EP0340597A2 - Method to signal the free and occupied state of track sections in railway shunt arrangements, and device to perform this method - Google Patents

Abstract

During shunting, it occasionally occurs that a points-circuit zone is prematurely reported as free below an unusually long vehicle by the associated track free report device. Special measures then have to be taken in order to prevent the points turning below this unusually long vehicle. For this purpose, the invention provides for the free report signal of the track free report device (GFAW) only to be evaluated as a free report of the associated track section if it has been ensured that all the axles of a vehicle (FZ) or a group of vehicles travelling over the section have previously travelled into the section. For the first section in the driving direction of a track system, this is determined by an indicator (EL) which detects the completion of the passing of the vehicle or of the group of vehicles. The indicator signal (EFWA) which occurs earlier in time is connected to the free report signal (GFWA &uarr& ) of the track free report device to form a vehicle end code (FEZA) which indicates that the vehicle or the group of vehicles has left the first track section. This vehicle end code (FEZA) is connected, as the vehicle or group of vehicles advances further, to the free report signal (GFZA &uarr& ) of the track free report device of the following track section to form a new vehicle end code (FEWB) for this section which indicates that the second section is completely cleared. This process continues as the vehicle or group of vehicles advances from section to section. <IMAGE>

Description

The invention relates to a method according to the preamble of claim 1 and to a device for performing this method.

In order to achieve high shunting performance, it is necessary to design the switch effective zones of the distribution switches lying in the path to the directional tracks as short as possible, because the longer the individual switches are occupied, the greater the time interval between the vehicles running in succession. The minimum turnout zone length is determined, in addition to the mechanics of the turnout, the maximum changeover time of the turnout drive and the maximum possible advancement speed of the vehicles on the turnout. The effective zone length of a switch is generally 14 meters. Track circuits or axle counters are used to monitor the effective zones. If an excessively long vehicle with a center distance that is greater than the effective zone length passes a distribution switch, the effective zone is temporarily released by the clearance detection device assigned to the switch under the excessively long vehicle without it being actually free. The switch could then be set automatically for a following vehicle and circulate under the excessively long vehicle. This would lead to serious disruptions in runtime operation.

In order to avoid this, restrictive operational precautionary measures, such as reducing the pull-off speed or switching off the automatic drain when running overlong vehicles, have to be accepted as a rule in older drainage systems. In modern drainage systems, in addition to conventional track vacancy detection devices such as axle counters or track circuits, the individual distribution points are also assigned induction loops to monitor the associated turnout zones net. These induction loops are the frequency-determining elements of assigned oscillators, the oscillation behavior of which changes markedly when railway vehicles pass the induction loops. The output of a free signal for a turnout zone is made dependent on the fact that in addition to a first free signal for the turnout zone, which is brought about by a track circuit or an axle counter, there is also a corresponding free signal which has been initiated via the associated induction loop. Oversized vehicles can then still influence the track vacancy detection device of a turnout zone in the direction of an untimely vacancy detection; the free signal coming from this has no effect, however, because it is recognized via the induction loop that the turnout zone is still occupied. Only when both the induction loop and the track vacancy detection device assigned to the same turnout zone have independently recognized that the track section they are monitoring is clear, is the turnout zone actually released (Elsners Taschenbuch der Eisenbahntechnik 1982, p. 316).

Instead of induction loops for detecting passing railway vehicles, any other suitable indicators, for example light barriers, can also be used, via which a statement can be made as to whether or not a vehicle or group of vehicles has completely passed a particular location. Such an indicator based on light barrier is disclosed in DE-OS 20 46 507. There, the light barrier monitors a turnout zone in the area of its entry end and, after the complete passage of a vehicle or a group of vehicles consisting of several vehicles, emits a first vehicle end indicator when it is lightened, which serves to set a memory. The first vehicle end indicator indicates that a vehicle or group of vehicles has passed the indicator with all its axes and has completely entered the subsequent track section. As soon as the track clearance detection device assigned to the turnout zone is activated when the zone is subsequently cleared triggers a free signal, the memory is read out. If it had previously been set, it now causes a second vehicle registration number to be issued. This end-of-vehicle indicator indicates that the vehicle or group of vehicles previously entering the effective zone has entered and exited the monitored section with all its axles. If the turnout is passed by an excessively long vehicle, the turnout zone is temporarily released via the associated track vacancy detection device; However, since the switching distance of the light barrier is still interrupted at this point, the end of vehicle identifier that is still to be stored in the memory is missing and the second end of vehicle identifier cannot be formed. Only when the turnout zone is released again after the track section has been occupied again and the light barrier has been brightened, is the memory set via the light barrier read out and the second vehicle end indicator is formed. Only then can the switch be set again.

If additional indicators are used to determine the complete passage of vehicles or groups of vehicles at predetermined locations within the effective zones of switches, it is prevented that the switches can circulate under excessively long vehicles; However, since all switches in the switch distribution zone of a shunting location have to be equipped with additional indicators of this type, the effort required for the secure clearing of the switch effective zones is considerable.

The object of the invention is to provide a method according to the preamble of claim 1, with which a secure clearing of track sections is possible, but without such an additional indicator is required for each of these sections. The invention solves this problem by means of the characterizing features of patent claim 1. To ensure that the track sections of a maneuvering system are released free, it is only necessary to assign such an indicator to the first track section.

An advantageous development of the method according to the invention is specified in claim 2. According to the teaching of the main claim, the linkage between free-signaling signals and vehicle end-of-license plate should only take place when the automatic sequence control is switched on. This opens up the possibility of using the track system outside of the automatic sequence mode for maneuvering purposes and automatically releasing the track sections occupied during the clearing process without the need for a link to the vehicle end indicator.

The implementation of the method according to the invention requires a minimum of effort for each track section, namely only at least one memory and one track vacancy detection device.

The use of axle counters according to claim 4 creates the prerequisite for the assignment of the incoming and outgoing vehicle axles to the individual departments. This is important for longer track sections that can be used by several departments at the same time.

Claim 5 specifies the means which are required to form vehicle end indicators when several departments advance in a long track section and to advance to the respective subsequent track section.

For the technical implementation of the device according to the invention, according to the teaching of claim 6, each switch or a group of switches is assigned a microcomputer which receives the free signals from the track vacancy detection device of the associated turnout zone and the free signals from the track vacancy detection devices of the two intermediate sections adjacent to the following distribution switches, linked to the end of vehicle identifier stored in the direction of travel in the direction of travel and the end of vehicle identifier formed in the process is stored for the respectively following section of track. This requirement enables a modular construction of a track system from similar control modules, each of which can be represented, for example, by a separate single-board microcomputer.

According to claim 7, these microcomputers are also intended to include the counters for registering the incoming and outgoing vehicle axles; separate axle counters are not necessary.

The decision as to which of the two intermediate sections following a turnout effective zone in the direction of travel is to be deposited with a vehicle end indicator formed by a vehicle or a group of vehicles when clearing the turnout effective zone is determined according to the teaching of claim 8 by the actual position of the relevant turnout .

According to the teaching of claim 9, it is provided that the counting contacts from one track section simultaneously form the counting contacts for the track section that follows in the direction of travel. The simultaneous use of the counting contacts as counting-in and counting-out contacts means that the effort required to register and clear the track sections is kept to a minimum.

The use of double contacts for the direction-dependent evaluation of traffic events according to claim 10 is the prerequisite for the automatic clearing of the individual track sections during shunting movements outside of the automatic mode.

According to the teaching of claim 11, the counting capacity of the axle counters assigned to the individual track sections should be adapted to the maximum possible number of vehicle axles located simultaneously within one track section. This demonstrates a relatively inexpensive track monitoring system compared to track monitoring systems with the same effect as are known from track technology.

Suitable indicators for detecting the complete passage of a vehicle or a group of vehicles are, according to the features of claims 12 to 15, preferably light barriers, ultrasound detectors or induction loops, which are each to be arranged in such a way that they monitor an area within the first track section of the track system or the free signaling device separate track section that is longer than the center distance of the longest vehicle.

• Figur 1 die ersten drei Verteilweichen einer Rangier­anlage zusammen mit den für die gesicherte Freimeldung der ein­zelnen Abschnitte erforderlichen Überwachungsschaltmitteln und in
• Figure 2 ein Diagramm für ein die Gleisanlage nach Figur 1 passierendes überlanges Fahrzeug zusammen mit Meldekennzeichen von den einzelnen Gleisabschnitten zugeordneten Gleisfreimelde­einrichtungen und für die einzelnen Gleisabschnitte hinterlegte Fahrzeugende-Kennzeichen, die in zugehörigen Steuerungen zu neuen Fahrzeugende-Kennzeichen verknüpft werden.
• Fig. 3 zeigt ein Ausführungsbeispiel der Erfindung zum Überwachen eines Gleisabschnittes, der gleichzeitig von mehreren Abteilungen befahren werden kann.

The invention is explained below with reference to an embodiment shown in the drawing. The drawing shows in

• 1 shows the first three distribution points of a shunting system together with the monitoring switching means required for the secure clearing of the individual sections and in
• Figure 2 is a diagram for an overlong vehicle passing the track system according to Figure 1 together with the registration indicators of the track vacancy detection devices assigned to the individual track sections and the end-of-vehicle indicators stored for the individual track sections, which are linked in associated controls to new end-of-vehicle indicators.
• Fig. 3 shows an embodiment of the invention for monitoring a track section that can be used by several departments simultaneously.

Figure 1 shows a schematic representation of the three first distribution points VA, VB and VC of a railroad shunting system. Each switch area A, B or C shown with dash-dotted lines consists of a switch effective zone covering the actual switch and two adjoining intermediate sections. Turnout zone and intermediate sections are independently monitored by assigned track vacancy detection devices. The length of the turnout zones is as short as possible. The maximum speed of the passing vehicles and the changeover time of the turnout drives determine the minimum length of the lead length from the entry end of a turnout zone to the tip of the tongue, while the turnout construction determines the subsequent tongue lock length to the end of the turnout zone. The length of the intermediate sections depends on the geometry of the maneuvering system; the intermediate sections can be of any length under certain conditions, which will be discussed later. Axle counters, not shown, are used to monitor the switch effective zones and the intermediate sections. These axle counters are controlled directly or indirectly via so-called directional units of rail contacts, which are symbolized by black circles in the drawing. Double-rail contacts are used for direction-dependent counting of passing vehicle axles, which are connected in such a way that they simultaneously serve as counting contacts for each past and are used as counting contacts for the respective preceding section. The counters for outputting free and busy messages for the associated sections can be part of microcomputers which are assigned to the individual switch areas. The counting capacity of the individual counters is adapted to the maximum possible number of vehicle axles located simultaneously within a track section.

In addition to the track vacancy detection device represented by axle counters, the turnout zone WA of the first distribution points VA is also assigned an indicator which is set up to detect the complete passage of a passing vehicle or a vehicle group consisting of several vehicles. This indicator is shown in the drawing as a light barrier, which consists of a transmitter SL and a receiver EL. The light barrier is arranged in such a way that the receiver EL remains unilluminated as long as a vehicle passes the switching path of the light barrier shown in broken lines. For the relationships explained below with reference to FIG. 2, it is assumed that an excessively long vehicle FZ is to pass the track system shown in FIG. 1 coming from X to Y.

At time t1, the vehicle occupies the effective zone of the first distribution switch VA of the shunting system. It actuated the counting contacts EA1 of the assigned axle counter with its front wheel set and its structure interrupted the switching distance of the light barrier. The axle counter reports the turnout zone occupied; This is indicated in the drawing by an arrow pointing downward next to a message indicator GFWA (track vacancy detection GF of the active zone W of the turnout area A) of the associated track vacancy detection device; the switching distance of the light barrier is interrupted. The vehicle FZ is supposed to be an excessively long vehicle, the center distance of which is greater than the effective zone length of the distribution switch.

At time t2, the vehicle tip has the counting contacts AA1 at the end of the effective zone of the first distributor soft VA happens. The counter of the axis counter monitoring the effective zone determines that as many axes have moved out of the section as we have previously counted in; the turnout zone is temporarily released. This is symbolized in the drawing by an upward-pointing arrow next to the GFWA message indicator of the associated track vacancy detection device. However, the free signaling of the turnout zone remains ineffective for the time being because the switching distance of the light barrier is still interrupted, ie a control command for the first distribution switch VA that may be present by the automatic sequence control is not carried out. Simultaneously with the counting of the vehicle axles from the effective zone WA of the first distribution points, these vehicle axles were counted into the subsequent intermediate section ZA. The intermediate section was reported as being occupied, as can be seen from the downward-pointing arrow for the associated registration number GFZA.

At time t3, the switching status of the track vacancy detection devices and the light barrier has not changed: The light barrier is still interrupted, the track clearance detection device assigned to the turnout zone WA determines that the associated effective zone is free and the track clearance detection device assigned to the subsequent intermediate section ZA determines that the intermediate section monitored by her is occupied; Turnout zone and adjoining intermediate section remain reported as busy.

At time t4, the vehicle has advanced so far that its end has passed the light barrier monitoring area. The switching distance of the light barrier is closed again and the light barrier receiver issues a vehicle end indicator FEWA (vehicle end indicator FE for the effective zone W of the switch area A), which is stored in a memory assigned to the effective zone. This indicator means that the vehicle entering the effective zone has completely passed the light barrier. This means that all axles of the vehicle are moved into the effective zone and are detected by the associated track vacancy detection device. A later clear notification of the effective zone by the track vacancy detection device then implies the statement that the vehicle with all of it Axes are extended from the monitoring area of the track vacancy detection system. Previously, the track vacancy detection device assigned to the turnout zone of the first distribution switch had registered the entry of the rear wheel set of the vehicle into the turnout zone WA and had reported the turnout zone occupied again. The front wheel set of the vehicle is still in the intermediate section ZA between the first and the second distribution switch; the associated track vacancy detection system reports that the intermediate section is occupied.

At time t5, the vehicle with its front wheelset passed the inlet contacts EB1 at the start of the active zone of the second distribution switch VB and reported this active zone as occupied. This is illustrated by an arrow pointing downwards next to the GFWB registration number of the associated track vacancy detection system. The track vacancy detection device for the past intermediate section ZA has determined that as many axes from the section have been counted as were previously counted in and temporarily releases the intermediate section ZA. The effective zone of the first switch is still reported because the rear wheel set of the vehicle has not yet passed the outlet contacts AA2.

This happened at time t6. The track vacancy detection device assigned to the effective zone WA of the first distribution switch VA reports the effective zone freely. This means that the vehicle, which had previously passed the entire length of the light barrier, has now completely left the effective zone WA. The vacant signal GFWA ↑ of the track vacancy detection device of this section is now linked in a microcomputer MCA assigned to the first distribution switch with the vehicle end identifier FEWA of the light barrier receiver stored for the effective zone WA to form a new vehicle end identifier FEZA which is stored and displayed for the following intermediate section ZA that the vehicle with all its axles has entered the intermediate section and has been detected by the track vacancy detection device there. The vehicle end indicator FEWA stored for the past turnout zone WA is deleted. The switch VA can be set again as long as the free signal GFAW is present. The front wheelset of the vehicle occupies the switch effective zone of the distribution switch VB, the rear wheel set the intermediate section ZA between the distribution switches VA and VB. The associated track vacancy detection systems mark these sections as occupied with their messages GFWB ↓ and GFZA ↓.

At time t7, the vehicle has advanced so far that it has passed the counting contacts AB1 at the end of the effective zone of the second distribution switch VB with its front wheel set. The adjacent intermediate section ZB was reported to be occupied by the associated track vacancy detection device (GFZB ↓). The turnout zone of the turnout VB is temporarily released by the associated track vacancy detection device (GFWB ↑), because the rail contacts AB1 have reported as many counting impulses to the associated axle counter as were previously counted in via the rail contacts EW1. The intermediate section ZA between the first and the second distribution switch remains occupied by the rear wheelset of the vehicle. The switching status of the track vacancy detection devices is indicated by arrows next to the associated message indicator.

At time t8, the switching status of the track vacancy detection devices under consideration has not changed compared to the switching status at time t7. However, this is the case at time t9. Then the vehicle has advanced so far that it has passed the counting contacts EB1 at the start of the effective zone of the second distribution switch VB with its rear wheel set. The track vacancy detection device assigned to this effective zone reports the active zone WB occupied again. The same applies to the track vacancy detection device assigned to the intermediate section ZB behind the switch WB. When the vehicle leaves the intermediate section ZA between the points VA and VB, the track vacancy detection device assigned to this intermediate section has issued a corresponding message code GFZA ↑. This message identifier is now linked in the microcomputer MCA assigned to the switch area A with the vehicle end identifier FEZA stored there to form a new vehicle end identifier FEWB.

This vehicle end indicator is stored for the following turnout zone WB.

The vehicle end indicator FEWB would also be formed if, in the meantime, a following vehicle had entered the turnout zone of the first distribution switch. So it does not matter whether this section is actually free or occupied at the time of linking; for the derivation of the vehicle end indicator FEWB it is only important that the intermediate section ZA is registered and that it has been determined at some point in the past that the vehicle with all its axles had entered the intermediate section ZA.

At time t10, the vehicle under consideration has advanced so far that it has passed the counting contacts EE1 of a following switch area, only indicated in FIG. 1, with its front wheel set. The rear wheel set of the vehicle is still within the turnout zone WB of the distribution switch VB. The track vacancy detection device associated with the intermediate section ZB adjoining this effective zone determines that the same number of vehicle axles from the intermediate section were counted as were previously counted in; it then reports the intermediate section free (GFZB ↑). However, this free notification remains initially ineffective because no vehicle end indicator has yet been stored for this intermediate section from the previous point effective zone.

However, this is the case at time t11. The vehicle has advanced so far that it has passed the counting contacts AB1 of the turnout zone WB with its rear wheel set. The microcomputer MCB controlling the turnout area B now links the vehicle end identifier FEWB triggered when the intermediate section ZA located between the distribution switches VA and VB is cleared and stored for the following turnout effective zone WB with the release message GFWB ↑ of the switch effective zone of the second distribution switch VB to form a vehicle end identifier FEZB and stores this for the adjacent intermediate section ZB.

As the vehicle advances further, nothing changes in the occupancy status of the track system under consideration. Both at time t12 and at time t13, the intermediate section ZB adjoining the second distribution switch is reported to be occupied by the associated track vacancy detection device. The vehicle only completed the intermediate section at time t14 dig cleared and the responsible track vacancy detection system reports the section free. The microcomputer MCB assigned to the turnout areas B now links the vehicle end identifier FEZB stored for the intermediate section ZB with the free signal GFZB ↑ supplied by the track vacancy detection device of the intermediate section to a vehicle end identifier FEWC and stores this for the following track section.

The same procedure is used with the switch action zones and intermediate sections of the switches A to C with the switch action zones and intermediate sections of the other switches of the system. Here too, the free-reporting signal originating from a free-reporting device for an effective zone or an intermediate section is linked to the end-of-vehicle identifier previously stored for this section.

The decision as to which of the two track sections following a turnout effective zone in the direction of travel is to be deposited with the vehicle end indicator formed by a department when clearing the turnout effective zone is determined by the actual position of the relevant turnout. The actual position of the switch can be determined by indicators assigned to the switch or the drive, but can also be derived from which of the counting contacts at the end of the effective area of the distribution switch are actuated by the department.

The link between the free signal coming from the track vacancy detection device of a turnout zone or an intermediate section and the vehicle end indicator stored for this track section only takes place when the automatic sequence control is switched on. The reason for this is that when maneuvering outside of the automatic mode, it is not possible to gradually switch and link free signals and end-of-vehicle indicators from the first to the last section of the system. For this reason, outside of the automatic mode, the individual effective zones and intermediate sections are only released and occupied via their associated track vacancy detection devices.

In principle, it does not matter whether the track vacancy detection devices assigned to the individual track sections of a marshalling system are designed as axle counters or as track circuits, as long as it is ensured that in each track only vehicle axles of a single sequence can be located. If this requirement no longer exists, i.e. if a second department behind a leading department would enter a track section before the section is released by the preceding department, and if the track vacancy detection device assigned to this track section were designed as a track circuit, then the no end-of-vehicle license plate can be formed from the preceding department from the track section due to the lack of free notification and consequently cannot be stored for the following track section.

However, if you assign several axle counters that can be activated separately by the individual departments to the individual track sections as free reporting devices, there is the possibility of recognizing the entry and exit of the individual departments from a track section and the department-specific clearance signals output by the axle counters with the stored for this track section to link the associated vehicle end plates to new vehicle end plates for the subsequent track sections.

An exemplary embodiment of a device for linking such department-specific vacancy signals with associated vehicle end indicators is shown in FIG. 3. It is assumed that a section delimited by the metering points ZP1 and ZP2 is so long that it can be occupied by three successive departments at the same time. Corresponding to this number, the track section is assigned three counters Z1, Z2 and Z3 for counting incoming and outgoing vehicle axles and three memories S1, S2 and S3 for storing vehicle end indicators to be stored for this section. Each counter has a counting input E1, E2 or E3, which can be activated and deactivated as required, as well as a counting input A1, A2 or A3. Input circuits FE1 to FE3 are connected upstream of the memories S1 to S3, via which the vehicle end identifiers formed in the previous track section can be fed to them in succession. The are linked for the track section End-of-vehicle identifiers stored in the memories S1 to S3 with the department-specific vacancy signals initiated by the counters Z1 to Z3 in logic circuits U1 to U3. Their output signals are fed to the memory or the memories of the following track section via an OR circuit O.

It is assumed that a first section has completely entered the track section. Their respective number of axles has been fed to the counter Z1 via the counting input E1; the count-in inputs E2 and E3 of the counters Z2 and Z3 are deactivated via blocking signals previously supplied to them. In addition, the memory S1 has been set by a vehicle end indicator triggered by the department when the track section lying behind in the direction of travel has been completely cleared, and has been fed to it via the input circuit FE1; the input circuits FE2 and FE3 connected upstream of the two other memories S2 and S3 have been deactivated by previously applied blocking signals. As soon as the memory S1 has recorded the vehicle end identifier assigned to the first department, it deactivates the counting input E1 of the first counter Z1 and activates the counting input E2 of the second counter Z2. This completes the counting process for the first department, any subsequent axes are assigned to a second department and counted into the second counter Z2. In addition, the first memory S1 causes the deactivation of the input circuit FE1 and the activation of the input circuit FE2, which is connected upstream of the second memory S2, when the vehicle end identifier assigned to the first department is adopted. A vehicle end indicator issued by the second section in the direction of travel at a later time when this section is completely cleared is thus stored in the second memory S2. The counting process for the second department ends when this vehicle end number plate is deposited. The second memory deactivates the counting input E2 of the second counter Z2 with its output signal and simultaneously activates the counting input E3 of the third counter Z3. All subsequent vehicle axles are now a third incoming Department assigned and counted in counter Z3. The output signal of the second memory S2 also causes the deactivation of its input circuit FE2 and the activation of the input circuit FE3, which is connected upstream of the third memory S3. The vehicle end indicator, which is issued when the previous track section has been completely cleared and is assigned to the third department, thus arrives in the memory S3. This then uses its output signal to deactivate the counting input E3 assigned to the third counter Z3 and to activate the counting input E1 of the first counter Z1. Furthermore, the third memory deactivates its input circuit FE3 while simultaneously activating the input circuit E1 connected upstream of the first memory S1.

At any time, the first section leaves the section of track under consideration. Their axes are counted out of counter Z1 via counting input A1; the counting inputs A2 and A3 of the counters Z2 and Z3 are deactivated. By comparing the vehicle axles counted in and out of it, the counter Z1 recognizes when the first department has completely left the track section monitored by it. This is irrespective of whether there are other axes in the track section at this time; these are counted by the counters Z2 or Z3. As soon as the first counter Z1 has determined that all axes of the first department have left the section, it issues a clear signal to the first logic circuit U1. This systematically combines the vacant signal assigned to the first department with the vehicle end identifier stored for the department in the memory S1 to form an end vehicle identifier, which is stored via the OR circuit O for the following track section. The output of this vehicle end indicator leads to the deactivation of the counting input A1 for the counter Z1 and to the activation of the counting input A2 for the counter Z2. The next axes running out of the track section are thus assigned to the second department and counted from the counter Z2. If all axes of the second department have moved out of the monitored track section, the counter Z2 recognizes this from the correspondence of the counted and counted vehicle axes. He gives a department specific vacant signal to the link circuit U2, which links this vacant signal with the vehicle end identifier assigned to the second department and stored in the memory S2 and feeds this vehicle end identifier to the following track section via the OR circuit O With the output of this vehicle end indicator, the counting input A2 of the second counter Z2 is deactivated with simultaneous activation of the counting input A3 of the third counter Z3. All other vehicle axles leaving the section are now counted from the third counter Z3. If the third department has completely left the track section, the third counter sends a related free signal to the link circuit U3, which links this free signal with the vehicle end indicator for this department stored in the section S3 when it has completely moved out of the previous section and the vehicle end indicator transmitted to the memory (s) of the following track section. At the same time, the count input A3 of the third counter Z3 is deactivated and the count input of the first counter Z1 is activated. The facility is now in the state it had been in before the first section entered the track section.

Instead of separate logic circuits U1 to U3 for linking department-specific clearing signals with the associated vehicle end indicators, a common logic logic can also be provided for forming the vehicle end indicators to be passed on to the next track section. The linking of the vehicle axles entering and leaving a section with the end-of-vehicle markings stored for this section or for the following section makes it possible to track each department running through the section separately. This makes it possible for the first time to run individual track sections of a shunting system for any length. This applies in particular to the intermediate sections located between the effective zones of the distribution points, which for technical reasons often have to be carried out much longer than the effective points. The vehicle end license plates therefore do not need several shorter ones with the associated track free partial intermediate sections equipped with signaling devices can be forwarded from switch to switch, but can be passed on via an arbitrarily long intermediate section equipped with only one set of insertion contacts and one set of counting contacts. The maximum number of counters and memories to be provided for such a section depends on the length of the section concerned.

The counting-in and counting-out contacts can be implemented in any conventional technique. The indicator assigned to the effective zone of the first distribution switch for determining the complete passage of a vehicle or a group of vehicles has been assumed in the drawing as a light barrier. However, any other indicator suitable for this purpose can also be used here, for example an ultrasound transmitter, an induction loop installed between the tracks, or the free-signaling device of a separate track section, the length of which is greater than the greatest center distance of a vehicle traveling on the system.

Claims (15)

1.Procedure for clearing and busy reporting of track sections in railway shunting facilities that are continuously monitored by track detection systems that can be used by vehicles (FZ) whose center distance is greater than the shortest monitored track section length, using at least the first track section (WA) in the direction of travel Indicator (SL, EL) assigned to the track system to be monitored for issuing a vehicle end indicator (FEWA) when a section formed from a single vehicle or from a plurality of vehicles has completely passed, which is transmitted to the vehicle end with the free signal (GFWA ↑) of the track vacancy detection device assigned to the section. The indicator (FEZA) is linked, which indicates that the department has entered and left the section (WA) with all its axes, characterized in that
that the vehicle end indicator (FEZA) formed when the department exits the first track section (WA) of the system is stored for the respective subsequent track section (ZA),
that when the vehicle end indicator (FEZA) is stored for the next track section (ZA), the vehicle end indicator (FEWA) stored for the previous track section (WA) is deleted,
that if there is a free signal (GFZA ↑) for the following track section (ZA) it is checked whether a vehicle end indicator (FEZA) is stored for this track section, that if there is a simultaneous presence of the track release signal (GFZA ↑) and the stored vehicle end indicator ( FEZA) a vehicle end indicator (FEWB) is formed for the following track section (WB) and is stored for this
and that the other track sections of the track system are moved in the same way when the department advances. 2. The method according to claim 1, characterized in that the link of the back of the track section (WA) deposited in the direction of travel Vehicle end indicator (FEZA) with the current free signal (GFZA ↑) of the respective track section (ZA) is only given when the automatic sequence control is switched on. 3. Device for performing the method according to claim 1 or claim 1 and 2, characterized in that the track sections at least one memory (S1) for storing a vehicle end indicator, a fine alarm device (Z1) for monitoring the track section and a link (U1) for outputting a vehicle end indicator to the respective following track section and for deleting the memory (S1). 4. Device according to claim 3, characterized in that the fine signaling device is designed as an axle counting device. 5. A device according to claim 3, characterized in that for each track section a number of memories (S1, S2, S3) corresponding to the maximum possible number of departments traveling at the same time for storing vehicle end indicators for successively entering departments and an equal size Number of counters (Z1, Z2, Z3) are provided for registering incoming and outgoing vehicle axles, of which one (S1, Z1) is initially activated when the track section is free,
that the storage of a first, second etc. end-of-vehicle identifier for the track section in the first, second etc. memory (S1) deactivates the counting input (E1) of the first, second etc. counter (Z1) and activates the counting input (E2) of the second, third etc. counter (Z2) and the activation of the second, third etc. memory (S2), the last memory (S3) when a vehicle end indicator for the track section is adopted the activation of the first memory (S1) and the activation of the counting input (E1) of the first counter (Z1) causes the formation or deposit of a first, second, etc. Vehicle end indicator for the respective track section: deactivating the counting input (A1) of the first, second etc. counter (Z1) and activating the counting input (A2) of the second, third etc. counter (Z2) and deleting the first, second, etc Memory (S1) causes, the depositing of the vehicle end indicator derived from the vehicle end indicator stored in the last memory (S3) for the following track section activates the counting input (A1) of the first counter (Z1). 6. Device according to one of claims 3, 4 or 5, characterized in that each switch (VB) or a group of switches, a microcomputer (MCB) is assigned, which the free signal (GFWB ↑) assigned to the associated turnout zone (BW) Free reporting device and the free reporting signals (GFZB ↑) from the adjacent intermediate sections (ZB) to the following distribution points (VC) assigned to the free reporting devices, linked to the track section (ZA) for the respective department, which is stored in the direction of travel and the vehicle end identifier (FEZB) thus formed is stored for the following track section (ZB). 7. Device according to claim 6, characterized in that the microcomputers contain the counters for registering the vehicle axles entering and leaving the associated track sections. 8. Device according to one of claims 4, 5 or 6, characterized in that the decision as to which of the two intermediate sections (ZB) following in the direction of travel on a switch effective zone (WB) is a vehicle end indicator (FEZB) formed when clearing the switch effective zone. is to be deposited, is determined by the actual position of the turnout concerned (VB). 9. Device according to one of claims 4 to 7, characterized in that the counting contacts acting on the counting input of a counter simultaneously form the counting contacts for a counter assigned to the respective track section. 10. Device according to one of claims 4 to 7 or 9, characterized in that the counting-in and counting-out contacts are represented by double contacts for the direction-dependent evaluation of traffic events. 11. Device according to one of claims 4 to 7, characterized in that the counters have a counting capacity adapted to the maximum possible number of vehicle axles located simultaneously within a track section. 12. Device for performing the method according to claim 1, characterized in that the indicator for detecting the complete passage of a department is formed by a light barrier (SL, EL) or a light barrier grid, which or the one track area within the first track section (WA ) of the track system monitored. 13. Device for carrying out the method according to claim 1, characterized in that the indicator for detecting the complete passage of a department is formed by an ultrasound detector which monitors a track area within the first track section of the track system. 14. Device for performing the method according to claim 1, characterized in that the indicator for detecting the complete passage of a department is formed by an induction loop which monitors a track area within the first track section of the track system. 15. A device for carrying out the method according to claim 1, characterized in that the indicator for detecting the complete passage of a department through the track vacancy detection device of a track section located in front of the first track section of the track system or projecting into this track section is shown, the length of which is greater than that maximum center distance of a vehicle.

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