EP2547568A1 - Method and device for train length detection - Google Patents

Abstract

The invention relates to a method and a device for train length detection in a train set which is composed of a plurality of carriages (1a - 1c) and which, by means of a pneumatic braking system, is braked in a plurality of braking stages according to the pressure in a main air line (HL) coupled from carriage (1a) to carriage (1c), the pressure (p_HL) and throughflow (formula (I)) of said main air line and the ambient temperature (T) being detected along the time axis by sensors, and from these the train length (L) being calculated by means of an electronic evaluation unit (4), wherein the measurement variables are detected by sensors, proceeding from the steady state of a present braking stage (I.), during the execution of the next braking stage (II.) until a steady state is again reached. The volume (V) of the main air line (HL) is calculated by additive integration of the throughflow (formula (I)) during the ventilation of the main air line (HL) for the execution of the next braking state (II.), taking into consideration the pressure (p_HL) prevailing in the initial state and the end state and the ambient temperature (T), in order to determine the train length (L) corresponding to the main air line length at a known line cross section (Q) using said volume.

Description

 Method and apparatus for train length detection

The present invention relates to a method and a device for

Train length detection in a train consisting of many cars, which is braked via a pneumatic brake system in accordance with the pressure in a coupled from car to car main air line HL in several braking stages whose pressure p _H L and flow V and the ambient temperature T sensor detected along the time axis from which the train length L is finally calculated by means of an electronic evaluation unit. Furthermore, the invention also relates to a method implementing device and a train in which such a device is installed.

The main air line HL in train assemblies is used primarily for triggering the pneumatically operated brake, which come in the sense of a signal transmission by reducing the pressure in the braking position and are released when pressure increases. The

Main air line HL, which runs along all the wagons of a train, can also be used to obtain information about train-specific characteristics. It is thus possible to monitor the main air line HL with regard to train separation. Here, a check of the nachgespeisten volume flow and the pressure conditions during driving with brakes released, during braking and during the release is performed. Basis for the recognition of train separations or for the length recognition of the

LK: Main air line HL and thus of the entire train are characteristic

Characteristics of the brake system, such as the maximum make-up of the

Main air line HL due to the maximum leakage of the system and the typical length-dependent breakdown time, in which a change in the pressure ratios can be detected.

These and other characteristic features of a pneumatic brake system are preferably based on standardized specifications of the main air line HL to allow a general applicability. Derived from these properties

Threshold values and gradients for the flow values and pressure values are defined, which allow conclusions to be drawn about the train length or the continuity of the main air line HL via signal engineering processing. For example, if it is found that the continuity of the main air line HL is not given, it can be inferred as a disturbing cause of this on a closed shut-off valve within the main air line HL between two cars.

From DE 199 02 777 AI is a technical solution for monitoring the

Zugvollständigkeit out, which by means of a compressed air sensor and a

Flow meter to determine the volume flow in the main air line HL gives a message about the condition of the train. The main air line of the train usually passes through all connected cars and can be monitored by sensors, for example, the relay valve on the traction unit, with the direction and amount of the volume flow of compressed air are measured by sensors known per se. Overall, there is a balance between inflow and outflow of air in the stationary state of the brake system. The incoming compressed air replaces only the leakage of air leakage from the brake system, which emerges over the entire length of the main air line HL. If it is braked, the air pressure in the main air line HL defined in most braking stages is lowered. For monitoring train completion, the measured values of the sensors monitoring the main air line HL are supplied to an electronic evaluation unit, which compares the detected measured values with predetermined values of the respective operating variables for a corresponding operating state of the train. Depending on the result of the comparison, it is concluded that the train is complete. In this case, the evaluation and acquisition of the measured values to determine the train completion information takes place only at a single point of the train, preferably in the train

Traction of the train, so that other means for detecting operating variables of the main air line HL at other points of the train - especially at the train - are not required.

However, this monitoring of train completeness has the disadvantage that at the same time it can not be determined precisely which train length is present at the same time. The knowledge of the train length is useful, for example, for the detection of so-called black cars. The order of the cars and the properties are usually known from a car list. Derived from the car list, the essential information for the driver, such as braking characteristics, compiled on a so-called brake note. Furthermore, the train length when driving on frequently traveled routes is important to comply with safety distances, for example.

DE 199 33 798 A1 proposes a method for train length detection in which the length of the train is measured directly and transmitted to the traction vehicle. For this purpose, volume and pressure signals in the main air line HL are determined by sensor technology, wherein in particular a timely transmission of information about the last car of the train follows the power tool. Subsequently, an evaluation device checks whether the volume and pressure signals and physical variables derived therefrom are known to a known setpoint range stored in the evaluation unit for the train length correspond. Depending on this, a signal is output which provides the information as to whether the measured values lie within the stored setpoint ranges. It is also proposed to determine the stored in the evaluation unit of the traction unit length of the train to be measured train of a Zuglängenmesser and to the

To transmit locomotive. The train length can also be measured by an axle counter when starting or when leaving a station and transmitted to the locomotive. Thus, a stationary measuring device is activated here on the track for Zuglängenmessung.

All of these measures appear quite complex, since sensors placed outside the locomotive, namely in the last car or even outside the train, are used to obtain measured values for train length detection.

DE 100 09 324 AI, however, shows a method for engine-based determination of the train length of a train, in which only the physical state variables pressure, flow and temperature of the air in the main air line HL are measured in the field of the traction unit, from a defined sequence of the

Driver brake valve in the towing vehicle or other suitable actuators pressure changes in the main air line HL are generated, the associated flows temporally integrated and constant pressure - ie their steady state - determines the leakage rate and from these variables, the volume of the main air line HL is calculated, which arises to conclude the train length.

Although this calculation method takes into account the system-inherent leakage of the brake system, but other disturbances, such as local vents in the range of the individual brake cylinders of the car associated control valves remain during their

Acceleration ignored. Because the control valves provide the braking acceleration in the first braking stage for a temporary additional ventilation of the main air line HL. However, this measure leads to inaccurate measurement results in determining the train length.

It is therefore an object of the present invention to provide a method and a device for train length detection, in which a precise length determination is possible only with zugverbinterner sensors.

The object is achieved on the basis of a method according to the preamble of claim 1 in conjunction with its characterizing features. The following dependent claims give advantageous developments of the invention.

With regard to a device corresponding to the method, reference is made to claim 9. In claim 11, a train that contains this device is specified.

The invention includes the solution that the sensor-technical measured variable detection is carried out only from the stationary state of an existing brake stage I during the execution of the next brake stage II, until a stationary state within this braking stage II is reached again. By subsequently integrating the

Flow rate during the venting of the main air line HL to perform the next stage brake II., Taking into account the prevailing pressure in the initial and final state and the ambient temperature, the volume of the main air line HL is calculated. From the volume calculated in this way, it is finally possible, in a manner known per se, to conclude the length of the main air line HL and thus the length of the train L given a known line cross-section.

The volume can be determined concretely via the following formulaic relationship:

From L = - finally results in the line length and thus the train length L of

 Train set. The cross section of the main air line HL and the couplings is in

Generally known.

With the method described, the line length can thus be checked for each brake request which does not take place from the released state. This can be the

Continuity of the main air line HL checked and a closed shut-off valve can be detected. If the cable length determination is integrated into the brake sample before the start of the journey, the system can issue a warning about a different train length in the

Compared to the information given in the brake note. For example, if after the brake test other cars with a closed stopcock attached to the train, this error is detected when connecting the traction unit at the other end to change direction.

To detect the correct volume flow, the leakage must be considered in the above procedure. When decelerating from an existing braking stage, the main air line HL is vented completely, except for the leakage, via the driver's brake system, and thus detected by the flow measurement. The leakage rate must be added in addition to the volume flow. The following relationship applies:

[II] V _NGESAMT - VN _Mcss + v _NLeclage The leakage rate is dependent on the pressure level in the main air line HL. For the calculation, the leakage is regarded as a nozzle in the main air line HL with a constant nozzle cross-section, which vents against the atmosphere.

_ V * p, * T _N

From the volumetric flow V = A * (2 * R * T) * Y and the relation V _} , the flow coefficient Y yields the following expression:

with T _N = 293, 15K and P _N = 1.013 barA, where:

Y> 0.528 with k = l, 402, otherwise Y = 0.484.

pi corresponds to the absolute pressure before, p ₂ the absolute pressure after the nozzle and T the

 J

 Temperature. R = 287 is the general gas constant.

 kg * K

 After determining the leakage rate at a constant pressure level, the constant nozzle cross-section A can thus be determined by the formal relationship [III] as a function of

Temperature can be determined. VN _Lectage can thus be calculated approximately from the measured pressure _curve in the main air line HL.

The advantage of the solution according to the invention results, in particular, from the measure that the air flowing in the main air line HL is ignored during the initial filling of the brake system. Because when first filling the air flows not only in the Main air line HL, but also in the working chambers of the control valves and in various reservoirs of the car. In this case, the volume of the storage container of the individual carriages can vary, so that in practice a calculation-related correction of this disturbance variable is not possible. In addition, most of the initial state of the working chamber of the control valves and the reservoir is not known. The solution according to the invention completely excludes the measurement errors resulting therefrom. To solve this problem, the solution according to the invention provides, in principle, the flow rate of the air only in the filled state, for example, after first filling while driving or in any stationary state of the main air line HL, in which the pressure P _{HL is} constant, is detected. By excluding the acceleration effect, the solution according to the invention avoids an unknown flow size, which leads to a more accurate measurement result.

According to a measure improving the invention, it is proposed that

Determining the train length during the ventilation of the main air line HL the sensor-related measured value acquisition is only carried out until the pressure of the supply air tank connected to the main air line is reached. During such a

Einleitungsbetriebs is in conventional brake interpretations so also the evaluation of the filling process of the main air line to the onset of Vorratsbehälternachspeisung according to the method of the invention possible. The flow will be up to one

Pressure value evaluated below the reservoir pressure. In this process, the unknown reservoir size is advantageously excluded.

According to a measure which further improves the invention with regard to a precise measuring result, it is proposed that the cross-section of the line cross-section which is used with the determined volume of the main air line HL for calculating the train length be both the cross section of the main air line HL passing through the individual carriages and the cross section the interposed line couplings is taken into account. The Tensile length L results - as stated above - from dividing the determined volume of the main air line HL through the line cross-section Q.

For computational compensation of the leakage as a further disturbance variable within the brake system, it is proposed that the volume flow induced thereby in the stationary state is additionally measured within the main air line HL, so that this measured variable can be used as a correction value in determining the train length for the computational elimination of the disturbance. The necessary for the calculation

The flow coefficient Y can be set in a simplified manner in the range 0.45 to 0.5, if the pressure ratio p2 to pl is greater than the value 0.528 +/- 10%. Also at one

Ratio greater than this value, the error remains relatively low, since with decreasing pressure in the main air line HL and the leakage decreases. If the leakage of the pneumatic brake system is calculated or fixed, a better quality result can be obtained by including it in the calculation of the train length.

According to another measure improving the invention, it is proposed that at least once the volume of the main air line HL be determined at least once

Correction value, the air volume, which is lost by brake acceleration losses of the individual control valves associated with the brake cylinder from the dissolved state of the brake system, to eliminate computationally when determining the train length. The inventive method is based on the fact that the acceleration effect of

Control valves of the brake system for determining the length of the main air line HL

be excluded. However, if the line volume is determined once only, for example in the course of a brake test before the departure of the train, the resulting error in now known volume can be determined. The background to this is that during the train ride when braking the train length also at

Brake requirements can be checked from the released state to detect the demolition of a tensile part or a closed stopcock. Preferably, the should Implementation of this measure, at least a pressure of about 0, lbar be vented through a nozzle until the acceleration effect responds in the individual control valves. The acceleration effect takes about a pressure of 0,3bar locally from the

Main air line HL. Then the effect is complete and the control valves are absolutely sensitive. By this connection, an approximate calculation of the amount of air lost as a result of the ideal glass equation is now possible. The following applies:

Pvorher * V before Pdanach * Vdanach

According to another measure further developing the invention, the volume determination of the main air line HL can also take place in the so-called two-line mode. At the

Two-line operation are reservoir, which can vary in size, and other compressed air consumers via a separate compressed air line, the main reservoir line HB filled. The main tank line HB runs along the train in parallel to the main air line HL. Thus, the inventive method in the

Two-pipe operation are also applied in the aeration case after Erstauffüllen because no unknown volume sizes exist. In other words, the determination of the volume of the main air line HL thus takes place during release of the brakes as a result of ventilation of the main air line HL.

The filling of the main air line HL can be between any two stationary

States are evaluated on the inventive method for determining the train length. Since no acceleration effect occurs during the ventilation process, only the leakage must be taken into account as a disruptive factor. In contrast to the volume determination via the vent, in two-line operation, the leakage must be subtracted from the measured volume flow as a function of the pressure. So you get:

V Total V Nmess "V Nleckage Determining the volume via the dissolving and filling process in two-pipe operation is only possible without error if the air from the main air line HL is only routed via the

Driver's brake system and not taken by other devices.

Further, measures improving the invention will be described in more detail below together with the description of a preferred embodiment of the invention with reference to FIGS. It shows:

Figure 1 is a schematic representation of one consisting of several cars

 Train association with a device for train length detection via the

 Main air line, and

FIG. 2 shows a flowchart for illustrating the individual method steps for

 Train length detection.

According to Figure 1, a train consists of many juxtaposed car la to lc. A pneumatic brake system brakes the train in accordance with the pressure in one of carriage la to wagon lb and finally wagon lc coupled main air line HL in one or more braking stages to a standstill. Here, sensors 2a to 2c monitor the

Pressure p _H L, the flow V and the ambient temperature T within the

Main air line HL along the time axis. These sensors 2a to 2c are arranged in a carriage la to lc preceded traction unit 3. Also in the traction vehicle 3, an electronic evaluation unit 4 collecting the measured sensor signals is placed, which finally calculates the train length. As part of the sensor technology in this embodiment, two separate sensors

2b and 2b 'for determining the flow ^ provided. While the first sensor 2b is used during the changeover between the stationary states, ie during the transition from one braking stage to the next higher braking stage, the second sensor 2b 'is used only in the steady state for the purpose of leakage measurement. Because the change between stationary

States generates a much higher flow ^, the first sensor 2b is larger sized than the second sensor 2b ', which in contrast only very small flows

^ has to determine. As a result of the different measuring ranges used thereby, the accuracy of the determination of the flow rates increases overall. However, a distinction must be made between single-line operation and two-pipe operation. in the

In dual-line operation, a sensor that measures both leakage and ventilation processes or two sensors with the same cross-section in series may be sufficient in the case of ventilation. The leakage sensor requires a smaller measuring range and can therefore achieve greater accuracy.

In the case of single-line operation with leakage measurement, two sensors are absolutely necessary or one device that allows bidirectional measuring since the flow during braking is opposite to the flow during the leakage measurement. Again, that the cross section of the main air line HL may not be narrowed and the leakage sensor requires a smaller measuring range and thus a higher accuracy can be achieved.

The electronic evaluation unit 4 takes into account both the cross section of the running through the individual carriages la to lc main air line HL and the cross section of the interposed line couplings 5 in determining the train length with respect to the line cross section to achieve more accurate calculation results.

In each individual car la to lc is at least one control valve 6 with this

connected pneumatic brake cylinder 7 arranged to actuate the brakes. For the purpose of braking acceleration also escapes air volume from the control valves 6, which can be detected as a correction value in order to consider this computationally when determining the train length.

According to Figure 2, the Zuglängenerkennung preferably takes place by starting from a stationary state of the brake system, which is formed by the applied brake I. First, a sensor-technical measured variable detection of the physical values pressure p _HL , flow V of the main air line HL and the ambient temperature T takes place, namely during the execution of the next brake stage II. Until a stationary state is set again.

Subsequently, an integration of the flow V thus determined takes place under

Considering the initial and final states of the prevailing pressure P _HL and the ambient temperature T according to equation (I) above. The result of calculation is the volume V of the main air line HL. This is due to the above-mentioned calculation relationship with known line cross-section Q of

Main air line HL whose length calculated, which corresponds to the train length L.

The invention is not limited to the preferred one described above

Embodiment. On the contrary, modifications are conceivable which are included in the scope of protection of the following claims. It is also possible to determine further disturbing influencing variables and to calculate them as correction values

take into account, so that a precise train length detection can be realized. LIST OF REFERENCE NUMBERS

1 car

 2 sensor

 3 locomotive

 4 evaluation unit

 5 line coupling

 6 control valve

 7 brake cylinders

 8 storage air tanks

HL main air line

 HB main tank line

 V volume of the main air line

 Q Conductor cross section of the main air line

 PHL pressure in main air line

 V Flow through the main air line

T ambient temperature

 L train length

Claims

Claims

1. Method for train length detection in one of many carriages (la-lc)

existing train, which via a pneumatic brake system in accordance with the pressure in one of carriage (la) to car (lc) looped main air line (HL) in several

Braking stages is braked, the pressure (P _HL ) and flow (V) and the

Ambient temperature (T) sensor technology along the time axis are detected, from which by means of electronic evaluation unit (4) the train length (L) is calculated,

characterized in that the sensor-technical measured variable detection from the

stationary state of an existing braking stage (I) during the execution of the next braking stage (II.) Is performed until a steady state is reached, after which by integrating the flow (V) during the venting of the main air line (HL) to carry out the next Brake level (II.) Under

Taking into account the pressure prevailing in the initial and final state (P _HL ) and the ambient temperature (T), the volume (V) of the main air line (HL) is calculated in order to determine the train length (L) corresponding to the main air line length with known line cross-section (Q) ,

2. The method according to claim 1,

characterized in that to determine the train length (L) during the ventilation of the main air line (HL), the sensor-technical measured variable detection is only performed until reaching the pressure (P _HL ) of the main air line (HL) Vorratsluftbehälters (8).

3. The method according to claim 1,

characterized in that both the cross section of the main air line (HL) running through the individual carriages (la - lc) and the cross section of the line couplings (5) arranged therebetween are taken into account in the line cross section (Q).

4. The method according to claim 1,

characterized in that in the steady state of the caused by leakage of the pneumatic brake system volume flow (V Nieck) is measured in order to use this measure for computational elimination of the disturbance as a correction value in determining the train length (L).

5. The method according to claim 1,

characterized in that when previously determined at least once the volume (V) of the main air line (HL) as a correction value, the air volume (V), which by Bremsbeschleunigungsverluste the individual the brake cylinders (7)

Control valves (6) from the dissolved state of the brake system is lost, is computationally eliminated in the determination of the train length (L).

6. The method according to claim 1,

characterized in that in a two-line operation in which the

Compressed air consumers are filled via a separate main reservoir line (HB), whereas the main air line (HL) exclusively for braking, the determination of the volume (V) of the main air line (HL) during the release of the brakes due to ventilation of the

Main air line (HL) is performed.

7. The method according to claim 6,

characterized in that representing the leakage of the brake system

Correction value as a function of the pressure (P _HL ) is subtracted from the measured flow (V).

8. Apparatus for train length detection in a train consisting of many carriages (la-lc), the pneumatic brake system of which is subject to the pressure in one of carriages (la) to trolley (lb) looped main air line (HL) in several

Brake stages brake, whereby sensors (2a - 2c) the pressure (PHL) and the flow (V) and the ambient temperature (T) along the time axis capture, resulting in a

electronic evaluation unit (4) calculates the train length (L),

characterized in that the evaluation unit (4) from the stationary state of an existing brake stage (I.) during the execution of the next braking stage (II.) Performs the sensor-technical measured variable detection until a steady state is reached again, by integrating the flow (V ) to calculate the volume (V) of the main air line (HL) during venting of the main air line (HL) to carry out the next brake step (II), taking into account the pressure (PHL) prevailing in the initial and final state and the ambient temperature (T); in order to determine the train length (L) corresponding to the main air line length in the case of a known line cross section (Q).

9. Apparatus according to claim 8,

characterized in that for measuring the flow (V) of the main air line (HL) during the change between the stationary states of the sensor (2b) is used, while for leakage measurement in a stationary state, a comparatively smaller sized second sensor (2b ') for Use comes.

10. Train with many cars (la - lc), each with a pneumatic

Brake system according to a looped main air line (HL) are braked, comprising a device for train length detection according to one of the preceding

Claims 8 and 9.