RU2737817C1 - System for hybrid control of marshalling yards operation with decision support function on procedure for trains classification - Google Patents

Abstract

FIELD: rail transport.

SUBSTANCE: invention relates to railway transport and can be used for control of marshalling yards and prediction of their operation results. System for hybrid control of operation of marshalling yards with function of supporting decision making on procedure for trains classification comprises an automated workstation computer, which includes a processor with a data input/output unit connected to it, a monitor, a memory unit and a unit for processing and generating output data, which output is connected to second input of monitor, additional input/output of processor is connected to first output/input of server, second output/input of which is connected via data network with corresponding inputs/outputs of hardware-software devices of automatic control system of marshalling and goods yards, automated system for on-line control of transportation and automated dispatching control center, first and second interfacing units. At that, in the specified system there introduced is a matching unit, the first, second and third outputs of which are connected to the input of the processor, respectively, with second input of processing unit and generating output data and with first input of actual operation data generating module connected to memory unit, in which database of real operation of yard by clock is recorded, and to which a departure point set unit is connected, a data recording unit connected to the output of infrastructure approach sensors of trains.

EFFECT: as a result, the system functional capabilities are expanded, control efficiency of marshalling yards is increased.

1 cl, 1 dwg

Description

The invention relates to rail transport and can be used to control marshalling yards and predict the results of their work.

There is a known system for controlling the operation of sorting stations of the direction, containing an automated workstation of the responsible employee of the direction of traffic control, including a processor with an input / output unit and a monitor, a memory unit, the input / output of which is connected to the corresponding output / input of the processor, the first output of which is connected to the input a block for processing and generating output data, the output of a monitor connected to another input, a block for modeling the operation of marshalling yards, which includes a series-connected block for calculating train decomposition options, a block for choosing a train decomposition sequence, a block for selecting a sequence for accumulating wagons and a block for modeling the departure of formed trains, the output of which is connected with the first input of the processor, as well as the unit for calculating the indicators of the operation of sorting and freight stations for the past period, the input of which is connected to the first output of the processor, and the output is connected to the first input of the block for calculating the variants train operation, a block for the formation of planned indicators of the operation of marshalling and freight stations, the input of which is connected to the second output of the processor, and the output is connected to the second input of the block for calculating the variants of train expansion, the block for the formation of an actual formation plan, the input of which is connected to the third output of the processor, and the output is with a block for analyzing options for the sequence of train disbandment, a block for generating average car flows of marshalling yards, the input of which is connected to the fourth output of the processor, and the output is connected to the input of the block for selecting the sequence of accumulation of cars, while other inputs / outputs of the processor are connected via a server via a data transmission network with the corresponding outputs / inputs of hardware and software devices of an automated control system for sorted and cargo stations, an automated system for operational management of transportation and an automated dispatch center, as well as outputs / inputs of the first and second interfaces, the inputs of the first interface units are connected to the sensors of the approach of freight trains installed on the tracks of the marshalling yards, and the inputs / outputs of the second - to the outputs / inputs of the hardware and software devices of the centers for complex diagnostic monitoring of the technical condition of the rolling stock of moving trains (RU2500558, B61B 1/00, 10.12 .2013).

The system for controlling the operation of marshalling yards in the direction of the railway network allows you to control the operation of marshalling yards, in conjunction with the work of the direction of the railway network, at the stages of monthly, ten-day, shift-daily planning and management, checking the implementation of the plan by simulating the processing of car flows at marshalling yards and the movement of trains along the sections of the direction, the coordination of indicators of shift-daily work plans within the boundaries of the direction and the development of optimal control decisions.

However, this system does not have the functionality for building reference technological processes of the station operation, taking into account the variance of development.

As a prototype, a system was adopted to control the operation of marshalling yards in the direction of the railway network, containing a computer for an automated workstation, including a processor with a data input / output unit connected to it, a monitor, a memory unit and a processing unit and output data generation, the output of which is connected to the second input monitor, a block for simulating train operation of marshalling yards, consisting of a series-connected block for calculating train decomposition options, a block for choosing a sequence for disbanding trains, a block for choosing a sequence for accumulating cars and a block for simulating the departure of formed trains, the output of which is connected to the input of the processor, the first output of which is through the calculation block the performance indicators of marshalling yards for the past period is connected to the first input of the block for calculating the variants of train decomposition, the second input of which is connected to the unit for forming the planned indicators of the marshalling yards, to the input of which the second output of the processor is connected, the third output of which is connected through the block for forming the data of the current plan for the formation of trains to the block for selecting the sequence of train disbandment, the fourth output of the processor through the block for generating averaged data of car traffic flows of the marshalling yards is connected to the input of the block for selecting the sequence of accumulation of cars, the outputs of the processor are connected through the server, via the data transmission network, with the corresponding outputs / inputs of the hardware and software devices of the automated control system for marshalling and freight stations, the automated operational control system for transportation and the automated dispatch control center, the first and second interface blocks, while the inputs of the first block the interfaces are connected to the sensors for the approach of freight trains installed on the tracks of the marshalling yards, and the inputs of the second interface unit are connected to the hardware and software devices centers for complex diagnostic monitoring of the technical condition of the rolling stock of moving trains, a block for forming process models based on an artificial neural network with a learning function is connected to the server, to which four memory blocks are connected, while the first memory block contains a database of process models, in the second block In memory, a database of external technological processes is recorded, a database of technical and administrative acts and diagrams is recorded in the third memory block, and a database of event retrospective models of the station operation is recorded in the fourth memory block (RU2671790, B61B 1/00, 06.11.2018).

The disadvantage of the known system is the limited functionality due to the fact that when modeling and controlling the operation of marshalling yards, it does not take into account factors such as the dependence of the efficiency of managing marshalling yards on the consistency of the train departure schedule from the marshalling yard, with the availability of locomotives and locomotive crews.

The technical result of the invention is to expand the functionality of the system and improve the efficiency of management of sorting yards.

The technical result is achieved by the fact that the system for hybrid control of the operation of marshalling yards with the function of supporting decision-making on the procedure for disbanding trains, containing a computer for an automated workstation, including a processor with a data input / output unit connected to it, a monitor, a memory unit and a processing unit, and generating output data, the output of which is connected to the second input of the monitor, an additional input / output of the processor is connected to the first output / input of the server, the second output / input of which is connected via the data transmission network to the corresponding inputs / outputs of the hardware and software devices of the automated control system for sorting and cargo stations, an automated system for the operational management of transportation and an automated dispatch control center, the first and second interface units, while the inputs of the first interface unit are connected to the infrastructure sensors installed on the tracks of the marshalling yards train, and the inputs of the second interface block are connected to the hardware and software devices of the centers for complex diagnostic monitoring of the technical condition of the rolling stock of moving trains, while the third output / input of the server is connected to the input / output of the block for forming process models based on an artificial neural network with a learning function, to which four memory blocks are connected, while a database of process models is written in the first memory block, a database of external technological processes is written in the second memory block, a database of technical and administrative acts and schemes is written in the third memory block, and a database is written in the fourth memory block event retrospective models of the station operation, according to the invention, a matching unit is introduced, the first, second and third outputs of which are connected, respectively, to the processor input, to the second input of the processing unit and the formation of output data and to the first input of the module for generating data of the actual performance of work s connected to a memory unit in which the database of the actual operation of the station is recorded by the hour, and to which the unit for setting the point of departure is connected, the data logging unit connected to the output of the infrastructure sensors for train approach, and the data analysis module, the first input of which is connected to the first the output of the processor, the second output of which is connected to the second input of the data generation module of the actual work performance, the third input of which is connected to the data recording unit connected to the data transmission network, the first output of the data analysis module through the self-learning system block is connected to the first input of the simulation model block, the second input of which is connected to the output of the intelligent block for processing information about the dissolution approach, connected to the memory block, in which the database of the actual work of the station is recorded by the hour, and to the output of the simulation model block is connected to the block for simulating the composition of the accumulation, the second input of the data analysis module is connected to the fourth output the matching block, the fifth and sixth outputs of which are connected respectively to the input of the correction block of the direct simulation model, the output of which is connected to the third input of the simulation model block, and to the input of the correction block of the inverse simulation model, the output of which is connected to the block of simulation of the accumulation composition, the input / output of which is connected with the output / input of the matching unit, the unit for generating the departure schedule through the unit for setting the point of departure is connected to the input of the inverse simulation model, the output of which is connected to the input of the matching unit, the other inputs of the unit of the inverse simulation model are connected respectively to the outputs of the self-learning system unit, the unit for generating the issuance schedule locomotives and a block for forming a timetable for the appearance of locomotive crews, connected to a memory block in which a database of normative and reference information is recorded and to which a block for forming a departure schedule and a block for forming a schedule for issuing lo comotivs.

The drawing shows a functional diagram of a system for hybrid control of the operation of marshalling yards with the function of supporting decision-making on the procedure for disbanding trains.

The system for hybrid control of the operation of marshalling yards with the function of supporting decision-making on the order of disbanding trains contains a computer 1 of an automated workstation, including a processor 2 with a data input / output unit 3 connected to it, a monitor 4, a memory unit 5 and a block 6 for processing and generating output data output, the output of which is connected to the second input of the monitor 4, the additional input / output of the processor 2 is connected to the first output / input of the server 7, the second output / input of which is connected via the data transmission network 8 to the corresponding inputs / outputs of the hardware and software devices of the automated control system for sorting 9 and cargo 10 stations, an automated system 11 for operational management of transportation and an automated dispatch control center 12, the first and second blocks 13 and 14 of the interface, while the inputs of the first block 13 of the interface are connected to the infrastructure sensors 15 of the approach installed on the tracks of the marshalling yards trains, and the inputs of the second interface unit 14 are connected to the hardware and software devices of 16 centers for complex diagnostic monitoring of the technical condition of the rolling stock of moving trains (IC CDC), while the third output / input of the server 7 is connected to the input / output of the block 17 for forming process models based on an artificial neural network with a learning function, to which four memory blocks 18, 19, 20 and 21 are connected, while the first memory block 18 contains a database of process models, the second memory block 19 contains a database of external technological processes, and the third block 20 memory, the database of technical and administrative acts and schemes is recorded and in the fourth memory block 21 a database of event retrospective models of the station operation is recorded, the first, second and third outputs of the matching block 22 are connected, respectively, to the input of the processor 2, to the second input of the processing unit 6 and the formation of output data and with the first input of the module 23 for generating data of the actual about the performance of work connected to the memory unit 24, in which the database of the actual work of the station is recorded by the hour, and to which the unit 25 setting the departure point, the data recording unit 26 connected to the output of the infrastructure sensors 15 of the train approach, and the data analysis module 27 are connected , the first input of which is connected to the first output of the processor 2, the second output of which is connected to the second input of the unit 23 for generating data of the actual performance of work, the third input of which is connected to the data recording unit 26 connected to the data transmission network 8, the first output of the data analysis unit 27 via block 28 of the self-learning system is connected to the first input of the block 29 of the simulation model, to the second input of which the output of the intelligent block 30 processing information about the dissolution approach is connected, connected to the memory block 24, in which the database of the real work of the station is recorded by the clock, and to the output of block 29 the simulation model is connected to the block 31 for simulating the composition of the accumulation, the second input of the data analysis module 27 is connected to the fourth output of the matching block 22, the fifth and sixth outputs of which are connected, respectively, to the input of the direct simulation model correction block 32, the output of which is connected to the third input of the simulation model block, and to the input of the inverse simulation model correction block 33, the output of which is connected to the block 31 for simulating the composition of the accumulation, the input / output of which is connected to the output / input of the matching block 22, the block 34 for forming the departure schedule through the block 25 for setting the point of departure is connected to the input of the block 35 of the reverse simulation model, the output of which is connected to the input of the matching block 22 , the other inputs of the block 35 of the inverse simulation model are connected, respectively, to the outputs of the self-learning system block 28, the locomotive delivery schedule formation block 36 and the locomotive crew turnout schedule formation block 37, connected to the memory block 38, in which the database of normative and reference information is recorded and to which the unit 34 for generating the departure schedule and the unit 36 for generating the schedule for issuing the locomotives are connected.

The system for hybrid control of the operation of marshalling yards with the function of decision-making support on the order of the breaking up of trains operates as follows.

The system uses the data of the information system, which at the local (nodal) level ensures the execution of the following functions in an automated mode:

- forecast of car traffic for the marshalling yard for the planned period;

- planning the volumes of processing of car flows at the railway marshalling yard, taking into account the passage of transit trains on the basis of the current formation plan;

- planning the departure of trains from the marshalling yard on the basis of the current schedule in conjunction with the road.

At the polygon level in an automated mode, the proposed system performs:

- coordination of the work of marshalling yards of railways within the boundaries of the direction for the planned period;

- assessment of the work plan of the marshalling yard in conjunction with the work of the railway direction for the planned period;

- formation and issuance of assignments to the marshalling yards for the planned period.

The normative and technological basis for the work of the sorting station of the direction are:

- typical technological process of the sorting yard;

- the current plan for the formation of trains to be sent for the planned period;

- an up-to-date standard (variant) schedule of train departures from the station to the direction for the planned period;

- technical standards of operational work of the station and directions.

For the interaction of marshalling yards, the directions of the railway network analyze the work of the marshalling yard over the past accounting period; carry out planning based on the marketing forecast of the plan for loading the network and the direction of the roads for the accounting period; forecasting (planning) of loading by rolling stock by type, owner, etc. for the planned period; carry out control of the actual formation of trains at marshalling yards, taking into account which the model of the approach of trains with wagons by category from different directions for the forecast period is adjusted.

The operation of the marshalling yards is controlled in three stages.

At the first stage, preliminary planning (forecasting) of the operation of the marshalling station of the direction for a month at the network level is carried out with the development of directives for railways within the boundaries of the direction for a month (by decades).

At the second stage, the preliminary monthly work plan of marshalling yards is refined at the network level for a ten-day period with the development of directives for railways within the boundaries of the direction for a decade (by day).

At the third stage, they solve the problem of detailed planning of the work of marshalling yards at the road level per shift and day, with the subsequent coordination of the indicators of shift-daily work plans of the stations, and, if necessary, railways within the boundaries of the direction at the network level.

The responsible employee of the traffic control directorate from his computer 1 of the automated workstation (AWP) requests from the hardware and software devices of the automated control system of sorting 9 (ACS 9 SS) and 10 cargo (ACS 10 GS) stations information about typical and actual technological processes of sorting and freight stations. This information is transmitted via the data transmission network 8 to the server 7, which transmits it to the processor 2. The processor 2 processes the information data for each direction station and writes it to the memory unit 5. In addition, the memory block 5 stores information on the current train formation plan and the current normative train schedule for stations and sections of the direction for the planned period, as well as technical standards for the operational work of the direction.

The unit 6 for processing and generating output data carries out the appropriate processing and transformation of information from the memory unit 5 for its visual presentation on the screen of the monitor 4 in tabular and / or graphical form.

Information about the actual decomposition of cars in moving trains and their technical condition comes from the hardware and software devices of 16 centers for complex diagnostic monitoring of the technical condition of the rolling stock of moving trains. In them, data on the identification of the car and its technical condition are received during the passage of the train from the safety device located on the locomotive and the corresponding sensors installed on the train tracks.

Information about the decomposition of the train composition comes from the automated system 11 of the operational management of transportation (ASOUP), and about the characteristics and current state of the tracks and direction stations - from the automated dispatch control center 12 (ADCU).

When the train approaches the station's entrance traffic light, the train approach sensors 15, which are axle counting sensors, determine the number of axles and the type of train cars by which the train is identified. The corresponding information through the first interface unit 13, via the data transmission network 8, is transmitted to the automated system 11 for operational management of transportation and is taken into account in the operational planning of the supply of trains to the marshalling yard and disbandment of trains.

The results of modeling forecasts for the processing of cars at marshalling yards enter the processor 2, which transfers them for storage to the memory block 5, as well as to the block 6, which carries out the appropriate processing and transformation of information for its visual presentation on the monitor screen 4.

For clarity, the output information is presented on monitor 4 in the form of graphs, for example, hourly train departures from marshalling yards, histograms of carriages in trains, tables of the time spent by cars at marshalling yards, etc.

The system provides automatic receipt of highly detailed and closest to the optimal technological process of the station operation, as well as its automatic updating. In this case, the technological process is obtained in a formalized form, ready for presentation both to a person (in a paper version, available for reading) and for machine processing (in the form of technological chains written in the form of blocks of machine code).

For the formation of process models from the processor 2, information enters the block 17 for the formation of process models based on an artificial neural network with a learning function, where it is decomposed into components and based on them, the key elements of the process model are built. Also, the block 17 receives information from the memory block 18, in which the database of process models is recorded, from the memory block 19, in which the database of external technological processes is recorded, from the memory block 20, in which the database of technical and administrative acts and schemes is recorded and from block 21 of memory, which contains a database of event retrospective models of the station.

Block 17 for generating process models operates as follows. A set of technological operations (a set of operations) comes from the base of process models, from which a technological chain is built, based on data from memory blocks 18 and 19.

The parameters are initialized for the created chain. Statistics for evaluating such parameters are obtained from the memory block 21, which contains a database of event-driven retrospective models of the station's operation. On its basis, the artificial neural network (ANN) of the block selects the coefficients for the particular scheme under consideration, based on the minimum learning error of the ANN.

In block 17, the error functional is minimized in the process of building dependencies between information from block 17 and information from blocks 18, 19 and 20. The result obtained is used to form process models and is written into memory block 18. From the memory block 18, data on the process models are fed to the processor 2 of the computer 1 of the workstation of the technologist of the station, where these data are written into the memory block 5. Process models are used to control the operation of marshalling yards. Information about them comes from block 17 via data transmission network 8 when requested by the operator from his computer 1 AWP.

To increase efficiency in managing the operation of the station in the proposed system, additional information about the passage of individual points by trains (SAIPS, station boundaries, etc.), coming from the corresponding infrastructure sensors 15 for the approach of trains via communication channels, is automatically entered into the memory block 24, in which database of the actual work of the station by the hour. In this case, information from the infrastructure sensors enters the data recording unit 26, in which the signals are initially cleared from noise, the elimination of deliberately incorrect readings, etc.

From the database of block 24, this information is transmitted to the intelligent block 30 for processing information about the approach of the dissolution, also operating on the basis of an artificial neural network (ANN), the results of which are transmitted to block 29 of the simulation model (reception-dissolution) in the form of an arrival forecast ("direct model").

Meanwhile, the information from the memory unit 38, in which the database of normative and reference information is recorded (for example, the travel times on the tracks, the time for acceleration and deceleration, etc.), is transferred to the unit 34 for forming the departure schedule, in the unit 36 the locomotive delivery schedule and into block 37 of the formation of the locomotive crew attendance schedule. This information is necessary for the inverse simulation model to be initialized by block 35. The reverse simulation model from block 25 receives as input the data of the planned departure of trains, lists of locomotive crews and locomotives that have been run in these directions and are available to the locomotive depot officer on duty.

In the course of the operation of the block 35 of the inverse simulation model, information about the predicted late start time of the end of formation process is provided. Thus, the forward model gives a forecast of the early start time of the end of the formation of trains, and the reverse model gives the moment of the late start time of the end of the formation. These times are associated with the marshalling yard and exhaust-forming elements at the station.

The block 31 for simulating the composition of the accumulation models the time cutoffs and the corresponding values of the groups of cars arriving on the track of a given direction. If the solution given by this block contradicts the operation of the forward and reverse simulation models, then the correct scenario of the accumulation of cars is sent from the matching block 22 to the block 31.

The blocks 32 for correcting the forward model and 33 for correcting the inverse model operate as follows: based on the readings of the matching block 22, blocks 32 and 33 perform operations to remove the arrival time or departure time of the corresponding trains from the design scenario for the forward or reverse simulation model, or change the order of the release of arrivals or the procedure for supplying the accumulated compositions to the exhaust.

Information about the moments of the beginning of the end of the formation comes from blocks 29 and 35 to the matching block 22, in which the operation of both models is coordinated with each other, with the transfer of information about the agreed work plans to the computer 1 AWS. The calculated work plan, taking into account the control decisions adopted in the block 22 for coordinating, upon changing the order of disbanding trains or changing the direction of departure of a particular train is sent for verification to the data analysis module 27 and then to the self-learning system block 28 through the data generation module 23, which formats the result operation of block 22 for further processing in blocks 27 and 28.

The self-learning system adjusts the parameters of the direct simulation model during the operation of the models.

Thus, in comparison with the prototype, the proposed system for controlling the operation of marshalling yards due to a hybrid control model consisting of forward and reverse simulation models provides enhanced functionality and increases the efficiency of managing marshalling yards.

Claims (1)

A system for hybrid control of the operation of marshalling yards with the function of supporting decision-making on the order of breaking up trains, containing a computer for an automated workstation, including a processor with a data input / output unit connected to it, a monitor, a memory unit and a processing unit and output data generation, the output of which is connected with the second input of the monitor, an additional input / output of the processor is connected to the first output / input of the server, the second output / input of which is connected via the data transmission network to the corresponding inputs / outputs of the hardware and software devices of the automated control system for sorting and freight stations, the automated system for operational management of transportation and an automated dispatch control center, the first and second interface units, while the inputs of the first interface unit are connected to the infrastructure sensors for train approach installed on the tracks of the marshalling yards, and the inputs of the second interface unit connected to the hardware and software devices of the centers for complex diagnostic monitoring of the technical condition of the rolling stock of moving trains, while the third output / input of the server is connected to the input / output of the block for forming process models based on an artificial neural network with a learning function, to which four memory blocks are connected, when In this case, a database of process models is recorded in the first memory block, a database of external technological processes is recorded in the second memory block, a database of technical and administrative acts and schemes is recorded in the third memory block, and a database of event retrospective models of the station's operation is recorded in the fourth memory block, which differs in the following: that a matching unit is introduced into it, the first, second and third outputs of which are connected, respectively, to the input of the processor, to the second input of the processing unit and to generate the output data, and to the first input of the data generation unit for the actual performance of the work connected to the memory unit, in which The torus recorded a database of the actual operation of the station by the clock, and to which the unit for setting the departure point, the data recording unit connected to the output of the infrastructure sensors of the train approach, and the data analysis module, the first input of which is connected to the first output of the processor, the second output of which is connected to the second input of the module for generating data of the actual performance of work, the third input of which is connected to the data recording unit connected to the data transmission network, the first output of the data analysis module through the self-learning system block is connected to the first input of the simulation model block, to the second input of which the output of the intelligent processing unit is connected information about the dissolution approach, connected to the memory unit, in which the database of the real work of the station is recorded by the clock, and the block for simulating the composition of the accumulation is connected to the output of the block of the simulation model, the second input of the data analysis module is connected to the fourth output of the matching block, the fifth and sixth in The outputs of which are connected, respectively, to the input of the direct simulation model correction unit, the output of which is connected to the third input of the simulation model block, and to the input of the inverse simulation model correction unit, the output of which is connected to the accumulation composition simulation block, the input / output of which is connected to the output / input of the matching unit , the block for forming the departure schedule through the block for setting the point of departure is connected to the input of the block of the reverse simulation model, the output of which is connected to the input of the matching block, other inputs of the block of the reverse simulation model are connected, respectively, to the outputs of the block of the self-learning system, the block for forming the schedule for issuing locomotives and the block for forming the turnout schedule locomotive crews connected to a memory unit in which a database of normative and reference information is recorded and to which a departure schedule generation unit and a locomotive delivery schedule generation unit are connected.

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