RU2697162C1 - Device for confirming integrity of rail vehicle coupling and corresponding rail vehicle - Google Patents

Abstract

FIELD: rail vehicles.SUBSTANCE: group of inventions relates to devices for confirming integrity of a track train, as well as to railroad train equipped with such a device. Device comprises communication medium and beacons. One beacon is installed at the beginning of the composition, the second - at the end. Second beacon generates modulated signal and transmits it to communication medium. First beacon receives signal from communication medium, decodes data of coded signal, compares them with reference values and determines integrity of coupling of composition. Communication environment is made with possibility of rupture in case of inter-car coupling disengagement.EFFECT: higher reliability of determination of integrity of inter-car coupling.7 cl, 13 dwg

Description

The present invention relates to a coupling integrity confirmation device for confirming the integrity of a coupling of a train comprising at least one first carriage and one second carriage, the device comprising a communication medium passing between the first carriage and the second carriage, a first airborne beacon mounted in one of the carriages and connected to the communication medium, a second airborne beacon mounted in another of the wagons and connected to the communication medium.

The invention is applied in the field of railway safety, in particular to confirm the integrity of the train.

The expression “confirmation of integrity” for the purposes of this patent application is used to refer to the detection of an unbroken state of a train coupler, in other words, an unbroken state of a mechanical link between two freight cars or two cars of a train, regardless of whether the latter is a “screw” coupler, automatic hitch or any other type of hitch.

It is a well-known practice to use a transmitter to generate a signal at the level of the first train car, located at the tail end of the train, and supply this signal sequentially over time and in the form of a sound wave of the pressure line of the train.

The receiver, located in the second train car, located at the head end of the train, is able to receive the sound wave generated by the transmitter and propagate in the pressure line.

In the event of a coupling break, a sound wave is not able to propagate between the transmitter and receiver along the pressure line. The receiver no longer receives the sound wave generated by the transmitter, thus further detecting a breakage of the coupler within the train.

However, such a device does not give full satisfaction.

In fact, the sound wave emitted by the transmitter weakens during its propagation along the pressure line. Due to the length of the trains, the sound wave power that reaches the receiver is very likely to be at the same level as the random noise present in the pressure line, which is also detected by the detection device. In this regard, it is impossible to declare with a sufficient level of reliability that the signal detected by the detection device is a sound wave that was transmitted by the transmitter in the first carriage. This means that it is not possible to claim with a sufficient level of reliability that the integrity of the linkage of the train is still uncompromising.

In this regard, the objective of the invention is to provide a device that provides the ability to confirm the integrity of the train with a greater degree of reliability.

To this end, an object of the invention relates to a device of the aforementioned type, in which:

a second beacon configured to generate a signal modulated by the predetermined encoding data and to supply a modulated signal to the communication medium;

the communication medium is configured to transmit the specified signal to the first beacon, and the communication medium is further configured to break in the event of a breakage of the coupling between the two cars, preventing the signal from propagating to the first radio beacon;

the first beacon is configured to receive a signal transmitted by the communication medium and to extract encoding data extracted from the received signal;

the device is configured to confirm the integrity of the coupling between the cars of the train, when the encoding data retrieved by the first beacon is identical to the specified encoding data.

Moreover, it is possible to select a code of sufficient size to ensure that the code is detected by a device with a sufficient degree of reliability, in other words, to ensure that the code is distinguished from a code randomly generated by noise with an error rate that is lower than the required threshold value.

According to other preferred aspects of the invention, the detection device comprises one or more of the following characteristic features, taken into account separately or in accordance with any technically possible combination:

the second beacon is able to calculate the image of the preset code by means of the first predetermined function so as to generate a computed key, the computed key generating encoding data, the second beacon is further configured to modulate the specified signal generated by the second beacon using the preset code;

the first beacon is able to extract the extracted code and the extracted key from the signal received by the communication medium, and apply the first predetermined function to the extracted code to generate the calculated key;

and the device is able to confirm the integrity of the coupling between the cars of the train if the key retrieved by the first beacon is identical to the key calculated by the first beacon;

the first beacon is able to apply the second predetermined function to the extracted encoding data to generate image data, generate a response signal that is modulated by the image data, and transmit a response signal sent to the second beacon;

the second beacon is able to apply the second predetermined function to the encoding data to generate the original image data, receive a response signal, extract the extracted image data from the received response signal, compare the extracted image data with the original image data;

and the device is able to confirm the integrity of the coupling between the cars of the train, if the extracted image data is identical to the original image data;

the first beacon includes an electromagnetic wave transmitter, the second beacon includes an electromagnetic wave receiver, the first beacon is capable of transmitting a response signal through the air using an electromagnetic wave transmitter, the second beacon is capable of receiving a response signal through the air using an electromagnetic wave receiver;

the communication medium is a pressure rail of a train, and is characterized in that the second radio beacon is capable of delivering an audio signal to the communication medium;

the communication medium is an electric cable of a train, and is characterized in that the second radio beacon is capable of supplying an electrical signal to the communication medium;

in addition, the device is capable of transmitting in the signal generated by the first beacon to the second beacon using the communication medium an additional information element that is not related to confirming the integrity of the train.

Moreover, the object of the invention relates to the provision of a train including a coupling integrity confirmation device as defined hereinabove to confirm the integrity of the hitch of said train.

The invention will be better understood by using the description that follows, given solely by way of non-limiting example, and with reference to the accompanying drawings, in which:

Figure 1 is a schematic representation of a train including a detection device according to the invention;

Figure 2 is a schematic illustration of a first beacon of the device shown in Figure 1;

Figure 3 is a schematic illustration of a second beacon of the device shown in Figure 1;

Figure 4 is a schematic illustration of a first beacon of a second embodiment of a detection device according to the invention;

Figure 5 is a schematic representation of a second beacon of a second embodiment of a detection device according to the invention;

Figure 6 is a schematic representation of a train including a third embodiment of a detection device according to the invention;

Figure 7 is a schematic illustration of a first beacon of the device shown in Figure 6;

Figure 8 is a schematic illustration of a second beacon of the device shown in Figure 6;

Figure 9 is a block diagram of the operation of the detection device, which functionally perform beacons shown in Figures 7 and 8;

Figure 10 is a schematic representation of a train including a fourth embodiment of a detection device according to the invention;

Figure 11 is a schematic illustration of a first beacon of the device shown in Figure 10;

Figure 12 is a schematic illustration of a second beacon of the device shown in Figure 10;

Figure 13 is a block diagram of the operation of the detection device, which functionally perform beacons shown in Figures 11 and 12.

The train 2, including the coupling integrity confirmation device 4 for confirming the integrity of the coupling according to the invention, is shown in Figure 1.

The train 2 includes a plurality of cars 6, in particular a head car 6A and a tail car 6B or a service car.

Cars 6 are connected in pairs with each other by means of couplers (not shown).

The detection device 4 comprises a communication medium 8, a control beacon 10, and a transmitter beacon 12.

The communication medium 8 passes along the train 2. In particular, the communication medium 8 passes between the head carriage 6A and the tail carriage 6B.

The control beacon 10 is installed in the head carriage 6A, and the transmitter beacon 12 is installed in the tail carriage 6B. Each of the control beacon 10 and the transmitter beacon 12 is connected to the communication medium 8.

The communication medium 8 is capable of breaking if the coupling between the cars 6A, 6B is broken. The communication medium 8, for example, is a brake pressure line of a train 2 for pneumatically controlling the brake system of a train 2. Alternatively, the communication medium 8 is an electric cable of a train 2.

As illustrated in FIG. 2, the control beacon 10 includes an information processing unit 14 connected to the receiver 16.

The processing unit 14 comprises a memory 18 and a processor 20.

A storage 18 stores the reception software 22 and the comparison software 24. The storage 18 memory further includes a first storage area 28 for storing a given code, for example 256-bit code.

The processor 20 is capable of running software applications 22, 24 stored in the storage 18 of the memory.

The receiver 16 is capable of receiving signals that are transmitted over the communication medium 8. In the case of the pressure line forming the communication medium 8, the receiver 16 is capable of receiving sound waves. In the case of an electric cable forming a communication medium 8, the receiver 16 is capable of receiving electrical signals.

The receiving software application 22 is capable of processing the signals received by the receiver 16 in order to extract code from them. The comparison software application 24 is capable of comparing each code retrieved by the reception software application 22 with a predetermined code.

As illustrated in FIG. 3, the transmitter beacon 12 includes an information processing unit 32 connected to the transmitter 34.

The processing unit 32 comprises a storage 36 of memory and a processor 38.

A storage 36 stores a transfer software application 40. The memory storage 36 includes, in addition, a second storage area 42 for storing predetermined code.

The transmitter 34 is capable of supplying signals to the communication medium 8. In the case of a pressure line forming a communication medium 8, the transmitter 34 is capable of delivering sound waves. In the case of an electric cable forming a communication medium 8, the transmitter 34 is capable of supplying electrical signals.

The transmission software application 40 is capable of generating a signal that is modulated by a predetermined code. The transmission software application 40 is further capable of transmitting the generated signal to the transmitter 34.

In operation, the transmission software application 40 of the transmitter’s beacon 12 generates a signal modulated by a predetermined code, which is stored in the second storage area 42. The predetermined code thus further generates encoding data. Next, the transmitter 34 of the radio beacon 12 of the transmitter signals the communication medium 8.

Preferably, the transmitter beacon 12 transmits a signal sequentially over time with a repetition rate that is above 0.1 Hz, preferably above 1 Hz, for example, above 5 Hz.

If the receiver 16 of the control beacon 10 receives a signal routed and transmitted by the communication medium 8, then the software application 22 for receiving the control beacon 10 processes the indicated signal to extract a code from it. Next, the comparison software 24 compares the received code with a predetermined code that is stored in the first storage area 28. If the received code is identical to the given code, it is further considered that the train 2 has uncompromising coupling integrity, and the control beacon 10 transmits a coupling integrity confirmation signal confirming the integrity of the railway coupling, for example, sent to the operator or the railway network monitoring system.

If the received code is different from the set code, or if at the end of the set waiting period the control beacon 10 does not receive a signal containing a code that is identical to the set code, then the control beacon 10 does not transmit an integrity confirmation signal to confirm the integrity of the railway vehicle.

According to a second embodiment of the detection device 4 according to the invention, the control beacon 10 and the transmitter beacon 12 are further capable of performing at least one error detection algorithm for detecting transmission errors.

For example, the control beacon 10 and the transmit beacon 12 are capable of functionally executing an algorithm for detecting transmission errors using CRC coding (for “cyclic redundancy check”), which is traditionally known.

In the case of CRC coding, the algorithm performs a given generating polynomial. Preferably, the predetermined generating polynomial is capable of detecting, with a higher level of reliability than the predetermined threshold value of reliability, possible errors during transmission between the control beacon 10 and the transmitter beacon 12.

As illustrated in FIG. 4, the storage 18 of the memory of the processing unit 14 of the control beacon 10 also stores the calculation software application 44. The storage 18 of memory includes in addition a third storage area 46 for storing a generating polynomial. Unlike the control beacon 10 illustrated in Figure 2, the control beacon 10 illustrated in Figure 4 does not include a first storage area for storing a predetermined code.

As illustrated in FIG. 5, the storage 36 of the memory of the processing unit 32 of the radio beacon 12 of the transmitter also stores the calculation software 48. The storage 36 memory includes in addition a fourth storage area 50 for storing a generating polynomial.

The calculation software application 44 and 48, respectively, is capable of applying an algorithm to perform detection of a generating polynomial stored in the third storage area 46 and the fourth storage area 50, respectively, to the code. In particular, the transmitter beacon calculation software application 48 is capable of applying a detection algorithm to a given code stored in the second storage area 42. In addition, the control software application 44 for computing the beacon 10 is capable of applying the detection algorithm to the code provided by the receive software application 22.

In operation, the software application 48 for calculating the radio beacon 12 of the transmitter calculates a control key related to a given code. Further, the software application 40 for transmitting the radio beacon 12 of the transmitter transmits a signal to the transmitter 34, which is modulated with a given code and the corresponding control key. The control key further generates encoding data. The transmitter 34 provides the specified signal to the communication medium 8.

If the receiver 16 of the control beacon 10 receives a signal transmitted by the communication medium 8, then the program application 22 for receiving the control beacon 10 processes the indicated signal to extract a code and a corresponding key from it. Next, the software calculating application 44 calculates a control key related to the code extracted by the receiving software application 22 by means of a generating polynomial stored in the third storage area 46. The comparison software application 24 further compares the key extracted by the reception software application 22 and the key calculated by the calculation software application 44. If the computed key is identical to the extracted key, it is further considered that the train 2 has uncompromising coupling integrity, and the control beacon 10 transmits a coupling integrity confirmation signal confirming the integrity of the railway coupling, for example, sent to the operator or the railway network monitoring system.

If the computed key is different from the extracted key, or if at the end of the specified waiting period the control beacon 10 does not receive a signal containing a code that is identical to the specified code, then the control beacon 10 does not transmit an integrity confirmation signal to confirm the integrity of the railway vehicle.

According to a third embodiment of the detection device 4, illustrated in Figures 6-9, the control beacon 10 is installed in the tail carriage 6B, and the transmitter beacon 12 is installed in the head carriage 6A.

The control beacon 10 illustrated in FIG. 7 differs from the control beacon 10 illustrated in FIG. 4 in that it comprises an electromagnetic wave transmitter 52, also called a “transmit antenna”. In addition, the memory storage 18 of the control beacon 10 stores a transmission software application 56 similar to the transmission software application 40 described above. The storage 18 of the memory of the beacon 10 control does not store any software application comparison.

The transmitter beacon 12, illustrated in Figure 8, differs from the transmitter beacon illustrated in Figure 5 in that it contains an electromagnetic wave receiver 58, also called a “receiving antenna,” as illustrated in Figure 8. Moreover, the memory storage 36 of the beacon 12 the transmitter stores a comparison software application 60 similar to the comparison software application 24 described above. Memory storage 36 also stores a reception software application 62 similar to the reception software application 22 described above.

The transmit antenna 52 is capable of emitting an electromagnetic signal into the air.

Preferably, the transmitting antenna 52 of the control beacon 10 is capable of emitting an electromagnetic signal either directly in the direction of the receiving antenna 58 of the beacon of the transmitter 12, or through a communication network, for example, of type GSM-R (Global Railway System for Mobile Communications).

The receiving antenna 58 is capable of receiving an electromagnetic signal that propagates through the air. Preferably, the receiving antenna 58 of the transmitter beacon 12 is capable of receiving an electromagnetic signal, either directly from the transmitting antenna of the control beacon 10, or coming through a communication network, for example, of type GSM-R.

The transmission software application 40 of the processing unit 32 of the transmitter beacon 12 is capable of generating a signal that is modulated by a code, also called a “modulating code”, for example, a given code or a random code.

The third storage area 46 of the radio beacon 10 control and the fourth storage area 50 of the beacon transmitter 12 store a predetermined function. Such a function is capable of associating an image code with a code supplied to a function.

Each of the control beacon calculation software application 44 and the transmitter beacon calculation application 48 are capable of applying a predetermined function stored in the third storage area 46 and in the fourth storage area 50, respectively, to the code.

The operation of the detection device 4 will be described with reference to Figure 9.

In operation, the transmission software application 40 of the transmitter’s beacon 12 generates a signal that is modulated by a modulating code. The modulating code thus generates encoding data. Next, the transmitter 34 of the radio beacon 12 of the transmitter supplies the generated signal to the communication medium 8. In addition, the software application 48 for calculating the radio beacon 12 of the transmitter applies the predetermined function, which is stored in the fourth storage area 50, to the modulating code to obtain the source image code.

If the receiver 16 of the control beacon 10 receives a signal transmitted by the communication medium 8, then the software application 22 for receiving the control beacon 10 processes the indicated signal to extract a code from it. Next, the calculation software application 44 calculates an image code by a predetermined function that is stored in the third storage area 46 from the extracted code. The transmission software application 56 of the control beacon 10 further generates a response signal comprising an image code from the extracted code. Further, the transmitting antenna 52 of the control beacon 10 emits a response signal in the form of an electromagnetic wave into the air.

If the receiving antenna 58 of the radio beacon 12 of the transmitter receives a signal emitted by the transmitting antenna 52 of the radio beacon 10 of the control, then the software application 62 for receiving the radio beacon 12 of the transmitter processes the signal to extract an image code from it. Next, the comparison software application 60 compares the extracted image code and the image source code. If the extracted image code is identical to the original image code, it is further considered that the train has uncompromising coupling integrity, and the control beacon 10 transmits a link integrity confirmation signal confirming the integrity of the railway coupling, for example, sent to an operator or a railway network monitoring system.

If at the end of the next second predetermined waiting period following the transmission of the transmitted signal, the receiving antenna 58 of the transmitter beacon 12 does not receive a signal coming from the transmitting antenna 52 of the control beacon 10, then the control beacon 10 does not transmit a link integrity confirmation signal confirming the integrity of the railway transport coupling facilities.

In addition, if the extracted image code is different from the original image code, and if at the end of the third predetermined waiting period, the receiving antenna 58 of the transmitter beacon 12 does not receive a new signal for which the extracted image code is identical to the original image code, then the control beacon 10 does not transmit hitch integrity confirmation, confirming the integrity of the hitch of a railway vehicle.

According to a fourth embodiment of the detection device 4 illustrated in Figures 10-12, a control beacon 10 is installed in the tail carriage 6B, and a transmitter beacon 12 is installed in the head carriage 6A.

The control beacon 10 illustrated in Figure 11 is different from the control beacon illustrated in Figure 7 in that it does not include an electromagnetic wave transmitter. The latter has been replaced by a transmitter 64, similar to the transmitter 34 of sound or electrical signals, illustrated in Figure 8, which is connected to the communication medium 8.

The transmitter beacon 12 illustrated in Figure 12 is different from the transmitter beacon illustrated in Figure 8 in that it does not include an electromagnetic wave receiver. The latter has been replaced by a receiver 66, similar to the receiver 16 for audio or electrical signals, illustrated in Figure 7, which is connected to the communication medium 8.

In this embodiment, the communication medium 8 is used in a bi-directional manner, as shown in Figure 13, in other words, for transmitting signals from the radio beacon 12 of the transmitter, the control beacon 10 and from the control beacon 10, the radio beacon 12 of the transmitter.

The operation of the device 4 shown in Figures 10-12 is similar to the operation of the device 4 illustrated in Figures 6-8.

According to the fifth embodiment, the device 4 is additionally able to transmit an additional information element in the generated signal from the first beacon 10, 12 to the second beacon 12, 10 using the communication medium 8, which is not related to confirming the integrity of the train coupling, this information is presented in addition to coding, performed on the generated signal, which makes it possible to confirm the integrity of the composition.

In this embodiment, the communication medium 8 is used either bi-directionally or not, thereby providing communication, which does not necessarily relate to integrity verification, between the first beacon 10, 12 and the second beacon 12, 10.

Claims (18)

1. Device for confirming the integrity of the coupling for confirming the integrity of the coupling of a train comprising at least one first carriage and one second carriage, moreover, the device comprises a communication medium passing between the first carriage and the second carriage, a first airborne beacon installed in one of the cars and connected to a communication medium, a second airborne beacon installed in another of the cars and connected to a communication medium: wherein: the second beacon is configured to generate a signal modulated with the specified coding data and transmit the modulated signal to the communication medium; the communication medium is configured to transmit the specified signal to the first beacon, and the communication medium is further configured to provide a gap in the event of a break in the coupling between the two cars, thereby preventing the signal from propagating to the first radio beacon; the first beacon is configured to receive a signal transmitted by the communication medium and to extract encoding data extracted from the received signal; wherein the device is characterized in that it is configured to confirm the integrity of the coupling between the wagons of the train, when the encoding data retrieved by the first beacon is identical to the specified code data, while the second beacon is configured to calculate an image of a predetermined code by means of a first predetermined function to generate a computed key, wherein the computed key generates encoding data, while the second beacon is further configured to modulate said signal generated by the second beacon by means of a predetermined code; but the first beacon is configured to extract the extracted code and the extracted key from the signal received by the communication medium, and apply the first predetermined function to the extracted code to generate the calculated key, wherein the device is characterized in that it is configured to confirm the integrity of the coupling between the cars of the train when the key extracted by the first beacon is identical to the key calculated by the first beacon. 2. The device according to claim 1, in which the first beacon is configured to apply a second predetermined function to the extracted encoding data to generate image data, generate a response signal modulated with image data, and transmit a response signal transmitted to the second beacon; wherein the second beacon is configured to apply a second predetermined function to the encoding data for generating the original image data, receiving a response signal, extracting the extracted image data from the received response signal, and comparing the extracted image data with the original image data; moreover the device is characterized in that it is configured to confirm the integrity of the coupling between the cars of the train, when the extracted image data is identical to the original image data. 3. The device according to claim 2, in which the first beacon includes an electromagnetic wave transmitter, the second beacon includes an electromagnetic wave receiver, the first beacon configured to transmit a response signal through an electromagnetic wave transmitter, and the second beacon configured to receive a response signal using receiver of electromagnetic waves. 4. The device according to p. 1, in which the communication medium is a pressure line of the train, while the second beacon is configured to supply an acoustic signal to the communication medium. 5. The device according to claim 1, in which the communication medium is an electric cable of a train, wherein the second beacon is configured to supply an electrical signal to the communication medium. 6. The device according to claim 1, characterized in that it is additionally configured to transmit in the signal generated by the first beacon for the second beacon, using the communication medium, an additional information element not related to confirming the integrity of the train. 7. The train, including the device according to claim 1 for confirming the integrity of the coupling of the specified coupling of the train.

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