RU2230252C2 - Method of warning on break in product line - Google Patents

Abstract

FIELD: monitoring and check of underwater and underground product lines. SUBSTANCE: proposed method includes supply of sounding signal and estimation of results of sounding ; used as sounding signal is optical pulse signal sent over at least one measuring channel isolated from surrounding medium; for forming such signal, envelope of product line is fastened with fibrous light guide; it is good practice to make is continuously over entire length of section under test; break is demonstrated by change in parameters of reflected optical signal at measuring channel input. EFFECT: possibility of monitoring product lines; enhanced efficiency. 2 cl, 1 dwg

Description

The invention relates to means for preventing emergencies at gas and oil pipelines and can be used to create a system for continuous monitoring of the technical condition of underwater and underground product pipelines, i.e. pipelines not available for direct control.

There is a method of warning about the breakdown of the product pipeline, based on the use of radar, including the radiation of electromagnetic energy and the reception of electromagnetic waves reflected from the sea surface of decameter and meter ranges (see Kutuzov V.M., Popov A.G., Bezuglov A.V., Ryabukhov I.R. Monitoring of water areas based on over-horizon radar systems of the decameter range // In the journal of the State Committee of the Russian Federation for Higher Education "Monitoring", special issue, March 1996, p. 18).

The disadvantages of this method are that the presence of gusts of underwater product pipelines is determined only after a certain time, when the transported product appeared on the surface of the sea and the coordinates of the gust are determined by the location of the exit of the transportation object (oil or gas) to the surface, however, in the presence of underwater and surface currents, the coordinates spots on the surface of the sea do not coincide with the coordinates of the gust, and with a small amount of crack opening of the underwater product pipeline, gas bubbles or oil Products from a gust may not reach the surface, scattering and dissolving in the marine environment.

There is also a known method for warning of a product pipeline rupture, including the supply of a sounding signal on the pipeline route and the evaluation of sensing results (see Antokolsky L.M., Pronin S.V., Shakhov M.N. Development of a sonar system for examining water areas based on side-scan sonar // Acoustic Journal, Volume 40, No. 2, 1994, p. 323). The method is based on the use of hydroacoustic means and is based on the fact that the emitted acoustic energy interacts with the transport objects leaving the gust, which leads to a corresponding change in the acoustic signals passing through this section of the water area.

The disadvantages of this detection method are the impossibility of constant monitoring of the underwater product pipeline along its entire length, since sonar bottom surveying at the product pipe laying sites is performed sporadically, in addition, the reliability of sensing results significantly depends on the environmental parameters of the pipeline environment, i.e. independent of the state of the product pipeline.

The task to which the stated solution is directed is expressed in providing the possibility of constant monitoring of the product pipeline in good condition and increasing the speed of warning about the break of an underwater product pipeline.

The technical result obtained by solving this problem is expressed in the fact that continuous monitoring of the technical condition of the product pipeline is provided, while the sensitivity of the method does not depend on the state of the water area. In addition, it provides the ability to control long (up to several hundred kilometers) sections of the pipeline with a minimum of involved forces and means.

To solve this problem, the method of warning of a product pipeline rupture, including the supply of a probing signal along the pipeline route and evaluating the sensing results, is characterized in that a pulsed optical signal is used as the probing signal, which is sent by at least one stationary measuring channel isolated from the external medium, for the formation of which a fiber optic fiber is fastened to the product pipe shell, preferably continuously, over the entire length of the controlled section duct, while the presence of a gap is judged by a change in the parameters of the reflected optical signal at the input of the measuring channel. In addition, when using several stationary measuring channels, at least one of them is laid in the form of a spiral covering the controlled section of the product pipeline.

A comparative analysis of the features of the claimed and known technical solutions indicates its compliance with the criterion of "novelty."

The features of the characterizing part of the claims solve the following functional tasks.

The signs of “using a pulsed optical signal as a probing signal, which is sent ... through .... a stationary measuring channel isolated from the external environment, for the formation of which a fiber optic fiber is fastened to the sheath of the product pipeline,” provide the opportunity to minimize the technical means needed to solve the assigned task, and the possibility of using a “stationary” work scheme. In addition, thereby eliminating the dependence of the measuring signal from the parameters of the state of the environment.

A sign indicating that there should be more than one stationary measuring channel allows one to make the identifying factor (changing the parameters of the reflected signal received at the input of the measuring channel) unambiguous when using several optical fiber lines that allow one to diagnose a false response while using these lines.

Signs that specify the bonding parameters of preferably a fiber waveguide with a product pipe, as “continuously, over the entire length of the monitored section”, ensure the reliability of the gap detection, i.e. they allow to fix the gap with a small crack width, since this eliminates the influence of the extension of the fiber due to its elasticity, which can reach 5% of the length of its stretched section.

The signs “of a gap are judged by changing the parameters of the reflected optical signal at the input of the measuring channel” provide the opportunity to simplify the operation, since both the transmitting and receiving nodes are located at the same end of the measuring channel. This additionally provides a sufficiently accurate determination of the location of the gap (together with a sign characterizing the optical signal as a pulse).

The features of the second claim allow to identify the longitudinal rupture of the pipeline.

The drawing shows a diagram of the implementation of the claimed method on the example of an underwater product pipeline.

The drawing shows: 1 - straight-line stationary measuring channels (fiber optic optical fibers), 2 - spiral-shaped stationary measuring channels, 3 - optical connectors, 4 - coherent radiation source, 5 - optical splitter, 6 - photodetector, 7 - data processing unit. In addition, the drawing shows an optical reflector 8, a product pipeline 9, a bottom 10 of the water area 11, an optical Y-splitter 12.

When implementing the method, the following set of equipment is used: fiber-optic optical fibers, the ends of which are equipped with optical connectors 3. In addition, an optical radiation source (laser) 4, an optical splitter 5, a photodetector 6 and a data processing unit 7 and an optical reflector 8 are included in the equipment set .

As the stationary measuring channels, standard fiber optic fibers are used, which are structurally identical and preferably solid. The optical connectors are structurally similar and are standard connectors, usually used to connect the optical fiber of a standard size corresponding to that used in the design of the measuring channel.

As the source of optical radiation 4, a pulsed laser, preferably a semiconductor, is used. As an optical splitter 5, a standard device is used that ensures the laser signal is divided into the number of channels corresponding to the number of stationary measuring channels (when using only one stationary measuring channel connected to the laser, for example, when the length of the monitored section of the product pipeline is long, when the power of the coherent radiation source should be large), optical splitter 5 do not use.

As an optical reflector 8, a device of known design is used, which in its performance characteristics corresponds to the set of equipment used.

The optical Y-coupler 12 is a standard design in which the optical stream supplied from one side of the coupler is divided into two optical streams output from its opposite side, or two optical streams supplied from one side of the coupler are combined on its opposite side into one optical stream.

As the photodetector 6, an electric converter of a known design, for example a photodiode, is used. The output of the photodetector 6 is connected to the input of the data processing unit 7, which can be used on stationary measuring channels with the simplest transducer of known design, providing either control of the optical and (or) acoustic indicator output to the operator’s console or the pumping unit of the product pipeline (or its valves ) - in the drawings, the named nodes are not shown, or the data processing unit 7 can be directly connected to the emergency control units of the product installation pumping unit or its latches.

As a data processing unit 7, a converter of a known design, preferably digital, can be used, which, in addition to supplying a warning signal, also measures the time interval between the emission of a pulsed optical signal and the time it arrives at the photodetector.

The method is illustrated by the example of an underwater product pipeline.

Stationary measuring channels 1 and 2 are formed, for which a predetermined number of optical fibers is fixed (for example, glued) to the shell of the product pipeline 9. It is preferable to use long continuous light guides, reeling them from bobbins (not shown in the drawings) and sticking to the product pipeline shell as it grows (before applying the standard protective coating to it and placing the formed whip of the product pipeline 9 at the bottom 10 of water area 11). At the same time, the technology for constructing a product pipeline does not differ from the generally accepted one.

The conclusions of the optical fibers extending beyond the controlled area are provided with optical connectors 3, through which the stationary measuring channels, through the optical Y-splitter 12, are connected to the optical radiation source 4 and the photodetector 6 (optical radiation source (s) 4 and photodetectors 6 are placed on one end of the stationary measuring channels 1 and 2, while the opposite ends of these measuring channels provide optical reflectors 8). The outputs of the photodetectors 6 are connected to the input of the data processing unit 7.

Turn on the source (or sources) of coherent radiation 4, while the optical signal, passing through the appropriate fiber to the optical reflector 8, returns to the beginning of this fiber (stationary measuring channel) and passing the optical Y-splitter 12, falls on the photodetector, this constantly measures the amount of time between the radiation of the optical signal and the time it arrives at the photodetector. If this parameter is constant in time, there is no control signal at the output of the data processing unit.

When the product pipeline 9 ruptures, the stationary measuring channels 1 and (or) 2 are simultaneously destroyed, the optical fibers break off at the section crossing the formed crack (not shown in the drawings), the optical signal does not reach the end of the measuring channel and is reflected from the surface of the fiber’s break, therefore, the value decreases the time interval between the emission of the optical signal and the time of its arrival in the photodetector 6. As a result, the corresponding control signal appears on the output of the data processing unit 7 (i.e. because the remote operator LED is activated or triggered block emergency control pump installation or its product pipeline valves, stopping the supply of the product).

In addition, measure the amount of time between the radiation of the optical signal and the time of its arrival in the photodetector and, knowing the speed of light propagation in the fiber, determine the distance to the place of the gap.

With a longitudinal rupture, rectilinear stationary measuring channels 1 oriented along the longitudinal axis of the product pipeline may not suffer at all. To fix such damage, use spiral-shaped stationary measuring channels 2, which are destroyed by longitudinal cracks.

For a detailed examination of the identified section of the water area in the zone of the alleged rupture of the product pipeline, a side-scan sonar is used or the site is inspected using divers. In the process of repairing the product pipeline, fiber optic fibers are also glued to its replaced sections, the ends of which are connected by welding with the ends of serviceable sections of fiber optical fibers previously fixed on the shell of the product pipeline.

Claims (2)

1. A method of warning about a product pipeline rupture, including the supply of a probing signal on the pipeline route and the evaluation of sensing results, characterized in that a pulsed optical signal is used as the probing signal, which is sent at least by one stationary measuring channel isolated from the external environment , for the formation of which a fiber optic fiber is fastened to the sheath of the product pipeline, preferably continuously, over the entire length of the controlled section of the product pipeline, PIR gap judged by the change in the parameters of the reflected optical signal at the input of the measuring channel. 2. The method according to claim 1, characterized in that when using several stationary measuring channels, at least one of them is laid in the form of a spiral covering the controlled section of the product pipeline.