EP0788961A2 - Method of treating hardware failures at clear track signalling by means of axle counting and device for carrying out the method - Google Patents

Abstract

The method of handling hardware failure or breakdown, during a 'track free' announcement, based on the axle count method by overlap of the count-result of a counting point, recognised as a fault, by the count results of counting points on both sides of the faulty count point. For each counting point (ZP3) loaded by several simultaneously possible routes, besides a first axle count result, a second axle count result, dependent on the first, is determined, and for 'free' and 'occupied' (or busy) track announcements for the track section being negotiated, the second axle count is compared with the axle count results of the remaining counting points (ZP21,ZP22) of this track section.

Description

German patent application P 195 22 584 discloses a method for treating counting disturbances in track vacancy detection by means of axle counting, in which a counting disturbance is detected at a counting point when wheel impulses which cannot be assigned are detected, which, until a later correction of the counting result, results in regular clearance reporting of the track sections affected by the counting disorder prevented. The counting disturbance is corrected by comparing axle counting results, which are arranged by counting points in front of and behind the counting point affected by the counting disturbance. These metering points jointly form a correction section temporarily installed in a computer, which corrects the counting result of the temporarily disturbed metering point if the counting results match its entry and exit points and reports the track sections reported as occupied within the correction track section due to malfunction.

The above-mentioned method for the treatment of counting disorders can be used not only on through-tracks, but also on branching tracks. There, the correction sections to be assigned to the individual points of delivery comprise as many neighboring points of delivery as there are tracks from which trains can travel on the relevant points of delivery or can be reached from the point of delivery in question. Which metering points are used depends on the route constellation and the arrangement of the metering points. For each type of route element there are free reporting equations which state which neighboring metering points are to be included in the free message of the relevant route element (DE 42 33 546 A).

In addition to sporadically occurring incorrect counts, permanent hardware failures can also occur at the individual metering points, for example due to a sensor unit shearing off the rail or due to line interruptions. Such defects are noticeable in the signal box like incorrect counts through occupancy reports of the track sections adjacent to the disturbed point of delivery.

With metering points that are integrated in axle metering circles, which can be occupied by several possible routes at the same time, such as transfer points, there is the problem that in the event of a hardware failure of such a metering point, all track sections must be temporarily occupied in order to be covered by the counting results of neighboring metering points the free reporting of the disturbed point of delivery is integrated. The reason for this is that when a vehicle advances past the defective metering point, it cannot trigger a busy message for the section into which it is entering. The busy message must therefore be triggered at least indirectly when entering a previous section. As a result, although in itself z. B. routes could be placed at the same time via the parallel passageways of a gateway, in fact only such a route can be placed because of the intended coverage of the defective metering point at least temporarily both passages have to be reported occupied. The counter evaluating the counting results has no information about the travel path actually set, so that for the overlap one must always assume a trip over the disturbed counting point.

The object of the present invention is to further develop the method according to the preamble of claim 1 so that even with branching tracks, no operational disabilities arise from the fact that when a defective metering point is used for the purpose of covering the metering point, sections of the track which are occupied by different routes are temporarily occupied can be. It is also an object of the invention to provide a device for performing such a method.

The invention solves this problem by applying the characterizing features of claim 1 and claim 3. Advantageous refinements of the method according to the invention and the device for carrying out the method are specified in the subclaims.

Figur 1

bezieht sich dabei auf die Installation eines Korrekturabschnittes wie er sich nach dem Stand der Technik ergeben würde und

Figur 2

auf die Installation von Korrekturabschnitten bei Anwendung der vorliegenden Erfindung. Für einander entsprechende Elemente sind in den Figuren der Zeichnung einander entsprechende Bezugszeichen verwendet worden.

The invention is explained below with reference to the drawing.

Figure 1

relates to the installation of a correction section as it would result from the prior art and

Figure 2

on the installation of correction sections using the present invention. Corresponding elements are in the figures of the drawing corresponding reference numerals have been used.

The drawing shows a transition point with two through rails 1 and 2, which are connected via the branching legs of switches W1 and W2. Metering points ZP11, ZP12, ZP21 and ZP22 limit the transition point to the neighboring tracks. Each metering point consists in a known manner of two sensors arranged offset in the longitudinal direction of the track, which respond to railway wheels passing by or other detectable devices present on the vehicle and derive direction-dependent counting pulses from two wheel pulses which overlap in time. The number of axles determined by the individual metering points are fed to a counter, not shown, which evaluates the counting results of a specific number of metering points. The counter has no knowledge of the set route; it is only informed about the arrangement of the metering points along the managed tracks. The counter can e.g. B. be part of a computer that manages a variety of neighboring points of delivery.

In the following it is assumed that a counter evaluating the counting results of the metering points shown in FIG. 1 should know that the metering point ZP3 is defective. This metering point forms together with the metering points ZP11 and ZP12 an upper axle counting section AO and together with the metering points ZP21 and ZP22 a lower axle counting section AU; these axle counting sections are illustrated in the drawing by ellipses. The counting points of both axle counting sections form a correction section, likewise indicated by an ellipse KA, which is used to report this after each complete passage through the correction section and thus to mask the effect of the defective metering point ZP3. If, for example, a route leading from left to right over track 2 is set from the signal box, the metering point ZP21 (incoming) causes a corresponding message to the meter when it is driven, which then reports the track section assigned to the lower axle counting section AU. Since the counter does not know whether the train causing the busy signal travels the transition point area on the continuous track towards the point of delivery ZP22 or whether the train advances via the point of delivery ZP3 in the direction of the point of delivery ZP12, the counter must also be used in addition to that Track section also occupy the track section assigned to the upper axle counting section AO. This can happen at the same time as occupying the lower section of the track, but also with a time delay. Due to the occupancy of the upper section of the track as a result of the occupancy of the lower section of the track, no routes can be set via the pass-through track 1 for the duration of the occupancy, although this would otherwise be possible on the signal box side. This means that a train approaching the metering point ZP11 or ZP12 on track 1 must be stopped before reaching this metering point until the train advancing through the passage track 2 has completely passed the correction section KA and the entered occupancy messages have been deleted .

The invention avoids the operational disability explained in more detail above by the fact that the metering points in the axle counting circles of track sections that can be used simultaneously by different routes are included, assigns correction sections, the counting points of which can only be used by one single route at the same time. This is achieved in that, according to FIG. 2, an additional metering point ZP3 * is installed in the vicinity of the metering point ZP3, which previously could be claimed by several simultaneously possible routes, which together with the original metering point forms an additional axle counting section AH. This additional metering point, together with the metering points ZP21 and ZP22 of the original axle counting section AU1, now forms a correction section KA1, which no longer includes the metering points ZP11 and ZP12 of the through track 1. If a vehicle now passes the metering point ZP21 and the metering point ZP21 has sent a corresponding message to the associated register, then the meter causes the occupancy message of the track section assigned to the axle counting section AU1, which is limited by the metering points ZP21, ZP22 and the metering point ZP3 recognized as defective becomes. The occupancy message of the track section comprising the passage track 1 is omitted, because in the event that the vehicle triggering the occupancy message should actually advance towards the passage track 1 via the defective metering point ZP3, this vehicle would now be detected by the sensors of the metering point ZP3 * and the latter Metering point so that the busy signal of the track section assigned to the upper axle counting section AO1 can be brought about. The busy signal of the lower track section triggered when the point of delivery ZP21 is driven is canceled via the correction section KA1 as soon as the train has completely passed the point of delivery ZP22 or ZP3 *. The correction section comprises the two in a known manner axle counting sections adjoining the disturbed counting point ZP3, namely the axle counting section AH on the one hand and the axle counting section AU1 on the other. If the metering point ZP3 and the additional metering point ZP3 * are arranged with the least possible offset in the longitudinal direction of the rails on the same or different rails on the same track, the axle counting circle AH formed by these two metering points results in a fictitious track section that is only available for the meter. for which there is no equivalent in the signal box.

Similar to the lower axle counting section AU1 now only includes the metering points ZP21 and ZP22 of the connecting track 2 and the metering point ZP3 assumed to be defective, the upper axle counting section A01 comprises the two metering points ZP11 and ZP12 of the connecting track 1 and the additional metering point ZP3 *. Here too, the correction section KA2 corresponding to the correction section KA1 comprises, in addition to the metering point ZP3, the metering points to the left and right of the metering point ZP3 *, namely the metering points of the axle counting sections A01 and AH. With continuous journeys over track 1 there is no influence on the lower track 2; when traveling from track 1 via the point of delivery ZP3 *, which is assumed to be faulty, the occupancy of the track section assigned to the lower axle counting section AU1 occurs when passing the point of delivery ZP3.

Claims (5)

Method for handling hardware failures in track vacancy detection by means of axle counting by covering the counting result of a point of delivery identified as defective by the counting results of metering points on both sides of the defective metering point, these metering points forming a correction section associated with the defective metering point and having a plurality of counting points and counting points.
characterized,
that for each metering point (ZP3) that can be used by several simultaneously possible routes, a second axle counting result is determined in addition to a first axle counting result, and that this second axle counting result with the axle counting results of the other metering points (ZP21, ZP22) is used to report the vacant and occupied track section. this track section is compared. Method according to claim 1,
characterized,
that the coverage of a defective metering point (ZP3) by the counting results of neighboring metering points (ZP3 *, ZP21, ZP22) is only permitted for a specifiable period of time. Device for performing the method according to claim 1 or 2,
characterized,
that an additional point of delivery (ZP3 *) is provided in the vicinity of each point of delivery (ZP3 *) which can be claimed by several routes which can be used simultaneously, which together with the other metering point (ZP3) forms an axle counting circle (AH) and that the correction section (KA1) assigned to the metering point (ZP3) includes the additional metering point (ZP3 *) and the other metering points (ZP21, ZP22) of the track section being traveled on. Device according to claim 3,
characterized,
that the metering point (ZP3) and the additional metering point (ZP3 *) are arranged with the least possible offset in the longitudinal direction of the rails on the same or on different rails on the same track. Device according to claim 4,
characterized by
that the point of delivery (ZP3) and the additional point of delivery (ZP4) form a fictitious track section.

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