RU2381126C1 - Operational communication system for low-intensity railway section - Google Patents

Abstract

FIELD: railway transport.

SUBSTANCE: switching hardware is mounted only at railway high-intensity terminals. Note here that switching hardware inputs of interstation communication at stations without switching hardware are connected to wayside station communication hardware and inputs of primary multiplexers. Note also that inputs of primary multiplexers at wayside stations are connected with outputs of subscriber terminals.

EFFECT: simplified system, higher quality and reliability and reduced operating costs.

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Description

The invention relates to the field of automation, communication and computer technology (to info-communications), and in particular to communication systems designed for the operational management of the operational work of railway transport in terms of providing railway traffic on inactive sections.

The principles of construction, structure and organization options for the operational management systems for the operational operation of railway transport are known. Depending on the purpose of the railway stations, the latter are equipped with the equipment of centralized dispatch systems, railway automation, communication and computer systems, automated control systems, computer-based workstations, microprocessors, sensor devices and systems, remotes, telephone, telegraph, fax machines and other equipment [journal "Automation, Communications, Informatics", No. 2, 2006].

The operational-technological communication system (OTC) is used to control the operational work of railway transport, which provides communication between dispatchers of different services and the performers of technological processes located at the railway stations, as well as the performers among themselves.

The OTC system of railway transport is known, organized on the basis of switching equipment, dispatch channels, distillation and inter-station communication, subscriber terminals located at each railway station, and the outputs of the subscriber terminals are connected to the first inputs of the switching equipment, which at each station is connected in parallel with the second inputs to dispatch communication channels, and the third inputs are connected to the distillation and inter-office communications. The disadvantages of this OTC system are its analogue performance, and, as a result, poor communication quality, limited functionality, and also quite expensive technical operation, and the use of this equipment expired in the late 90s [“Automation, communication, informatics”, No. 2, 2006, p. 36; Feasibility study on the development and modernization of communications and radio technology segment of the Ministry of Railways of Russia for 2002 - 2004 Book 3. Calculation of the economic efficiency of investments in the construction of networks of the technological segment of the Moscow railway. for 2004, St. Petersburg, GTSS, 2003, p. 2].

The closest to the claimed OTC system in technical essence is the digital OTC system developed on the basis of specialized digital switching equipment for railway transport in connection with the ongoing reform of Russian Railways, as well as due to the need to replace the old OTS analog equipment that has expired [“Concept building operational-technological communications of Russian railways (OTS Concept), edition 3 ”, approved by the Department of Informatization and Communications of the Ministry of Railways of Russia in 2000].

The digital OTC system contains equipment at each railway station, which includes a primary multiplexer, switching equipment, dispatch channels, inter-station and distillation communications, terminal equipment of users, and the outputs of the terminals are connected to the first inputs of the switching equipment, the second inputs of which are connected to the first outputs primary multiplexers, each of which is connected to the first inputs of the adjacent multiplexer along the second outputs, and the switching I equipment at each station connected to interoffice and distillation bonds with similar switching equipment adjacent station.

The disadvantages of the above OTS should be attributed to the complexity of the system due to equipping all stations of an inactive railway section with a full set of OTS equipment and the costly nature of such equipment.

The essence of the claimed invention is a new technology for organizing the OTC system, in which only the stations with the most intensive operational work are equipped with equipment in a complete set, and the switching equipment is not installed at other stations.

The claimed technical solution for the organization and equipping with OTs of inactive sections of railways, in addition to simplifying the system, improving the quality of service, reliable operation and lowering operating costs, also provides cost savings in the implementation of equipment technology.

The technical result is achieved by the fact that the system of operational-technological communication of an inactive section of the railway transport, containing subscriber terminals installed at the stations, according to the invention is equipped with primary multiplexers, dispatch communication channels, distillation communication, inter-office communication and installed only at stations with the most intensive operational work of switching equipment connected to subscriber terminals installed at its station and flow E1 from the primary a multiplexer connected along the E1 stream with primary multiplexers located at stations that are not equipped with switching equipment, while each of the multiplexers is connected by an E1 stream to its adjacent multiplexer with the formation of a chain between the multiplexers, and to multiplexers installed at stations without switching equipment, subscriber terminals and lines of distillation and inter-station communication are connected.

The drawing shows a block diagram of the organization of the technological communication system of an inactive section of the railway, which includes the primary multiplexers 1, switching equipment 2, organized in the stream E1 between the primary multiplexers 1 dispatch channels 3 and connecting lines between stations 1-2 and 1-3 terminals of 4 subscribers participating in operational work. The inputs and outputs of the multiplexers 1 indicated in the drawing are conditional concepts that apply only to the scheme and elements of the OTC organization system, namely, the direction of information transfer - “from left to right”, with the opposite direction “from right to left” - the role of inputs and outputs is functional for multiplexers change, but on the structure of the system and on the diagram, this change is not reflected.

The system operates as follows.

The dispatchers of various services of Russian Railways, using OTC facilities, have the ability to quickly and in real time interact with the process workers located at the railway stations, as well as the workers among themselves.

The duty dispatcher m of an administrative station (for example, road control) via dispatch channels 3 organized in stream E1, using terminal 4, calls the subscriber at the desired station (station 1, and / or 2, and / or 3, ... and / or N ) A call signal from the second output of the primary multiplexer 1 of the control station via dispatch channels 3 through the chain Station 1 - Station 2 comes to the input 1 of the multiplexer 1 of station 2 and to the output 1 is fed to the second input of the switching equipment 2, which commutes with the terminal 4 of the called subscriber station 2, and / or with a terminal 4 of a subscriber of a station that does not have its switching equipment in the E1 stream in an unoccupied (free) channel interval of that primary multiplexer 1 to which directly connects terminal 4 of the called subscriber manager.

When the dispatcher calls the executors who are subscribers of the distillation connection, the call signal on the connecting lines in the E1 stream comes through the chain Station 1 - Station 2 to the input 1 of the multiplexer 1 of station 2 and to the output 1 is fed to the second input of the switching equipment 2, which performs switching directly from subscribers of inter-station or distillation communications connected at the third input.

If necessary, on the initiative of subscribers, the connection with the road control manager m, the organization of communication and the passage of the call signal occurs in the reverse order. The call signal from the terminal equipment 4 of the subscriber located at the station with the most intensive work arrives at the corresponding first input of the switching station 2, which in the E1 stream, together with the primary multiplexer 1, provides connection to the corresponding dispatch communication channel 3, after which the call signal passes through the multiplexers 1 along the chain Station 2 - Station 1 - A control station at the entrance of terminal 4 of the road control dispatcher m. A call signal from a terminal 4 of a subscriber located at a station not equipped with switching equipment 2 (for example, at station 3) arrives at the corresponding third input of the primary multiplexer 1, then passes through the multiplexer 1 of Station 2 from the first output to the second input in stream E1 switching equipment 2, after which the latter, together with the primary multiplexer 1 of Station 2, connects it to the corresponding channel of dispatch communication 3, which provides communication through multiplexers 1 along the chain Station 2 - Station 1 - It will be ordered Station with terminal 4 of dispatcher m.

If it is necessary to connect subscribers to each other, the following situations are possible:

- connection of subscribers of "their" station;

- connection of subscribers of different stations.

The connection of subscribers of “their own” station is divided into two types: the connection of subscribers of the station with switching equipment 2 (Station 2) and the connection of subscribers of stations that do not have switching equipment 2 (Stations 1, 3, ..., N). When connecting subscribers of the first type, communication is provided only by the switching equipment 2, which directly connects the terminals 4 of subscribers 1, 2, ... n ₂ . The connection of the subscribers of the second type, that is, subscribers of stations that do not have switching equipment 2, occurs according to the following scheme. For example, a call from subscriber 1 to subscriber 2 at Station 3 passes to the corresponding third input of the primary multiplexer 1 of Station 3, arrives at the primary multiplexer 1 of Station 2, in flow E1 it arrives at the switching equipment 2, which provides its switching to the primary multiplexer 1 of Station 3 then the call signal in the E1 stream passes through the primary multiplexer 1 of Station 2, the primary multiplexer 1 of Station 3 to the input of terminal 4 of subscriber 2.

Thus, the connection of duty dispatchers with subscribers, subscribers of the station with the most intensive operational work among themselves and subscribers of stations without switching equipment with the dispatcher and with each other is carried out only on the basis of switching equipment 2.

OTS equipment installed on low-railway sections is produced in a modular version with the same basic configuration, the difference is in the implementation of the corresponding subscriber modules for terminal equipment for specific users. It should be noted that the terminals 4 of the subscribers are connected to the switching equipment 2 and to the primary multiplexers 1 only through the so-called linear sets (not shown in the drawing).

Cost-effectiveness assessment

Cost savings are achieved due to the fact that switching equipment 2 is not installed at several stations, and the subscribers of these stations are connected to technological communication through the use of linear sets (pairing equipment), the cost of which is significantly lower than the cost of switching equipment 2.

Let ΔZ be the savings from the fact that switching equipment (SC) is not installed at several stations n _{SC of the} railway section; Z _LK-ASG - the cost of purchasing one linear set - a submodule for transit of the ASG line; Z _{Submodule E1} - the cost of buying a submodule of the E1 interface installed in multiplexer 1 at a station with switching equipment 2. Then analytical expression (1) can be represented as a mathematical model for estimating the amount of savings:

According to the specification, for example, of the Pulsar NPL equipment, the cost savings when equipping a site with communication equipment is about 143,000 rubles.

Claims (1)

The system of operational-technological communication of an inactive section of the railway transport, containing subscriber terminals installed at the stations, characterized in that it is equipped with primary multiplexers, dispatch channels, distillation communication, inter-office communication, and switching equipment installed only at stations with the most intensive operational work connected to subscriber terminals installed at their station and along the E1 stream with a primary multiplexer connected by sweat E1 with primary multiplexers located at stations that are not equipped with switching equipment, each of the multiplexers being connected by an E1 stream to its adjacent multiplexer to form a chain between the multiplexers, and subscriber terminals and lines are connected to the multiplexers installed on stations without switching equipment distillation and inter-station communication.