RU2618659C1 - System of interval regulation of train traffic on basis of satellite navigation funds and digital radio channel with coordinate method of control - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: system includes locomotive on-board devices based on a complex locomotive safety device and a stationary device consisting of a personal computer of the operator's workstation with an uninterruptible power supply, a GPS/GLONASS signal receiver, a stationary radio modem connected through a duplex filter with an antenna. Moreover, a personal computer is equipped with a real-time data generation module about free station rail circuits and a module for generating and controlling the transmission of information to locomotives via a fixed radio modem. The second input of the personal computer is connected to the output of the periodic interrogation unit connected to the equipment of the electrical centralisation of the station, and each locomotive is equipped with a module for checking the compliance of the locomotive time intervals of the train locomotive with the railway route sections, which is connected to the additional input of the information processing unit.

EFFECT: improving the reliability of the system and the safety of train traffic by stations.

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Description

The invention relates to railway transport and can be used at railway stations equipped with interval control system equipment to improve traffic safety and increase the speed of trains passing through the station.

A known system of interval regulation of train traffic based on satellite navigation aids, containing on the locomotive electronics, indication, switching and data input units located in the driver’s cab. The electronics unit is capable of determining the permissible speed mode and exercising control over its observance by fixing feedback signals from the driver’s vigilance handle, internal background testing of each module, as well as two-channel information processing, and includes two central information processing modules, a route module , digital radio channel module, two modules for measuring motion parameters, two modules for external devices, a security monitoring system and an electro-pneumatic amplifier matic valve. The locomotive information display unit for the driver is configured to prepare the information necessary for the driver, register and display it, interact with the driver through the safety knob and information input buttons, enter and display locomotive and train characteristics, current time, actual speed and store them when the power is turned off and includes a registration module, a control module and a locomotive information display unit for the driver (RU 2248899, B61L 25/04, 03/27/2005).

A disadvantage of the known system is the low throughput and fault tolerance, the lack of the possibility of a forced stop of a mobile unit at the command of a station attendant or train dispatcher, as well as limited functionality and the high influence of the human factor on traffic safety.

Of the known systems of interval regulation of train traffic, the closest to the proposed combination of essential features and functionality is the system of interval regulation of train traffic based on satellite navigation aids and a digital radio channel with a coordinate monitoring method, containing on-board devices on locomotives made on the basis of an integrated locomotive safety device , which includes an electronics unit, the navigation equipment of which is connected with the GPS / GLONASS antenna, the first input / output of the electronics unit is connected to the output / input of the on-board radio modem, which is connected via a duplex filter to the first antenna, the first output of the electronics unit is connected to the display unit, the second and third outputs are connected to the brake line, respectively, via a prefix of the driver’s crane and through the electro-pneumatic valve, and the fourth output is connected to the locomotive traction control circuit, the first and second inputs of the electronics block are connected respectively to the output of the Alarm button and to the data exchange unit about the coordinate of the tail of the train connected to the second antenna, while the stationary device consists of a personal computer installed on an automated workstation connected to a radio modem, the second port of which is connected to a duplex filter connected to the antenna of the radio channel and the gas discharge input to a personal the computer of the workstation is connected to the output of the navigation receiver, the input of which is connected to the antenna, and the output of the interface device to the electronic system ktricheskoy centralization (RU 93766, B61L 25/04, 10.05.2010).

A disadvantage of the known system is that the traffic control method along the correct route does not have a sufficient level of safety integrity due to the lack of satellite navigators on locomotives and the lack of differential correction devices at the station with technical implementation at the SIL4 safety integrity level. The accuracy of the method of determining the current coordinate only by GPS / GLONASS may also decrease due to the shielding of signals from some satellites to a level that no longer allows you to distinguish adjacent railway lines from each other. Therefore, in addition to satellite navigation, to ensure the required level of SIL4 safety integrity, locomotive devices must now use data from additional independent sources of information about the correct route of the train traveling through the station to move along the established route through the station with the maximum permitted speed.

Such additional data sources at the station can be inductive or digital radio channels. Inductive communication channels can be provided by using code rail circuits transmitting rail circuit numbers in a code signal, or by using inductive communication loops of the SAUT system in front of the input traffic lights with the transmission of all information along them to control the correct movement along the route. The methods associated with inductive data transfer from the path to locomotives require complicated track equipment, which in many cases is absent and is not economically feasible to install. Digital radio communication channels between a stationary device and locomotives using address data transmission also allow control data to be transmitted to the locomotives to ensure correct movement along the route, but they have low noise immunity and limitations on the number of locomotives involved in the communication system.

In the known system, the function of safely confirming to the drivers when moving around the station that their locomotives follows the correct route to the station is realized either by over-complicating and increasing the cost of the travel device system, or by over-complicating the protocol and reducing the reliability of data transmission via digital radio communications.

The technical result of the invention is to increase the reliability and safety of trains on stations by reducing the requirements for the equipment of station track devices and improving the reliability of data transmission using digital radio communication to perform the function of monitoring the tracking of locomotives along the correct reception routes to the station.

The technical result is achieved by the fact that in the system of interval control of train movements based on satellite navigation aids and a digital radio channel with a coordinate monitoring method, containing on-board devices on locomotives made on the basis of an integrated locomotive safety device, which includes an information processing unit, whose navigation equipment connected to the GPS / GLONASS antenna, the input / output of the information processing unit is connected to the output / input of the on-board radio modem, which A duplex filter is connected to the first antenna, the first output of the information processing unit is connected to the information display unit for the driver, the second and third outputs are connected to the brake line, respectively, through the attachment of the driver's crane and through the electro-pneumatic valve, and the fourth output is connected to the locomotive traction control circuit, the first and the second inputs of the information processing unit are connected respectively to the output of the Alarm button and to the output of the data exchange unit about the coordinate of the tail of the train connected to the second the stationary device consists of a personal computer of the operator’s workstation with an uninterruptible power supply connected to it, a GPS / GLONASS signal receiver is connected to the first input of the personal computer, and its input / output is connected to the output / input of the stationary radio modem connected via duplex filter with antenna, according to the invention, the personal computer of the operator’s workstation is equipped with a software module for generating real-time data exchange of free station rail circuits and a software module for generating and controlling the transmission of information to locomotives via a stationary radio modem, while the second input of a personal computer is connected to the output of a periodic polling unit connected to the station's electrical centralization equipment, and each locomotive is equipped with a software module for checking the correspondence of time intervals locomotive classes of rail chains of track sections of the train route, which is connected to the additional input of the block brabotki information.

The drawing shows a structural diagram of the proposed system of interval regulation of train traffic based on satellite navigation aids and a digital radio channel with a coordinate control method.

The system of interval control of train traffic based on satellite navigation aids and a digital radio channel with a coordinate control method contains on-board devices on locomotives based on an integrated locomotive safety device (CLUB) 1, which includes an information processing unit 2, the navigation equipment of which is connected to the antenna 3 GPS / GLONASS, the input / output of the information processing unit 2 is connected to the output / input of the on-board radio modem 4, which is connected via a duplex filter 5 to the first antenna 6, the first output of the information processing unit 2 is connected to the information display unit 7 to the driver, the second and third outputs are connected to the brake line, respectively, through the attachment 8 of the driver’s crane and through the electro-pneumatic valve 9, and the fourth output is connected to the locomotive traction control circuit, the first and the second inputs of the information processing unit 2 are connected respectively to the output of the Alarm button 10 and to the output of the data exchange unit 11 about the coordinate of the tail of the train connected to the second antenna 12, while The device 13 consists of a personal computer 14 of the operator’s automated workstation with an uninterruptible power supply 15 connected to it, a GPS / GLONASS receiver 16 of signals is connected to the first input of the personal computer 14, and its input / output is connected to the output / input of a stationary radio modem 17 connected through a duplex filter 18 with an antenna 19. The personal computer 14 of the operator’s workstation is equipped with a software module 20 for generating real-time data on free station rail circuits and a software module 21 for forming and controlling the transmission of information to locomotives through a stationary radio modem 17, while the second input of the personal computer 14 is connected to the output of the periodic polling unit 22 connected to the electric centralization equipment of the station, and each locomotive is equipped with a program module 23 for checking the correspondence of intervals time occupied by the locomotive rail chains of track sections of the train movement route, which is connected to an additional input of information processing unit 2 .

The system of interval regulation of train movement based on satellite navigation aids and a digital radio channel with a coordinate monitoring method implements the following functions:

- reliable control of locomotive tracing along the correct reception routes to the station;

- prevention of access to the prohibitory traffic signal in an unencrypted area on command from a personal computer 14 of the automated workstation of the operator of the interval control system;

- transmission of a command to allow the prohibition of the prohibition signal of a traffic light using train radio communication;

- transfer of the coordinates of the tail of the train ahead in order to follow the traffic light with a yellow indication without reducing speed;

- receiving the alarm signal on the personal computer 14 from any mobile unit;

- targeted forced braking of one locomotive by command from a personal computer 14;

- targeted cancellation of forced braking of traction rolling stock on command from a personal computer 14;

- simultaneous forced braking of all locomotives on command from a personal computer 14;

- the cancellation of the simultaneous braking of all traction rolling stocks on command from a personal computer 24.

The system of interval regulation of train traffic based on satellite navigation aids and a digital radio channel with a coordinate control method works as follows.

The stationary device 13 begins to work immediately after turning on the uninterruptible power supply 15, after which messages are transmitted from the personal computer 14 via the serial interface to the stationary radio modem 17 to the antenna 19 in accordance with the interaction algorithm.

The locomotive safety device 1 starts working immediately after turning on the power source. Radio telegrams from the stationary device 13 are transmitted via radio channels and received on each of the locomotives through the first antenna 6 and the duplex filter 5 to the on-board radio modem 4. And from there, after decoding, they enter the information processing unit 2 in accordance with the interaction algorithm. Via radio channels, through the second antenna 12, data from the locomotive of the train ahead of them or from stationary devices 13 connected to it is transmitted to the train tail coordinate data exchange unit 11 (data is received if the second train approaches the tail car of the first train at a distance that requires a decrease in speed movement of the second train). The signals from the GPS / GLOIASS antenna 3 are fed to the navigation receiver of the information processing unit 2, which generates data on the location of the device (latitude, longitude). Then this data is converted in the information processing unit 2 to the locomotive position in railway coordinates on the route electronic map for calculating the braking curves and displaying the train position on the locomotive information display unit 7 to the driver.

In the event of an emergency on the locomotive, the driver or assistant driver, while following in the communication zone with the station by pressing button 4 “Alarm”, transmits to the stationary device 13 a signal about the need to force stop the locomotive. After receiving a forced stop signal from the stationary device 13, the locomotive traction is disassembled and service braking starts through the prefix 8 of the driver’s crane, the electro-pneumatic valve 9 will automatically stop the locomotive, and the locomotive will display an indication of the forced stop of the locomotive on the locomotive information display unit 7. After the locomotive stops completely, the train driver, using the train voice radio communication, finds out the reason for the stop with the station attendant or train dispatcher.

After the cancellation of the forced stop command, the electro-pneumatic valve 9 is set to the operating position. The transmission of the prohibition signal travel command upon command from the personal computer 14 is carried out in the following sequence.

The station attendant or train dispatcher, having ascertained that there is a stable radio mode with mobile units and that the mobile unit stops in front of a red traffic light, gives a command to allow the prohibition signal to be passed through the personal computer 14. After obtaining a permit for the prohibition signal on the information displaying unit 7 to the driver before the start of the movement, the value of the permissible speed of the moving unit will be set equal to 20 km / h, and the signal “KZh" on the information display unit 7 to the driver "BM" etsya on the signal.

The stationary device 13 transfers to the locomotive temporary speed limits, as well as the calculation and testing of the locomotive braking curve to the point of limiting the speed of movement, is carried out in the following sequence:

- The station attendant or train dispatcher enters the characteristics of speed limits and makes sure that there is a stable radio mode with mobile units.

- After receiving from the stationary device 13 a time limit, the locomotive safety device 1 fulfills the calculated braking curve when approaching the place of restriction of speed.

Address data exchange between the locomotive safety device 1 and the stationary device 13 consists of 2 stages:

- identification procedure of the locomotive device 1;

- exchange between the stationary device 13 and the locomotive safety device 1 after identification.

The identification procedure of the locomotive safety device 1 is as follows.

The interval between messages of the stationary device 13 during the address exchange of information with locomotives is determined during program setup and varies from 200 ms to 10,000 ms.

The identification procedure of the locomotive safety device 1 for the address exchange of information occurs when the locomotive safety device 1 responds to the invitation. After sending the invitation, the stationary device 13 does not transmit messages for 3 intervals. The locomotive safety device 1, using the random number procedure, responds to the invitation.

The invitation is transmitted normally (in the presence of registered locomotive safety devices 1) and not normally (in the absence of registered locomotive safety devices 1). In normal mode, every 60 (according to the setting) intervals, an invitation is sent. In non-standard mode, the invitation is transmitted continuously (subject to the agreed interval).

All address messages are subject to mandatory acknowledgment. In case of transmission of a broadcast message (stop / cancel stop command for all locomotives equipped with locomotive safety device 1 located in the radio communication zone), acknowledgment does not occur.

In the proposed system, the broadcast message is additionally used to solve the technical problem of increasing the reliability and safety levels of monitoring the correctness of trains following established reception routes at the station. Simplification and increase of reliability of using digital radio communication channels is achieved due to the simplified protocol for transmitting and receiving broadcast messages described above, which does not require registration of locomotive safety devices 1 and acknowledgment. Simplification and cheaper equipment is achieved in the proposed system by the fact that the information on the current vacancy of the station rail circuits transmitted in these broadcast messages makes it possible to increase the level of reliability of control by the locomotive safety device 1 of the correct train following the reception route established for it by the station or train duty dispatcher to the SIL4 requirements level without the use of additional track devices. To do this, the rail circuits at the station may not have coding, and there is no need to place SAUT track devices in front of the traffic lights.

The formation, transmission and processing of broadcast telegrams with arrays of real-time data on the current freedom of station rail circuits in the inventive system is as follows.

The analog signals taken from the contacts of the repeaters of the track receivers of the station rail circuits are supplied from the electrical centralization equipment to the periodic polling unit 22. The periodic polling unit 22 converts the analog signals into logic signals 1 for closed contacts and 0 for open contacts of track repeater repeaters at a predetermined periodicity and generates data arrays of station rail circuit numbers having open contacts of track repeater repeaters. With a frequency of, for example, 3-5 s from the periodical polling unit 22, these data arrays enter the personal computer 14 of the automated workstation of the interval control system operator. There, these arrays are analyzed by the software module 20 for generating real-time data on free station rail circuits, and the numbers of free station rail circuits are converted into arrays. Then, these arrays of numbers of free station rail circuits are transmitted to the module 21 for generating and controlling the broadcast telegrams to locomotives, which, for example, packs this data every 2-4 s into the format of broadcast telegrams, which are sent from the personal computer 14 to the stationary radio modem 17 and transmitted via radio channels simultaneously to all locomotives moving in the station.

Since the protocol for receiving broadcast telegrams is much simpler and more reliable than the protocol for address exchange between the station device 13 and locomotives, these broadcast telegrams are received and decoded on locomotives with a high level of reliability. In the on-board radio modem 4 of each locomotive, these telegrams are decoded and transferred from it to the information processing unit 2 for processing the telegram data by the program module 23 for checking the correspondence of the time intervals for occupying rail circuits. After decoding from broadcast telegrams, data packets are used for the current display of the free state of the track sections of the entire station on the screen of the information display unit 7 to the driver.

The software module 23 for checking the correspondence of time intervals for occupying rail circuits in the information processing unit 2 verifies the correspondence of the time intervals for locating the rail chains of the track sections of the train track determined on the locomotive itself to the time intervals for occupying the same rail circuits recorded in the personal computer 14 of the stationary device 13 , according to changes in the state of the contacts of the repeaters of the track receivers of these rail circuits. The time intervals of locomotive occupying rail chains of track sections of the train movement route are determined in information processing unit 2 on the locomotive itself by tracking the current coordinate of the locomotive in the GPS / GLONASS coordinate system with reference to the electronic map of the current train route. The time synchronization in the stationary device 13 is carried out from the stationary GPS / GLONASS receiver 16, and on locomotives is carried out according to the signals of the GPS / GLONASS receiver of the navigation equipment of the information processing unit 2. For example, if, with a tolerance of 1 second, the moment of opening the front contacts of the repeater of the track receiver of the next rail chain due to the front wheels of the locomotive entering it coincide with the moment the locomotive crosses the coordinates of the beginning of the same rail chain on the electronic route map, then this is recorded in the program module 23, and in block 2 of information processing, a confirmation is obtained with reliability at the level of SIL4 requirements (the coincidence of three independent conditions is data on the numbers of rail circuits from the route task, data on ovpadenii slots and the fact that these classes of track circuits on the track and on the locomotive apparatus) the fact locomotive on the correct route following administration. The system automatically corrects driver errors when typing a route. If, for example, on the stage after the voice message of the station attendant or train dispatcher about the route to the station, the driver incorrectly typed it on the function keyboard of the information display unit 7, then this error after the train follows the open traffic light and occupies the first rail circuit of the established route along the station will be automatically corrected by the information processing unit 2, and the correct train situation will be displayed on the information displaying unit 7 and the route given nogo and other trains in the station. In this case, the driver will be notified of the automatic correction by the information processing unit 2 of his error with the simultaneous requirement of the driver once confirming his vigilance by pressing the vigilance handle.

Thus, the proposed system improves the reliability and safety of trains on stations by simplifying the equipment requirements of station track devices and increasing the reliability of data transmission using digital radio communications to perform the function of monitoring the tracking of locomotives along the correct reception routes to the station.

Claims (1)

An interval control system for train movements based on satellite navigation aids and a digital radio channel with a coordinate monitoring method, containing on-board devices on locomotives based on an integrated locomotive safety device, which includes an information processing unit, the navigation equipment of which is connected to a GPS / GLONASS antenna, the input / output of the information processing unit is connected to the output / input of the on-board radio modem, which is connected to the first antenna through a duplex filter This, the first output of the information processing unit is connected to the information display unit for the driver, the second and third outputs are connected to the brake line, respectively, through the attachment of the driver crane and through the electro-pneumatic valve, and the fourth output is connected to the locomotive traction control circuit, the first and second inputs of the information processing unit are connected respectively, to the output of the Alarm button and to the output of the data exchange unit about the coordinate of the tail of the train connected to the second antenna, while the stationary device consists of um from a personal computer of the operator’s workstation with an uninterruptible power supply connected to it, a GPS / GLONASS signal receiver is connected to the first input of the personal computer, and its input / output is connected to the output / input of a stationary radio modem connected through a duplex filter with an antenna, characterized in that the personal computer of the operator’s workstation is equipped with a software module for generating real-time data on free station rail circuits and a software module for generating and controlling the transmission of information to locomotives via a stationary radio modem, while the second input of a personal computer is connected to the output of the periodic polling unit connected to the electric centralization equipment of the station, and each locomotive is equipped with a software module for checking the correspondence of the time intervals for locomotive occupying rail track sections the route of the train, which is connected to the additional input of the information processing unit.

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