RU2802238C1 - Fiber-optic cable line - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to safety systems for fibre optic cable systems in hazardous areas. A fibre-optic cable line includes an optical cable, transceiver equipment located mainly outside the explosive zone, to which all the optical fibres of the cable are connected in a way that allows at least 2 communication channels to be transmitted over each optical fibre, equipment for measuring the attenuation coefficient, a software and hardware complex for control of the operation of transceiver and measuring equipment, each fibre is connected to its own unit of transceiver equipment, and the measuring equipment uses one of the channels to test the attenuation of the signal in the fibre and, if the attenuation in the optical fibre grows above a predetermined value, the software and hardware complex produces disabling signal transmission at least along the fibre in which attenuation growth is detected.

EFFECT: ensuring safe operation of a data transmission system based on a fibre-optic cable in explosive areas in case of cable damage, resulting in the removal of optical radiation energy into a potentially explosive environment.

9 cl, 1 dwg

Description

The invention relates to the field of electrical engineering, namely to safety systems for fiber optic cable systems in hazardous areas.

When operating a fiber optic cable, there is always the possibility of damage to it. In this case, the energy of the laser or LED can be output from the optical fiber to the surrounding potentially explosive atmosphere and initiate ignition in the explosive environment.

The task to be solved by the claimed invention is to ensure the safe operation of a data transmission system based on a fiber-optic cable in explosive areas when the cable is damaged, resulting in the removal of optical radiation energy into a potentially explosive environment.

The claimed technical result is achieved by a fiber-optic cable line, including an optical cable, transceiver equipment located mainly outside the explosive zone, to which all the optical fibers of the cable are connected in a way that allows at least 2 communication channels to be transmitted through each optical fiber, equipment for measuring the attenuation coefficient, software and hardware complex for controlling the operation of transceiver and measuring equipment, each fiber is connected to its own unit of transceiver equipment, and the measuring equipment uses one of the channels to test the attenuation of the signal in the fiber and, in the case of an increase in attenuation in the optical fiber above a predetermined value, the hardware-software complex disables signal transmission at least along the fiber in which attenuation growth is recorded.

The signal is turned off by the hardware and software system when the specified attenuation value is reached, which is determined taking into account the type of fiber used and the length of the fiber optic line.

Measuring equipment is used for each fiber separately, or for all fibers one piece of equipment is used, which sequentially monitors the signal attenuation in all fibers of the cable.

The system is designed in such a way that the time interval between detection of exceeding the specified signal attenuation values and switching off the signal transmission through the fiber does not exceed 1 second.

The level of the average power of optical radiation at the output of the radiation source is not less than minus 9 dBm for wavelengths of 850, 1300, 1310, 1550 nm.

When signal attenuation is detected above the set values, the system provides a notification about the disconnection and the detected attenuation coefficient to the central control room of the service center servicing the communication line.

The value of the signal attenuation at the moment the line is disconnected, all points of local attenuation increase with an accuracy of 1 meter are recorded by the measuring device and can be transmitted to the central control center of the service center serving the communication line.

There are no metallic elements in the fiber optic cable.

The cable is made in a fire-resistant design that does not spread combustion during group laying.

Fig. 1 is a diagram of a data transmission system based on fiber optic cable in hazardous areas.

An exemplary embodiment of the invention

The fiber optic cable is laid in the hazardous area. At the same time, the beginning and end of the fiber-optic communication line, including cabinets with receiving and transmitting equipment, are outside the explosive zone. Transceiver equipment is connected to each of the optical fibers, allowing transmission of a plurality of channels, for example, from 4 to 96, over a single fiber. The measuring equipment included in the system performs attenuation testing of each fiber in at least one of the transmission channels. If on one of the fibers an increase in attenuation above the specified values is recorded, the hardware-software complex automatically switches off the source of optical radiation along this fiber. The rest of the fibers remain in work. This ensures the safe operation of a data transmission system based on fiber optic cable in hazardous areas in the event of cable damage, while maintaining system operability in the event of fiber damage.

In the framework of this application, the term "attenuation" refers to the decrease in the power of the optical signal, calculated by the formula:

α=10⋅lg(P ₁ /P ₂ ),

where α - attenuation, dB; P ₁ - signal power at point 1; P ₂ - signal power at point 2.

The attenuation measurement for each fiber can be carried out, for example, by the Rayleigh backscattering method, where the attenuation coefficient measurement requires connection on only one side of the optical line.

The set values are determined taking into account the type of fiber used, the length of the fiber-optic communication line. This allows you to determine the probability of damage or breakage of the fiber as accurately as possible.

Measurement equipment can be used for each fiber individually, which is preferable for response speed, or one piece of equipment is used for all fibers, consistently monitoring signal attenuation in all fibers of the cable.

The system is designed in such a way that the time interval between detection of exceeding the specified signal attenuation values and switching off the signal transmission through the fiber does not exceed 1 second. The level of the average power of optical radiation at the output of the radiation source is not less than minus 9 dBm for wavelengths of 850, 1300, 1310, 1550 nm.

In addition, in order to be able to take timely measures when signal attenuation is detected above the specified values, the system provides a notification about the disconnection and the detected attenuation coefficient to the central control center of the service center serving the communication line. Such a system will make it possible to introduce protective functions and to determine the location of damage in a timely manner and with high accuracy and to send specialists to the scene of an accident at critical infrastructure facilities, for example, gas pipelines, thereby creating a unified information system for monitoring and rapid response.

To correct the place, the value of the signal attenuation at the moment the line is disconnected, all points of local increase in attenuation with an accuracy of 1 meter, which include a break, are recorded by the measuring device and can be transferred to the central control center of the service center servicing the communication line.

It is desirable to use a completely dielectric cable design, in which there are no metal elements, for example, including a central strength element made of a fiberglass rod, around which optical modules are twisted, inside which optical fibers are located, an inner sheath made of polyethylene, armored cover, additional strength elements in the form of synthetic threads, cable sheath. This will ensure electromagnetic compatibility with electrical components in the immediate vicinity and eliminate the problem of intrinsic safety.

It is desirable to make the cable in a fire-resistant design that does not spread combustion during group laying, for example, according to GOST 31565-2012 Cable products. fire safety requirements.

Claims (9)

1. Fiber-optic cable line, including an optical cable, transceiver equipment located outside the explosive zone, to which all the optical fibers of the cable are connected in a way that allows at least 2 communication channels to be transmitted over each optical fiber, equipment for measuring the attenuation coefficient, software and hardware a complex for controlling the operation of the receiving-transmitting and measuring equipment, with each fiber connected to its own unit of receiving-transmitting equipment, and the measuring equipment uses one of the channels to test the attenuation of the signal in the fiber and, if the attenuation in the optical fiber grows above the specified value, programmatically - the hardware complex disables signal transmission at least along the fiber in which attenuation growth is recorded. 2. The cable line according to claim 1, characterized in that the signal is turned off by the hardware-software complex when the specified attenuation value is reached, which is determined taking into account the type of fiber used and the length of the fiber-optic line. 3. Cable line according to claim 1, characterized in that the measuring equipment is used for each fiber separately, or for all fibers one piece of equipment is used, which sequentially monitors the signal attenuation in all fibers of the cable. 4. The cable line according to claim 1, characterized in that the system is designed in such a way that the time interval between detection of exceeding the specified signal attenuation values and turning off the signal transmission through the fiber does not exceed 1 second. 5. Cable line according to claim 1, characterized in that the level of the average power of optical radiation at the output of the radiation source is at least minus 9 dBm for wavelengths of 850, 1300, 1310, 1550 nm. 6. The cable line according to claim 1, characterized in that when signal attenuation is detected above the specified values, the system provides a notification about the disconnection and about the detected attenuation coefficient to the central control room of the service center serving the communication line. 7. The cable line according to claim 1, characterized in that the value of the signal attenuation at the moment the line is turned off, all points of local increase in attenuation with an accuracy of 1 meter are fixed by the measuring device and can be transmitted to the central control center of the service center serving the communication line. 8. Cable line according to claim 1, characterized in that there are no metal elements in the fiber optic cable. 9. Cable line according to claim 1, characterized in that the cable is made in a fire-resistant design that does not spread combustion during group laying.

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