromagnetic alternating field around the rail. A receiving coil is arranged in the sphere of influence of this alternating field, for example opposite the transmitting coil on the other side of the rail. When an axle travels past, the field geometry of the alternating field changes. This change is received by the receiving coil and evaluated in an electronic evaluation circuit, in which it is decided whether an axle has passed or not. The result is transmitted to a counting point computer, which increments a counting storage device accordingly. The evaluation circuit, counting point computer, storage device and communication device can be accommodated in a housing close to the respective detector.
As shown in
The storage of counting values in the counting points ZP1-ZP3 shown in
According to the invention, the first, second and third counting point ZP1, ZP2 and ZP3 each has a storage device S1, S2 and S3, with the following storage cells:
The above mentioned counting-in status storage devices counting-in storage devices ST_EIN1, ST_EIN2 or ST_EIN3 and counting-out status storage devices ST_AUS1, ST_AUS2 or ST_AUS3 are not shown, in which bit information is stored respectively that indicates whether the corresponding counting-in storage device EIN1, EIN2 or EIN3 and counting-out storage device AUS1, AUS2 or AUS3 has stored a valid counting value.
In the example shown here, the second counting point ZP2 serves both as a counting-out point from the first section A1 and as a counting-in point into the second section A2. Of the first counting point ZP1 only the counting-in function into the first section A1 and of the third counting point ZP3 only the counting-out function from the second section A2 are considered here. The first counting-out storage device AUS1 and the third counting-in storage device EIN3 and the related status storage devices will thus not be considered further below.
In real systems, however, each counting point normally acts both as a counting-in point into the section lying ahead and as a counting-out point from the section lying behind.
The following exemplary initial status is assumed here:
Below the storage device contents of the counters, counting-in and counting-out storage devices of the counting points respectively at the times at which the first axle of the traction vehicle TFZ reaches the locations a-f:
It is to be shown with reference to
To determine the occupancy of the first track section A1, a difference is formed respectively between the stored values of the first counting-in storage device EIN1 and the second counting-out storage device AUS 2 and between the current counting values AKT1 and AKT2 and it is verified whether these differences correspond:
(AKT1−AKT2)−(EIN1−AUS2)=0 ?
If yes, the first section A1 is clear, otherwise it is occupied.
To determine the occupancy of the second track section A2, the following test is carried out accordingly:
(AKT2−AKT3)−(EIN2−AUS3)=0 ?
Naturally the equations described above can be rearranged in any mathematical form, for example they can be put into the following form:
(AKT1−EIN1)−(AKT2−AUS2)=0 ? and
(AKT2−EIN2)−(AKT3−AUS3)=0 ?
It is then also possible, for example, for the first counting point ZP1 to form the difference (AKT1−EIN1), the second counting point ZP2 to form the differences (AKT2−AUS2) and (AKT2−EIN2) and the third counting point ZP3 to form the difference (AKT3−AUS3) in advance and for the counting points to transmit respectively only these differences to the evaluation device AZA.
As shown in
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