RU2456747C1 - Multi-level distributed optic fibre communication system - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: system is developed, in which in case of various development of emergency situations in the field, resulting in disturbed communication, communication is automatically recovered between technological objects of the lower level of the system hierarchy, and also an automatic changeover is carried out to reserve radial and reserve circular optic fibre communication systems (OFCS), which does not result in loss of communication between system objects, at the same the system provides for the possibility to arrange control of field equipment, both from the main node station and from a control node station, and also from any of the node stations. In the system faulty communication lines are identified, on the basis of which failed OFCS are repaired. The multi-level distributed OFCS provides for reliable uninterrupted high-speed control of process equipment and meets requirements of safety for hazardous technological processes of gas-condensate mixture production and transportation for its processing.

EFFECT: development of a reliable multi-level distributed optic fibre communication system.

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Description

The invention relates to multi-level distributed fiber-optic communication systems designed for automated control systems of hazardous technological facilities for the production and transportation of gas condensate media.

The invention is known to patent 2138134 (application 96109377/09, 10/11/1994). A distributed switching communication system in which each delivery unit receives wireless information from a plurality of radio frequency transceivers.

This invention cannot be applied to the automation of explosive chemical and petrochemical industries. The automatic quick-acting locking or cutting devices used for these industries have a response time of no better than 12 s, and the data update period from wireless sensors is no better than 15 s, while the total response delay is no better than 27 s, which is not permissible for process units I explosion hazard category, as it leads to the risk of emissions of combustible and explosive substances into the environment during emergency depressurization of process units.

Known radial radio communication system with a central unit (Reference. "Industrial radio communication systems. G.Myaskovsky. / Edited by I.M. Pyshkina. Moscow: Communication, 1980, p.14), the disadvantage of which is low noise immunity, since Radiocommunication facilities are significantly susceptible to electromagnetic interference, and when using a radial structure when the central unit fails, it completely destroys the interaction of other units.

Known patent for utility model 52293 (application 2005133884/22, 02/11/2005). Distributed multiservice telecommunication system consisting of routers, blocks of digital multiplexers with optoelectronic transceivers connected via individual fiber-optic lines to a fiber-optic communication line based on a multicore fiber optic cable. However, this device has low communication reliability for hazardous production processes, since when the multicore fiber cable is destroyed, the transmission of control signals and reception of information on the status of technological equipment completely ceases, which leads to uncontrolled production processes and the development of an emergency in a gas condensate field.

Known patent for utility model 78617 (application 2008130207/22, 07/21/2008, H04M 9/08). An automated communication system comprising switching centers interconnected in series by fiber-optic communication lines, as well as transmitting and receiving units of the radio complex equipment.

However, in this device for the organization of communication, radio complexes are used that have low noise immunity, which does not allow their use in automated process control systems of hazardous industries, especially in emergency process protection systems.

Known patent for the invention 2395167 (application 2007139169/09, 10/22/2007, H04L 12/00). A universal telecommunication network containing data transmission and reception equipment connected by ring and linear communication lines, made in the form of a multi-level hierarchical system, as well as a central headend station of modular design with satellite and terrestrial antennas.

However, this network, as well as an automated communication system (patent for utility model 78617, application 2008130207/22, 07/21/2007) also uses radio complexes, has low noise immunity, which reduces the reliability of the emergency protection systems, and a long delay time, which is unacceptable for use in automated process control systems of hazardous industries.

The invention is known for patent 2304349 (application 2005121611/09, 08.07.2005). A multifunctional system of intra-ship communication, consisting of switching centers and a central switching unit, interconnected by sequentially duplicated ring fiber-optic communication lines. However, duplicated communication lines have low reliability and are not applicable for the automation of gas condensate fields, so in emergency situations at wells and gas treatment plants, there is a high probability of destruction of the main and duplicated ring fiber-optic communication lines in this device and the inability to act on shut-off organs to prevent development emergency situation.

The closest in technical essence and the achieved positive effect is the invention to patent 2255429 (application 2003137683/09, 12/29/2003). A distributed communication system with packet switching for fixed and fixed subscribers, containing nodal stations located in places with a higher density of communication stations, moreover, the communication stations are connected by fiber-optic communication lines into rings of the lower hierarchy, each of which is connected with its inputs and outputs to to the corresponding nodal stations, the main nodal station associated with each nodal station by working radial fiber-optic communication lines.

However, the known device has low reliability of communication, since in real operating conditions for gas condensate fields, failure of the ring of the lower hierarchy leads to the shutdown of a large number of communication stations (wells), the inability to remotely automatically control this large group of wells and create an emergency in the field . In addition, the disruption of radial communication also leads to the shutdown of a large number of communication stations (wells), the inability to remotely automatically control this large group of wells, which also creates an emergency in the field.

The aim of the invention is to increase the reliability of a multi-level distributed fiber-optic communication system.

The technical result of the invention is to create a reliable multi-level distributed fiber-optic communication system that meets the requirements for the safe operation of hazardous production processes, in particular gas condensate fields.

This goal is achieved by the fact that in a multi-level distributed fiber-optic communication system containing node stations located in places with a higher density of communication stations, the main node station connected to each node by working radial fiber-optic communication lines, and the communication stations are connected sequentially by fiber-optic communication lines, forming a lot of serial circuits, a control nodal station is additionally introduced, stations and end stations, while the control nodal station is connected to the main nodal station by a working fiber-optic communication line, the nodal stations are interconnected by redundant fiber-optic communication lines, forming a ring of the top hierarchy, the control nodal station is connected to each nodal station by reserve radial fiber-optic communication lines, and each headend and each end station are connected by their first inputs with fiber-optic communication lines to the corresponding serial communication stations, and the second inputs are connected by fiber-optic communication lines to the corresponding nodal station, forming rings of the lower hierarchy, while the control nodal station and the main nodal station are geographically separated, and the headends and end stations are territorially combined with the corresponding nodal station, wherein each headend contains a test signal generator of the corresponding ring of the lower level of the hierarchy, as well as a segment of fiber optic communication lines connected respectively to the first and second inputs of the headend and connected to the output of the test signal generator of the corresponding ring of the lower hierarchy, and each end station contains a block for receiving the test signal of the corresponding ring of the lower hierarchy, as well as an electron-optical key connected by its first and second inputs by means of segments of fiber-optic communication lines, respectively, to the first and second inputs of the end station, while the control input is electron-optical the key is connected to the output of the test signal receiving unit of the corresponding ring of the lower level of the hierarchy, the input of which is connected to a piece of fiber-optic communication line connected respectively to the first input of the end station and to the first input of the electron-optical key, with each node station containing a receiving unit test signal, a unit for generating a response test signal, a unit for receiving control commands for redundant lines, a matrix of priorities for enabling redundant lines, and a unit for enabling redundant lines, the first and second outputs of the test signal receiving unit are connected respectively to the input of the response test signal generating unit and the first input of the priority line switching priority matrix, the second input of which is connected to the output of the backup line control command receiving unit, and the output is connected to the input of the reserve line switching unit wherein the input of the test signal receiving unit, the output of the response test signal generating unit, the output of the power line enable unit, and the input of the reserve control command receiving unit connected to the corresponding interface bus connected to the inputs of the corresponding nodal stations, respectively connected to the first inputs of the backup radial fiber-optic communication lines, to the first inputs of the working radial fiber-optic communication lines and to the backup fiber-optic communication lines connecting nodal stations, while the main nodal station contains the first generator of the test signal of the upper level of the hierarchy, a block for receiving response test signals, an identification block a faulty working line, as well as a block of control commands for redundant lines, while a block for receiving response test signals, an identification block for a faulty working line, and also a block of commands for control of redundant lines are connected in series, and the output of the first test signal generator of the upper hierarchy level, the input of the block for receiving response test signals, as well as the output of the backup line command block, are connected to the interface bus connected to the inputs of the main node station, respectively connected to the second the inputs of the working radial fiber-optic communication lines and to the first input of the working fiber-optic communication line, while the control nodal station contains a second generator of the test signal of the top level of the hierarchy, a block for receiving commands for controlling redundant radial fiber-optic communication lines, a matrix of priorities for enabling redundant radial fiber-optic communication lines, as well as a unit for switching on standby radial fiber-optic communication lines, while the unit for receiving control commands for backup radio fiber optic communication lines, the priority matrix for turning on the backup radial fiber-optic communication lines, as well as the switching-on unit for the backup radial fiber-optic communication lines are connected in series, and the output of the second test signal generator of the top level of the hierarchy, the input of the receiving unit for receiving commands for controlling the backup radial fiber - optical communication lines, as well as the output of the unit for switching on the backup radial fiber-optic communication lines are connected to the corresponding interface bus, connected to the inputs of the control nodal station, respectively connected to the second input of the working fiber-optic communication line and to the second inputs of the standby radial fiber-optic communication lines, each nodal station, the main nodal station, and the control nodal station contain a satellite signal receiving unit exact time, each of which is associated with a corresponding interface bus.

Figure 1 presents the structural diagram of a multi-level distributed fiber-optic communication system.

Figure 2 presents a structural diagram of the lower level of the hierarchy of a multi-level distributed fiber-optic communication system.

Figure 3 presents a structural diagram of the upper level of the hierarchy of a multi-level distributed fiber-optic communication system.

In Fig.4 ... Fig.6 shows the priority matrix enable the backup lines 25 of the node stations 1-1 ... 1-3.

In Fig.7 ... Fig.9 shows the priority matrix for the inclusion of backup lines 25 of the node stations 1-4 ... 1-6.

Figure 10 shows the priority matrix for the inclusion of backup radial FOCL 35 control nodal station 5.

In Fig.11, Fig.12 and Fig.13 shows the inclusion of redundant lines in case of failure of the working radial FOCL 4.1 ... 4.3.

A description of a multi-level distributed fiber-optic communication system is given, for example, for six junction stations as applied to the Astrakhan gas condensate field, and another number of junction stations is also possible.

1. A multi-level distributed fiber-optic communication system containing node stations 1-1 ... 1-6 located in places with a higher density of communication stations 2, the main node station 3 connected to each node station 1-1 ... 1-6 by workers radial fiber-optic communication lines 4.1 ... 4.6, moreover, the communication stations 2 are connected in series by fiber-optic communication lines, forming a number of serial circuits, characterized in that a control node station is additionally introduced into the system 5, headend stations 6 and end stations 7, while the control node station 5 is connected to the main node station 3 with a working fiber-optic communication line 8, the node stations 1-1 ... 1-6 are interconnected by redundant fiber-optic communication lines 9.1 ... 9.6, forming a ring of the upper level of the hierarchy, the control nodal station 5 is connected to each nodal station 1-1 ... 1-6 by backup radial fiber-optic communication lines 10.1 ... 10.6, and each headend 6 and each end station 7 are connected with their first inputs fiber -opt personal communication lines to the corresponding communication stations of the serial circuit, and the second inputs are connected by fiber-optic communication lines to the corresponding nodal station 1-1 ... 1-6, forming rings of the lower hierarchy level, while the control nodal station 5 and the main nodal station 3 are geographically separated and the head stations 6 and end stations 7 are geographically integrated with the corresponding nodal station 1-1 ... 1-6.

2. The multi-level distributed fiber-optic communication system according to claim 1 is characterized in that each headend 6 contains a test signal generator of the corresponding ring of the lower level of the hierarchy 11, as well as a piece of fiber-optic communication line connected to the first 12 and second 13 inputs, respectively head station 6 and associated with the output of the test signal generator of the corresponding ring of the lower level of the hierarchy 11, and each end station 7 contains a block for receiving a test signal of the corresponding ring of the lower level above the hierarchy, as well as the electron-optical key 15 connected by its first 16 and second 17 inputs via segments of fiber-optic communication lines 18 and 19, respectively, to the first 20 and second 21 inputs of the end station 7, while the control input of the electron-optical key 15 connected to the output of the test signal receiving unit of the corresponding ring of the lower level of the hierarchy 14, the input of which is connected to a piece of fiber-optic communication line 18 connected respectively to the first input 20 of the end station 7 and to the first input 16 of the electronic o-optical key 15.

3. The multi-level distributed fiber-optic communication system according to claim 2 is characterized in that each node station contains a block for receiving a test signal 22, a block for generating a response test signal 23, a block for receiving commands for managing backup lines 24, a priority matrix for switching on backup lines 25, and also a backup line enable unit 26, wherein the first and second outputs of the test signal receiving unit 22 are connected respectively to the input of the response test signal generating unit 23 and the first input of the priority matrix is turned on I have backup lines 25, the second input of which is connected to the output of the receiving unit for command control of the backup lines 24, and the output is connected to the input of the switching unit of the backup lines 26, while the input of the receiving unit of the test signal 22, the output of the unit for generating the response test signal 23, the output of the switching unit redundant lines 26, as well as the input of the unit for receiving control commands for redundant lines 24 are connected to the corresponding interface bus 27 connected to the inputs 1-1-3 ... 1-6-3, 1-1-1 ... 1-6-1, 1- 1-2 ... 1-6-2 and 1-1-4 ... 1-6-4 of the corresponding nodal stations 1-1 ... 1-6, connected respectively to the first inputs of the standby radial fiber-optic communication lines 10.1 ... 10.6, to the first inputs of the working radial fiber-optic communication lines 4.1 ... 4.6 and to the reserve fiber-optic communication lines 9.1 ... 9.6, connecting interconnected stations 1-1 ... 1 -6.

4. The multi-level distributed fiber-optic communication system according to claim 3 is characterized in that the main node station 3 comprises a first hierarchical test signal generator 28, a response test signal receiving unit 28, a faulty working line identification unit 30, and a control command block backup lines 31, while the block receiving response test signals 29, the identification unit of the faulty working line 30, as well as the command block control backup lines 31 are connected in series, and the output of the first generator test signal of the top level of the hierarchy 28, the input of the block for receiving response test signals 29, as well as the output of the command block of the backup line control 31 are connected to the interface bus 32 connected to the inputs 3.1 ... 3.7 of the main node station 3, respectively connected to the second inputs of the working radial fiber optical communication lines 4.1 ... 4.6 and to the first input of the working fiber-optic communication line 8.

5. The multi-level distributed fiber-optic communication system according to claim 4 is characterized in that the control nodal station 5 contains a second generator of a test signal of the top level of the hierarchy 33, a block for receiving commands to control redundant radial fiber-optic communication lines 34, and a priority matrix for enabling redundant radial fiber optical communication lines 35, as well as a unit for switching on standby radial fiber-optic communication lines 36, while the unit for receiving control commands for standby radial fiber-optic and communication lines 34, the priority matrix for turning on the backup radial fiber-optic communication lines 35, as well as the switching-on unit for the backup radial fiber-optic communication lines 36 are connected in series, and the output of the second test signal generator of the top level of the hierarchy 33, the input of the receiving unit for receiving control commands for the backup radial fiber-optic communication lines 34, as well as the output of the block enable redundant radial fiber-optic communication lines 36 are connected to the corresponding interface bus 37 associated with the inputs 5.7, 5.1, 5.2, 5.3, 5.4, 5.5 and 5.6 of the control gateway 5 connected respectively to the second input working fiber-optic communication line 8 and to the second inputs of redundant radial fiber-optic communication lines 10.1 ... 10.6.

6. The multilevel distributed fiber-optic communication system according to claim 5 is characterized in that each node station 1-1 ... 1-6, the main node station 3, as well as the control node station 5 contain a unit for receiving satellite signals of exact time 38, each which is connected to the corresponding interface bus.

The system operates as follows.

N serial circuits of communication stations 2, for example, wells of a gas condensate field, each of which contains a head station 6 and an end station 7 connected to the corresponding nodal station 1-1 ... 1-6, are connected to the junction stations 1-1 ... 1-6, forming the lower rings hierarchy level from one to N (1 ... N). The number of communication stations 2 in each ring of the lower hierarchy level 1 ... N can fluctuate and reach dozens of wells. The number of rings of the lower level of the hierarchy connected to each node station can reach dozens of rings.

The length of the rings of the lower level of the hierarchy and the distance between the nodal stations can reach tens of kilometers.

Each communication station 2 contains, for example, a local automated control system for the technological process of the well - automated process control systems of the lower hierarchy, the input and output technological parameters of which are transmitted via fiber-optic communication lines to the corresponding nodal station 1-1 ... 1-6. For example, an automated process control system for the corresponding nodal station 1-1 ... 1-6 is connected to each node station; an automated process control system of the upper hierarchy level, which automatically controls the process of preparing gas-liquid flows from communication stations 2 — wells included in the corresponding rings of the lower hierarchy level of a multilevel distributed fiber optic communication system. Flows from wells are combined and transported through a main pipeline for processing. The control and management of these flows is carried out, for example, from the industrial control system of this level, connected to the main node station 3 and the control node station 5.

Communication between objects in a multi-level distributed fiber-optic communication system is based on the Ethernet standard.

In the initial state, when the serial connection of the communication stations 2 is not broken, the test signal containing the identification code of the corresponding ring of the lower level of the hierarchy from the generator 11 is connected, for example, using an electro-optical converter with a piece of fiber-optic communication line connected respectively to the first 12 and second 13 inputs of the head station 6, through series-connected communication stations 2, the first input 20 of the end station 7, a section of fiber optic link 18, associated with it, for example, the tiko-electronic converter is fed to the input of the test signal receiving unit 14, the signal from the output of which is fed to the input of the electron-optical key, holds it off and the technological information is exchanged between the corresponding nodal station 1-1 ... 1-6 and serial communication stations 2 is carried out through the headend 6.

If one of the fiber-optic transceiver connecting adjacent communication stations 2 is cut off, there is no test signal at the input of the test signal receiving unit 14, and the electron-optical key 15 is turned on, while the first input 20 is connected to the second input 21 of the end station 7. In this In this case, the ring breaks into two serial chains of communication stations, one of which continues to exchange information of communication stations 2 with the node station 1 through the headend 6, and the second carries out the exchange of information with the corresponding nodal station 1-1 ... 1-6 through a fiber-optic communication line of the end station 7 closed with the aid of an electronic-optical key 15, while the territorial association of the headend 6 and the end station 7 with the corresponding nodal station 1-1 ... 1-6 provides reliable backup of information exchange in the event of a breakdown of any FOCL connecting adjacent communication stations without resorting to a duplicated FOCL between communication stations 2, which at large distances between communication stations 2 allows GOVERNMENTAL reduce the length of fiber optic links connecting two communication stations.

For example, the corresponding automated process control system is connected to the main nodal station 3 and the control nodal station 5, such as an automated process control system at the level of dispatching multilevel distributed fiber-optic communication systems that automatically control the process of combining gas-liquid flows from nodal stations 1-1 ... 1- 6 into several main streams for transporting them for processing.

Coordination of the operation of nodal stations 1-1 ... 1-6 in order to ensure the supply of a stable amount of raw materials for processing is carried out from the main nodal station 3 by working radial FOCLs 4.1, 4.2, 4.3 4.4, 4.5 and 4.6.

In working condition, when the working radial FOCLs are not violated, a test signal containing the identification code of the main node station 3 from the first generator of the test signal of the upper hierarchy level 28 via the interface bus 32 and connected to this bus, for example, a transceiver electron-optical converter, arrives at the inputs 3.1, 3.2, 3.3, 3.4, 3.5 and 3.6 of the main node station 3. This signal is received from the working radial FOCLs 4.1, 4.2, 4.3, 4.4, 4.5 and 4.6. arrives at the inputs 1-1-1, 1-2-1, 1-3-1, 1-4-1, 1-5-1 and 1-6-1, and then on the interface bus 27, in each node station 1-1 ... 1-6, is fed to the input of the test signal receiving unit 22, which starts the response test signal generating unit 23, while the test signal keeps the priority matrix of turning on the backup lines 25 off, and the output of the blocks 26 does not have a turning on signal lines of the corresponding nodal station 1-1 ... 1-6.

The response test signals of the nodal stations contain the identification code of the corresponding nodal station 1-1 ... 1-6 and from the output of the block 23 through the interface bus 27 they arrive via the working radial FOCLs 4.1, 4.2, 4.3 4.4, 4.5 and 4.6 to the corresponding inputs of the main nodal station 3 and then through the interface bus 32 to the input of the block receiving response test signals 29, which is connected in series with the identification block of the faulty working line 30, as well as with the command block control of the backup lines 31.

The identification block of a faulty working line 30 contains, for example, a memory block of identification codes of nodal stations 1-1 ... 1-6, an identification code of the main nodal station 3, as well as an identification code of the control nodal station 5, whose codes are compared with the codes of the response test signals and there are response test signals from all six nodal stations 1-1 ... 1-6 at the output of block 31 there are no backup line control commands, while at the input of blocks 24 of each nodal station 1-1 ... 1-6 and the input of the block receiving control commands The equal radial FOCLs of 34 control node stations 5 also lack backup line control commands, the priority matrix for switching on the backup lines 25 of the corresponding node stations 1-1 ... 1-6, and the priority matrixes for turning on the backup radial fiber optic link 35 of the control node stations 5 are turned off, and at the output of blocks 26 nodal stations, as well as block 36 of the control nodal station 5 there are no commands to turn on the backup FOCL.

In the event of an accident, for example, when the working radial FOCL 4.1 is interrupted, the test signal from the first generator of the test signal of the upper hierarchy level 28 via the interface bus 32 and connected to this bus, the electron-optical converter enters the inputs 3.1, 3.2, 3.3, 3.4, 3.5 and 3.6 of the main nodal station 3. Further, this signal for working radial FOCLs 4.2, 4.3, 4.4, 4.5 and 4.6, inputs 1-2-1, 1-3-1, 1-4-1, 1-5-1 and 1-6- 1, interface buses 27, the input of the test signal receiving unit 22 starts the unit for generating the response test signal 22 only of the nodal stations 1-2, 1-3, 1-4, 1-5 and 1-6, while and at the output of block 23 of the nodal station 1-1, there is no response test signal.

In the absence of a response test signal from the nodal station 1-1, in block 30 of the main nodal station 3, this faulty working radial fiber optic link is identified and backup line control commands are generated at the output of block 31, which through blocks 24 of the corresponding nodal stations 1-2 ... 1- 6, and also block 34 of the control nodal station 5 is fed to the input of the corresponding priority matrices for switching on the backup lines of 25 nodal stations 1-2 ... 1-6 and to the input of the priority matrices for switching on the backup radial FOCLs 35 of the control nodal station 5.

The lack of a backup line control command at the input of block 24 and at the output of block 22 puts the priority matrix for turning on the backup lines 25 of the nodal station 1-1 to the automatic switching mode, for example, a clock generator that controls the operation of the shift register that is connected in series in the nodal station 1-1 input 1-1-3 to the backup radial FOCL 10.1, input 1-1-4 to the backup FOCL 9.1 and input 1-1-2 to the backup FOCL 9.6.

The clock is synchronized from the satellite system 38 and operates in real time.

At the same time, by commands from block 31 of the main nodal station 3, the input 5.1 is connected to the backup radial FOCL 10.1 and, if it is working, the signal from the second generator of the test signal of the top hierarchy 33 through the interface bus 37 of the control node 5, FOCL 10.1, interface bus 27 the nodal station 1-11 enters the input of the test signal receiving unit 22, and a response test signal is generated at the output of the block 23. In block 30 of the main nodal station 3, the restoration of communication with the nodal station 1-1 is identified and in block 31 the corresponding control commands are generated that stop the matrix 25 in the nodal station 1-1 in the state when the input 1-1-3 of the nodal station 1-1 connected to the first input of a working backup radial FOCL 10.1, and stop the matrix 35 in the control nodal station 5 in a state when the input 5.1 of the monitoring nodal station 1-5 is connected to the second input of a working backup radial FOCL 10.1.

In the case of a standby radial FOCL 10.1 that is faulty for some reason, the search for a workable standby line continues, while the priority matrix for switching on standby lines 25 of node 1-1 goes to the next clock, in which input 1-1-4 in node 1-1 it is connected to the backup FOCL 9.1, and upon command from block 31 through the working radial FOCL, the matrix 25 of the 1-2 nodal station connects the backup FOCL 9.1 to the input 1-2-1 of the nodal station 1-2 through the backup line 26 switching unit.

In the case of a backup radial fiber-optic fiber optic line 9.1 that is faulty for any reason, the search for a working backup line continues, while the priority matrix for switching on the backup lines 25 of the junction 1-1 goes to the next clock, in which the input 1-1-2 in the junction 1-1 it is connected to the backup FOCL 9.6, and upon a command from the command unit for managing the backup lines 31 via the working radial FOCL 4.6, the matrix 25 of the nodal station 1-6 connects the backup FOCL 9.6 to the input 1-6-4 of the nodal station 1-6 , while the main nodes I'm station 3 and a control gateway geographically separated and are a few kilometers away, which significantly reduces the likelihood of emergencies during the simultaneous failure of the operating radial fiber optic 4.1 4.6 ... and stand-radial fiber optic 10.1 ... 10.6, which also increases the reliability of the system.

The priority matrix for the inclusion of backup lines 25 of the node stations and the priority matrix for the inclusion of backup radial FOCLs 35 are synchronized from the satellite system 38 and operate in real time, which provides high speed search and recovery of failed FOCLs.

Similarly, the system works in case of failure of the working radial fiber optic links 4.2, 4.3, 4.4, 4.5 and 4.6.

The second test signal generator of the top level of the hierarchy 34 contains the identification code of the control nodal station 5, which, when one of the backup radial FOCLs 10.1 ... 10.6 is connected, enters the test signal receiving unit 22 and the identification code of the control nodal station 5 is generated in the response test signal of the corresponding node station, indicating that the exchange of information is carried out on the corresponding backup FOCL.

There are other possible scenarios for the development of emergency situations in the field, which also will not lead to a loss of communication between the objects of the system, while the system provides the possibility of organizing the management of field equipment both from the main node station and from the control node station, as well as from any of the node stations .

The state of the FOCL identified in block 30 of the main node station 3 is stored, for example, in the memory block of the main node station, to which, for example, an automated workstation of the operator is connected. The operator, on the basis of information on the state of the fiber-optic communication lines of the system, issues tasks for the repair of failed fiber optic links.

Thus, a multi-level distributed fiber-optic communication system provides reliable uninterrupted, high-speed control of technological equipment and meets the safety requirements for hazardous technological processes of production and transportation of gas condensate mixture for its processing.

In a multi-level distributed fiber-optic communication system, the main node station and the control node station can be performed on Alcatel's OmniSwitch 7000 series Ethernet switches, node stations can be made using Hirschmann 4000 series MACN Ethernet switches, headend stations and ring end stations hierarchies can be performed using RS20 Ethernet switches with the corresponding Hirschmann software, Eth is used as communication stations ernet switches are MS20 manufactured by Hirschmann, and communication lines can be implemented using Corning ADSS fiber optic cable of the A-D (T) 2Y E9 / 125 brand. Quantum programmable logic controllers (PLCs) from Schneider Electric and computer equipment (servers and workstations) from SUN Microsystems, with appropriate software, can be used in the system as software and hardware tools for monitoring and controlling the process.

Claims (6)

1. A multilevel distributed fiber-optic communication system containing node stations located in places with a higher density of communication stations, a main node station connected to each node by working radial fiber-optic communication lines, the communication stations being connected in series by fiber-optic lines communication, forming a lot of serial circuits, characterized in that the control node station, headends are additionally introduced into the system and end stations, while the control node station is connected to the main node station with a working fiber-optic communication line, the node stations are interconnected by redundant fiber-optic communication lines, forming a ring of the top hierarchy, the control node station is connected to each node by the backup radial fiber-optic communication lines, and each headend and each end station are connected by their first inputs with fiber-optic communication lines to the corresponding comm Discount stations series circuit and second inputs connected to optical fiber communication lines to the corresponding gateway, forming the lower level ring hierarchy, the control gateway and home gateway geographically spaced, and head stations and end stations geographically combined with a corresponding gateway. 2. The multilevel distributed fiber-optic communication system according to claim 1, characterized in that each headend contains a test signal generator of the corresponding ring of the lower level of the hierarchy, as well as a piece of fiber-optic communication line connected respectively to the first and second inputs of the headend and associated with the output of the test signal generator of the corresponding ring of the lower level of the hierarchy, and each end station contains a unit for receiving a test signal of the corresponding ring of the lower level of the hierarchy archies, as well as an electron-optical key connected by its first and second inputs via segments of fiber-optic communication lines to the first and second inputs of the end station, respectively, while the control input of the electron-optical key is connected to the output of the test signal receiving unit of the corresponding lower-level ring hierarchy, the input of which is connected with a piece of fiber-optic communication line connected respectively to the first input of the terminal station and to the first input of the electron-optical key. 3. The multi-level distributed fiber-optic communication system according to claim 2, characterized in that each node station contains a test signal receiving unit, a response test signal generating unit, a standby line command receiving unit, a standby line enable priority matrix, and an enable unit backup lines, while the first and second outputs of the test signal receiving unit are connected respectively to the input of the response test signal generating unit and the first input of the priority enable matrix lines, the second input of which is connected to the output of the standby line control command receiving unit, and the output is connected to the input of the standby line enable unit, the input of the test signal receiving unit, the output of the response test signal generating unit, the output of the standby line enable unit, and the input the backup line command receiving unit is connected to the corresponding interface bus connected to the inputs of the corresponding nodal stations connected respectively to the first inputs of the backup radial fiber optic iCal communication lines, to the first inputs of the radial working optical fiber communication lines and the backup optical fiber communication lines interconnecting the node stations. 4. The multi-level distributed fiber-optic communication system according to claim 3, characterized in that the main node station contains a first generator of a test signal of the top level of the hierarchy, a unit for receiving response test signals, an identifier for identifying a faulty working line, and also a unit for command control of the backup lines, at the same time, the block for receiving response test signals, the unit for identifying the faulty working line, as well as the block of commands for controlling the backup lines are connected in series, and the output of the first test generator with drove the top level of the hierarchy, the input of the block for receiving response test signals, as well as the output of the block of commands for controlling the backup lines are connected to the interface bus connected to the inputs of the main node station, respectively connected to the second inputs of the working radial fiber-optic communication lines and to the first input of the working fiber optical line of communication. 5. The multi-level distributed fiber-optic communication system according to claim 4, characterized in that the control node station contains a second generator of a test signal of the top level of the hierarchy, a unit for receiving commands to control redundant radial fiber-optic communication lines, a priority matrix for enabling redundant radial fiber-optic communication communication lines, as well as a unit for enabling redundant radial fiber-optic communication lines, while a unit for receiving commands for controlling redundant radial fiber-optic lines communications, the priority matrix for turning on the backup radial fiber-optic communication lines, as well as the switching-on block for the backup radial fiber-optic communication lines, are connected in series, and the output of the second test signal generator of the upper hierarchy level, the input of the command receiving unit for controlling the backup radial fiber-optic communication lines as well as the output of the backup radial fiber-optic communication lines switching unit are connected to the corresponding interface bus connected to the inputs of the control unit oic station connected respectively to the second input working fiber-optic communication line and to the second inputs of redundant radial fiber-optic communication lines. 6. The multilevel distributed fiber-optic communication system according to claim 5, characterized in that each node station, the main node station, and the control node station contain an exact time satellite signal receiving unit, each of which is associated with a corresponding interface bus.

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