RU174175U1 - DEVICE FOR DISTRIBUTED DISTRIBUTED FIBER OPTIC SENSOR - Google Patents

Abstract

The utility model relates to components of monitoring systems based on distributed fiber optic sensors and can be used to spatially link the readings of distributed sensors installed, for example, on pipelines, and to protect the tap-off part of the fiber from external influences. The device for tapping a distributed fiber optic sensor comprises a housing, inside of which there is placed a means for winding optical fiber and a label unit. The body is formed by a saddle with ties and a protective cover. The means for winding the optical fiber is formed by a coil on which a thermal label assembly in the form of an electric heater is fixed. A protective tube is fixed on the saddle, inside of which there is a tap-off part of the optical fiber. The utility model allows to expand the arsenal of technical means for retracting a distributed fiber optic sensor. f-ly, 2 ill.

Description

The utility model relates to components of monitoring systems based on distributed fiber optic sensors and can be used to spatially link the readings of distributed sensors installed, for example, on pipelines, and to protect the tap-off part of the fiber from external influences.

Monitoring systems based on distributed fiber-optic sensors use methods based on the effects of Rayleigh scattering (PP), Raman scattering (Raman scattering, or the Raman effect) and Mandelstam-Brillouin scattering (RMB).

The PP effect is coherent light scattering without changing the wavelength of particles, inhomogeneities, or other objects that are smaller than the wavelength. When using the properties of scattering coherence, the optical fiber plays the role of a distributed interferometer, the reflected signal from which contains information about the temperature and strain at the scattering point. The method based on the PP effect polls a distributed fiber optic sensor with a frequency of up to several tens of kHz, which allows you to control fast-flowing mechanical phenomena at the monitoring object. Thus, the method based on the PP effect is mainly used for recording mechanical vibrations in distributed vibro-acoustic monitoring systems.

The Raman effect is due to the interaction of radiation with thermal molecular vibrations in the medium. The reflected (Raman) signal contains information about the temperature at the scattering point. The method based on the Raman effect is used in temperature distribution monitoring systems.

Mandelstam-Brillouin scattering in an optical fiber occurs as a result of the interaction of radiation with acoustic waves (sound waves) of the gigahertz range. This effect can be regarded as the diffraction of light by a moving grating created by an acoustic wave. Thus, the reflected signal experiences a Doppler frequency shift, since the grating moves with the speed of sound. The speed of sound is directly related to the density of the material and depends both on its temperature and on internal mechanical stress (deformation). As a result, the magnitude of the Brillouin frequency shift carries information about the temperature and strain at the scattering point. The method based on the RMB effect is used in monitoring systems for temperature distribution and / or static deformations.

In the above monitoring systems, the determination of the place at which the temperature or deformation is measured is based on a technology similar to that used in radar installations (reflectometry). The determination of the distance to the point in the optical fiber at which the measurements are made is based on the conversion of the delay time from sensing to the registration of the scattering signal to a distance that corresponds to the path of light radiation through the optical fiber from the polling device to the scattering point and vice versa. Thus, the measurement result is the dependence of the measured quantity (for example, temperature) on the distance along the optical fiber to the polling device. The range of distances in such measurements can reach tens of kilometers, and the spatial resolution, which is determined by the duration of the optical pulse, is several meters.

Distributed fiber-optic systems for monitoring temperature, deformation, or mechanical vibrations based on the effects of PP, Raman, and RMB are currently widely known in the art and are commercially available (see, for example, URL: http://t8.ru/?page_id = 221, reference date 22/07/2016; URL: http://petrofibre.ru/products/, reference date 07/22/2016; URL: http://www.neubrex.com/htm/products.htm, appeal date 07/22/2016).

Pipeline deformation monitoring systems based on distributed fiber optic deformation sensors are known from the prior art (URL: http://www.smartec.ch/Ref/SNAM-Rete-Gas-Gas-pipeline-monitoring, accessed 22/07/2016; URL : http://www.smartec.ch/content/download/860/6837/file/c127.pdf, accessed 07/22/2016; URL: http://lscom.ru/pp.html, accessed date 22 / 07/2016). However, the known systems do not contain devices for spatially linking the readings of the distributed sensors to the monitoring object, in addition, in the known systems there are no devices providing reliable protection of the tap-off part of the optical fiber from external influences at the points of removal from the monitoring object (for example, a pipeline).

The closest in technical essence to the proposed utility model is a spatial reference device for a distributed fiber optic sensor, which can be used to divert the specified sensor from the monitoring object and contains a housing with grooves for the supply and removal of optical fiber, inside which there is a means for winding optical fiber and a label unit ( see patent GB 2210451, class G01K 11/32, publ. 06/07/1989). The disadvantages of the known device are the inconvenience of use and the complexity of installation.

The technical problem is the elimination of these shortcomings and the expansion of the arsenal of technical means for the removal of a distributed fiber optic sensor.

In the proposed device for retracting a distributed fiber optic sensor, comprising a housing, inside of which there is placed a means for winding optical fiber and a thermal label unit, the housing is formed by a saddle with ties and a protective cover, means for winding optical fiber is formed by a coil on which the thermal label unit is mounted in the form of an electric heater, and on the saddle a protective tube is fixed, inside of which the tap-off part of the optical fiber is located. The device is preferably provided with an additional pipe fixed to the saddle, inside of which a protective pipe is located. The coil is preferably provided with a removable pressure bar. The tag assembly is preferably in the form of a tape heater wound on a spool. The housing is preferably provided with slots for supplying and discharging the optical fiber.

The combination of the above features allows you to solve the above technical problem and get a technical result, which consists in creating an alternative device for the allocation of a distributed fiber optic sensor.

In FIG. 1 shows a General view of the proposed device;

in FIG. 2 - its inner part under the protective cover.

The proposed device for the distribution of a distributed fiber optic sensor consists of a saddle 1, rigidly fixed to it using brackets 2 and 3 of a protective polyethylene pipe 4 of a smaller diameter to provide hydraulic protection and an additional polyethylene pipe 5 of a larger diameter to provide mechanical protection, a thermal marking unit 6, a removable protective cover 7 , three ties 8 and a rubber gasket 9. The saddle 1 and the cover 7 form the device’s body, and the brackets 2, 3 are installed at a distance that meets the requirements for the bending radius fiber optic ba.

The saddle 1 through the gasket 9 is installed on the pipeline and by means of ties 8 is rigidly attached to it using six nuts M8. The saddle 1 is equipped with special grooves for supplying the optical fiber 10 from the monitoring object (pipeline) under the protective cover 7. Between these grooves inside the body there is a means for winding the optical fiber, consisting of a strap 11 rigidly mounted on the saddle 1, a removable clamping bar 12, two M6 13 studs 13 and coils 14.

The thermal tag assembly 6 is made in the form of a tape electric heater 15 wound on a coil 14. Two brackets 2 are installed in the immediate vicinity of the thermal tag assembly 6, which provide reliable fastening of the pipe 4 to the seat 1. To ensure reliable protection of the optical fiber transitions from the monitoring object to coil 14 and c a removable protective cover is installed in the protective tube 4 thereof. Reliable preservation of the optical fiber 10 from external influences on the tap section from the monitoring object to the cable well is provided by an additional pipe 5, rigidly fixed in the bracket 3 on the seat 1.

An electric cable 17 supplying the electric heater 15 and coming from the cable well is also located inside the pipes 4, 5.

The proposed device operates as follows.

Saddle 1 is fixed on the monitoring object (pipeline). From one or both sides, a distributed sensor optical fiber 10 is fed. At least one meter of optical fiber 10 is wound on a reel 14, which is installed between the studs 13 and pressed by the strap 12. The outlet end of the optical fiber 10 is inserted into a protective tube 4, which, in turn, is located in the additional pipe 5. At the place where the pipe 4 enters the pipe 5 set the heat shrink 16. The pipes 4, 5 are firmly fixed with brackets 2, 3 to the seat 1. A protective cover 7 is installed on the thermo label 6 and the underwing space is filled with polyurethane foam.

When voltage is applied via cable 17 to the electric heater 15, it heats the portion of fiber 10 wound on the coil 14. The heated portion acquires temperature and strain increments (due to thermal expansion), which is detected by the polling device and serves for spatial reference of the readings of the distributed fiber-optic sensor to the object monitoring.

The proposed device allows not only spatial reference of the readings of the distributed fiber optic sensor (the temperature effect of the electric heater is recorded by the sensor, which allows you to determine the point on the track where the monitoring object begins), but also protects the sensor in the most vulnerable place - the place of its removal from the monitoring object (attached at the monitoring object, the sensor is protected, including by the monitoring object itself). The proposed device can be used to make taps of the ends of the building lengths of the distributed sensors of the monitoring system mounted on the surface of the pipeline into the cable well for switching, protection and storage of the cable stock.

Claims (5)

1. A device for retracting a distributed fiber optic sensor, comprising a housing, inside of which there is placed a means for winding optical fiber and a label unit, characterized in that the housing is formed by a saddle with couplers and a protective cover, means for winding optical fiber is formed by a coil on which the thermo label assembly is fixed in the form of an electric heater , and a protective tube is fixed on the saddle, inside of which the tap-off part of the optical fiber is located. 2. The device according to claim 1, characterized in that it is equipped with an additional pipe fixed to the saddle, inside of which there is a protective pipe. 3. The device according to p. 1, characterized in that the coil is equipped with a removable pressure bar. 4. The device according to p. 1, characterized in that the node thermotags is made in the form of a tape heater, wound on a reel. 5. The device according to p. 1, characterized in that the housing is provided with grooves for the supply and removal of optical fiber.

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