EP0705753A2 - Method for predeterminating running speed at light signals - Google Patents

Abstract

In the signalling system, the signal provided at the beginning of a track section is dependent upon the signal provided at the end of the track section, allowing for the travel velocity restrictions within the track section and the braking characteristics of the train. The track section is divided into successive track elements (A1,A2.1,A2.,A3) of defined length and gradient, with the signal at the beginning of the track section also dependent on the sum of the track element lengths between the signals and the track section gradients.

Description

The invention relates to a method according to the preamble of claim 1. Such a method is known from DE 40 32 722 A1.

The signal term to be activated on a light signal is essentially dependent on five different quantities. Above all, this includes the length of the route area to be covered by the signal up to a follow-up signal, the track gradient in this route area, the signal term connected to the follow-up signal, the length of the subsequent slip path, if applicable, and the permissible top speed on the individual sections of the route area. The greater the distance to the following signal (target signal), the lower the inclination of the track there and the higher the permissible driving speed there, the higher the permissible driving speed on the signal in the direction of travel (start signal). This driving speed is possibly still limited by the length of the slip path adjacent to the target signal and by the permissible top speed. In the aforementioned DE-A1, these parameters are taken into account when determining the signal term to be switched on a light signal by using one of several tables for the individual light signals in the context of the choice of signal term for route formation and possibly route monitoring, in which the at the respective start signals, the signal terms to be switched on as a function of the signal terms that can be switched on the target signals are stored. The associated start and finish speeds take into account the parameters listed above with regard to distance, track gradient, maximum line speed and possibly Slip path length. The method known from DE-40 32 722 A1 for specifying driving speeds on light signals can also be used where the distance between the successive light signals is smaller than the usually taken into account control distance of these signals; For such shortened signal intervals, appropriate tables with associated start and finish speeds must be kept and queried if necessary.

The known method with tabular specification of travel speeds on light signals with its rigid assignments of start and finish speeds is not readily applicable to changes in the track system or during construction work that temporarily lead to a reduction in the permissible maximum line speed on individual sections, unless it is Corresponding tables existed from the start, which would take the individual construction conditions on the system into account. The known method also does not take into account the case of bypasses, which may require different driving speeds than the normally set standard routes.

The object of the invention is to provide a method according to the preamble of claim 1, which does not require a large number of assignment tables and which reacts flexibly to changes in the parameters to be included in the determination of travel speeds, and thus also fully covers the case of temporary track construction work and bypasses .

The invention solves this problem by the characterizing features of claim 1. By calling up the sections between the start signal and the destination signal and calling up the quantities stored for these sections and relevant for the selection of signal terms, the signal terms to be activated in each case can be dependent on the route determine; Any changes to the system or changes to the parameters required for the selection of signal terms and stored for the individual route elements are thus automatically recorded and taken into account.

Advantageous developments and further developments of the method according to the invention are specified in the subclaims.

Thus, according to the teaching of claim 2, the length information stored for the individual sections can be taken into account in rounded form. As a result, the storage effort and transmission effort to be kept for the individual sections is reduced without any rounding off of the length information resulting in any signs of danger.

Claim 3 provides that, with different slope information for the individual sections, the strongest slope inclination is used as the total slope for all sections. This measure serves to make the calculation of the permissible driving speeds as simple as possible by assuming a constant inclination for the route to be taken into account. This slope is the slope that causes the greatest driving restriction. Since the actual inclination of the route is at least partially lower than assumed when determining the travel term to be activated on the start signal, it is ensured that a train actually comes to a stop before a destination signal or can be braked to the permissible advance speed there.

Claim 4 regulates the case that the route following the start signal has only gradients; Here, for the specification of the driving speeds on the start signal, it is pretended that the gradient of the entire route corresponds to the gradient of the section with the smallest gradient.

Even so, there is a reserve for the advancing train when braking to the target signal.

According to the teaching of claim 5, the length and possibly slope information for branching elements should be stored in relation to the strand and evaluated according to the respective route of the route. This training takes into account the case that different maximum speeds are permitted via the continuous and branching rod of a switch, which in individual cases, depending on whether a route leads over one or the other branch, may lead to different signal terms for the light signal.

The length and possibly slope information to be stored for the sections can also be stored together for several sections according to the teaching of claim 6. This is of interest in particular for jointly isolated guideway elements, which are also dealt with jointly in the choice of signal terms.

If, according to claim 7, the actual section lengths and gradient statements of the route are taken into account when determining the travel speeds to be specified, then optimized speed specifications for the start signal are obtained; However, it must be accepted that the corresponding section-related variables are actually all included in the choice of signal terms, which requires increased transmission and computing effort.

To simplify the calculation process, the lengths of the individual sections can also be weighted on the basis of the respectively associated inclination information. In terms of mathematics, larger incline slopes shorten the length of a track section more than lower incline values. The respective shortening is taken into account the influence of the respective gradient on the braking distance of the vehicles.

According to the teaching of claim 9, the length and, if applicable, gradient specifications can be determined as soon as the scale map of the track system is recorded and stored for the sections. Any changes to the respective parameters can be taken into account at any time by changing the stored information without the corresponding information in adjacent sections being affected.

If, according to claim 10, the parameters required for the specification of travel speeds are queried in each case counter to the direction of travel of the trains, then the quantities required for speed determination are available in a manner known per se where the relevant signal term is to be switched on, namely at the start signal .

If there is the possibility that the trains traveling on the route transmit information about their braking capacity to the signal box in a fail-safe manner, then according to the teaching of claim 11, the braking properties of the trains can be taken into account when determining the travel speed to be specified. This means that different signal terms may be switched on for vehicles with different braking properties. Trains with better braking properties can pass the line faster and thus contribute to increasing the line performance.

When determining very small distances between successive light signals, the inadmissibility of the formation of train routes is recognized according to the teaching of claim 12.

In the event that station areas are available without shortened signal distances, claim 13 teaches the setting of memories in the associated route elements. These memories make the choice of signal terms independent of the length addition and, if necessary, the inclination consideration. The control interval of the light signals and a control gradient inclination must then be included in the signal definition.

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

The drawing shows a section of a section between two directly successive main light signals, the start signal SS and the target signal ZS. No real length track areas are assigned to these two signals in the outdoor area. Between the two light signals are the track sections A1 and A3 and a switch W with the track-related track sections A2.1 and A2.2; all these sections are represented in the outdoor area by real length track areas. The length of these track sections is plotted below the line representation, for example. The length of section A1 is 200 m, that of section A2.1 on the continuous strand of the switch is 125 m and that of section A3 is 300 m; the track section A2.2 leading over the branching branch of the switch W has a length of 140 m. Below the length information, the slope is plotted in the drawing, which the individual track sections have; this is the steepest slope or the flattest slope within the individual track sections. Furthermore, the maximum line speeds permitted for the individual track sections, namely 160 km / h, 120 or 80 km / h and 160 km / h, are plotted. All this data is stored for the individual sections and can be called up as required. This data is expedient when it is recorded the scale map of the track system is determined and saved for the individual sections.

It is assumed that the target signal ZS follows the start signal SS at a shortened signal distance below the normally available control distance. The arrangement in a shortened signal distance requires a separate determination of the signal term to be specified on the start signal SS with other than the usually taken into account distance information so that a train traveling on the route can be braked reliably to the respectively predetermined target speed on the way from the start signal to the target signal. According to the teaching of the invention it is provided that u. a. the length information stored for the individual track sections between the start and the destination signal is called up and added according to the track plan. This is expediently carried out from the target signal against the direction of travel, so that the distance value relevant for determining the signal term to be activated on the start signal is present in the element group of the start signal; in the present example, this distance is 625 m compared to an assumed standard distance of z. B. 1,000 m.

In addition to the length of the individual track sections between the start and destination signals, their respective gradients are also included in the determination of the signal term to be activated on the start signal; every track inclination has the effect of shortening the associated track section, each slope has the effect of an extension of this section. There are several ways to consider the influence of the track gradient when choosing the signal term. For the exemplary embodiment shown, it is assumed that the entire distance between the start and the destination signal has a uniform gradient, namely that of the most inclined track section. As can be seen from the assumed section gradients, this is the track inclination of section A3. With the track schedule Calling up the slope information stored for the individual track sections between the start and target signal, the slope value saved for section A3 prevails by overwriting the slope information stored for the other sections.

The signal term to be activated in each case on the start signal is dependent not only on the distance between the target signal and the gradient, but also on the signal term that is respectively activated on the target signal; if the train is to stop at the destination signal, a much lower concept of speed must be activated at the start signal than if the destination signal also shows a travel term.

As a further parameter relevant for the choice of signal terms, the slip path following the target signal must also be taken into account when setting train routes. Only if the danger point follows the target signal at a minimum distance, which is determined by the braking power of vehicles with positive brakes and a maximum driving speed assumed when the target signal slips, does the slipping path have no influence on the determination of the driving concept to be activated on the start signal. However, if it is a shortened slip path with a danger point closer to the target signal, this shortened slip path can certainly lead to a reduction in the term of travel to be activated on the start signal.

The target speed VZ stored for the target signal and the length LD stored for the adjacent slip path are advanced via the route elements called up according to the track plan and transmitted to the route element of the start signal. From the parameters available there, a computing arrangement determines a speed VR for the signal image to be switched on at the start signal in a manner not to be explained here. This speed is higher than the permissible maximum speeds VH stored for the individual track sections, the speed VS is to be graded to the permissible maximum speed in the adjacent route area. In the present case, the lowest permissible maximum line speed VH on the way to the target signal is the travel speed of 120 km / h stored for the continuous line of the switch W. If the calculated speed VR is below this permissible maximum line speed VH or if it has been graded to this maximum line speed, it forms the speed VS which is to be switched on at the start signal SS. A train passing the start signal at this speed can be safely braked to the target speed of the target signal even with a shortened signal distance.

Another less complex way of taking the respective track gradient into account when selecting the signal concept could be to modify the length information stored for the individual sections depending on the inclination, i. H. when calculating the signal term to be switched on for the length of the track section A3 z. B. only to be considered 250 m; on the other hand, the length of section A1 z. B. go into the calculation with 300 m.

Of course, it is also possible to take the actual slope of the individual track sections into account when calculating the signal term to be switched on. However, this requires the transmission of a corresponding number of gradients to the route element of the start signal and it requires a corresponding computing effort.

When taking the individual section lengths into account, it may make sense to round off the length specifications, ie to calculate with possibly slightly shortened section lengths. This would have the advantage that the storage effort for the individual track elements would be reduced and that too less data would have to be transferred. Shortening the length specifications included in the calculation can by no means lead to incorrect signal specifications in the sense of safety, because these length reductions lead to signal terms that are too low, but never lead to signal terms that are too high.

The length and slope information does not necessarily have to be stored separately for each route element, but can also be stored together for several route elements. This is particularly advantageous in the case of jointly insulated guideway elements that are treated by the signal box as a single guideway element.

When determining the length between successive light signals, the signal box also recognizes the case that there are such short distances between the signals that the formation of a train route is not permitted and short-long journeys are to be used instead.

If the vehicles traveling on the route are able to transmit information about their actual braking capacity to the signal box in a signal-safe manner, then the actual braking capacity of a vehicle can also be taken into account there instead of the braking capacity that is otherwise taken into account when selecting the signal concept.

The method according to the invention does not necessarily have to be used where the light signals follow one another at a distance that is at least equal to the defined control distance; There the control interval can be assumed everywhere for the choice of signal terms. For the route elements of such route areas, which are presented in the outdoor area by track areas of real length, memories are then to be set in the route elements in an advantageous manner, the query of which within the framework of the choice of signal terms and, if appropriate the monitoring makes the connection of a signal term independent of the consideration of these variables. This measure shortens the time for determining the signal term to be switched on and relieves the computers provided for the control from unnecessary work. On the other hand, it is also the case that the method according to the invention can also be used advantageously for routes in which the signals follow one another at intervals which are greater than the predetermined control interval, with higher entry speeds then possibly also at greater intervals can be approved. So far, it has usually been the case that on such sections of the route the vehicles are braked to the target speed specified on the target signal and cover the rest of the route to the target signal at a constant speed, the so-called intermediate speed. The application of the method to such sections of the route leads to a greater utilization of the computers used, but also contributes significantly to the increase in the route performance because the route can now be traveled at a higher speed than when taking into account constant control intervals between the signals. In any case, however, it is advantageous to use the method according to the invention where light signals follow one another at a shortened distance.

If main speed indicators are arranged in a route and these are at a shorter distance from the target signal ahead, the main indicators or the groups of elements provided for this purpose should also determine the speed to be displayed, taking into account the determined distance from the target signal ahead in the direction of travel.

Claims (13)

Method for specifying driving speeds on a light signal (start signal) as a function of a signal term that applies to a following light signal (target signal), in particular in the case of a shorter distance between the two signals compared to a standard distance, taking into account speed restrictions due to route elements in the route and below Taking into account the braking properties of the train or trains traveling on the route,
characterized,
that for all track elements that are represented in the outdoor area by track areas (A1, A2.1, A2.2, A3) of real length, corresponding length information and, if applicable, gradient information are stored,
that the length information for all between start and finish signal (SS, SZ) sections are added according to the respective track and
that the signal term to be switched on at the start signal is additionally made dependent on the added length information of the track sections between the start and destination signal and, if applicable, the slope information and maximum line speeds stored for these sections and called up according to the track plan. Method according to claim 1,
characterized,
that when adding up the length specifications, they are rounded off (shortened). The method of claim 1 or 2,
characterized,
that with different gradients (+ 3%, ± 0% - 1%) for the individual sections the strongest gradient (-1%) is used as the total gradient for all sections. The method of claim 1 or 2,
characterized,
that in the event that only slopes are stored for the individual sections, the weakest slope is used as the total slope for all sections. Method according to one of claims 1 to 4,
characterized,
that the length and, if necessary, the slope information for branching elements (W) are stored in relation to the strand and are evaluated in relation to the respective route course. Method according to one of claims 1 to 5,
characterized,
that common length and, if necessary, gradient information are stored for jointly insulated guideway elements. Method according to one of claims 1 to 6,
characterized,
that with different slope information for the individual sections, the actual section lengths and slope statements are used to determine the start signal term. Method according to one of claims 1 to 6,
characterized,
that the length information is weighted in the individual guideway elements on the basis of the respectively associated inclination information. Method according to one of claims 1 to 8,
characterized,
that the length and, if necessary, slope information for the individual sections when recording the scale Site plan of the track system is determined and stored for these sections. Method according to one of claims 1 to 9,
characterized,
that the addition of the length information and the query of the other parameters required for determining a signal term takes place in each case against the direction of travel and ends at the respective start signal. Method according to one of claims 1 to 10,
characterized,
that the signal term to be activated on a light signal is made dependent on the actual braking properties of a train traveling on the route and that the respective train transmits information about its braking capacity via a fail-safe information transmission in good time before a start signal is reached to the signal box determining the signal term. Method according to one of claims 1 to 11,
characterized,
that the detection of signal distances below a given minimum distance prevents the formation of train routes. Method according to one of claims 1 to 11,
characterized,
that for station areas without shortened signal spacing, memories are set in the guideway elements, the query of which, as part of the selection of signal terms and possibly monitoring, makes the connection of a signal term independent of the length addition and possibly inclination consideration of the sections following this signal.

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