RU2550768C1 - Device to monitor vibroacoustic characteristic of lengthy object - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: group of inventions relates to measurement equipment. The device to monitor vibroacoustic characteristic of a lengthy object according to the first version of realisation comprises a transmitter of optical radiation, two receivers, two sensitive elements, made in the form of optic fibre, two splitters, three communication channels, two couplers, three amplifiers. Fibres are channels of communication of a fibre optic transmission line, the length of which is not less than half of length of the sensitive element. At the same time the outlet of the transmitter is connected only by one first communication channel to each of inputs of two splitters, each of which is accordingly connected to one of sensitive elements, the outlet of one of splitters is accordingly connected by means of the second communication channel of the fibre optic transmission line to the inlet of one receiver of optical radiation, and the outlet of the other splitter by means of the third communication channel - to the inlet of the other receiver of optical radiation. According to the second version of realisation, the outlet of the transmitter is connected only by one first communication channel of the fibre optic transmission line to the input of the first splitter, which is connected to one end of the first sensitive element, which by the opposite end is connected to the inlet of the second splitter connected to the second sensitive element, the outlet of one of splitters is accordingly connected by means of the second communication channel of the fibre optic transmission line to the inlet of one receiver of optical radiation, and the outlet of the other splitter by means of the third communication channel - to the inlet of the other receiver of optical radiation.

EFFECT: increased accuracy of measurements.

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Description

The invention relates to devices for controlling the distribution of the vibro-acoustic characteristics of extended objects, using long-length fiber-optic sensitive elements and using the principles of optical Rayleigh scatterometry, and can be used in production (production and injection) wells, during transportation of well products to collection points, etc.

The tasks of controlling the presence and location of vibrations are relevant for controlling the transportation of oil, gas, other petroleum products, as well as other liquids and gases in pipes and pipelines, and can serve to detect leaks, localize in-tube shells and to determine the nature of the mode of movement of the transported product. Vibration control is also relevant for solving perimeter security tasks, where the presence and nature of recorded vibrations allows determining the presence and location of perimeter disturbance, i.e. intrusion into the object.

A fiber optic device is known for detecting intrusion into a predetermined perimeter of an extended object, which includes means for generating a coherent light pulse that is introduced into a sensitive optical fiber located along a predetermined perimeter. The backscattering of light caused by a pulse in a sensitive fiber is detected by a photodetector and generates a signal. Changing this signal is used to detect intrusion (US No. 5194847).

The device comprises a continuous laser, an optical modulator, a sensing element in the form of an optical fiber located longitudinally inside or outside an extended object, means for connecting the sensitive element to an optical modulator and a photodetector, and means for processing the signal from the output of the photodetector - an analog-to-digital converter with a processor.

The limitation of this device is the low power of the study source (typically 1 mW), therefore, a small signal to noise ratio, which leads to the need for long-term accumulation of the signal and the inability to register small values of vibroacoustic vibrations. For the same reason, it is impossible to use long (kilometers, tens of kilometers) sensitive elements. The device is not intended for use in wells.

The closest is a device for monitoring the vibro-acoustic characteristics of an extended object, containing a continuous laser, an optical modulator, a sensing element in the form of an optical fiber located longitudinally inside or outside the extended object, an optical radiation input unit into the sensitive element, a photodetector, and a signal processing unit with a processor, this device is equipped with a timer connected in series with each other by an analog-to-digital converter and introduced into the processing unit with drove it with a buffer memory, it additionally contains an active optical fiber, a spectral compaction unit, a filter based on the Bragg fiber array, an optical valve and an output directional optical coupler connected together with the optical modulator in a ring and forming a narrow-band fiber laser, and a continuous laser is connected to a spectral compaction unit, an output directional optical coupler - with a node for inputting optical radiation into a sensitive element, a photodetector - with an analog-to-digital converter and with a node for inputting radiation into the sensing element, a buffer memory with a processor, and a timer with an optical modulator, an analog-to-digital converter and buffer memory (RU No. 2271446).

However, the limitation of this device is not a large increase compared with the technical solution according to US No. 5194847 of the length of the sensitive element, which is associated with the attenuation of the signal in its optical fiber and with an increase in the instability of the coherence parameters from pulse to pulse with increasing time between them, leading to noise interfering with the detection of intrusion, since the time between pulses is determined by the length of the optical fiber of the sensing element.

Another disadvantage of the known device is the increase in the monitoring time of an extended object by successive light pulses due to the low repetition rate of the polling pulses, which leads to a decrease in the frequency range (band) of recorded vibrations, which makes it difficult to detect intrusion and its place.

The use in a known device of a signal processing unit with a buffer memory, a spectral compaction unit, a filter based on a Bragg fiber array, an optical valve, their connection together with an optical modulator in a ring to form a narrow-band fiber ring laser leads to a complication of the design as a whole.

In addition, the well-known technical solution uses terminology that does not correspond to the technically generally accepted and is not correct. For example, this applies to the signal processing unit with the buffer memory, the signal processing unit with the processor, and the concept “the unit for inputting optical radiation into the sensing element” does not correspond to the function performed (circulator or coupler), since, in addition to inputting radiation, this element must also fulfill the function radiation output from the sensing element (which perform a circulator or coupler). Therefore, in the claimed technical solution, the terminology is given in accordance with GOST 26599-85 “Fiber-optic transmission systems”.

The problem solved by the invention is the improvement of technical and operational characteristics and the possibility of monitoring at a sufficiently large distance from the extended object.

The technical result obtained by the implementation of the claimed device is an increase in the length of the sensitive element, especially when it is removed from the transmitter and / or radiation receiver, an increase in the distance from the receiver / transmitter to the most remote end of the sensitive element, increased accuracy by expanding the frequency range of recorded vibrations, simplification designs.

An additional technical result that can be obtained is the use of only one optical radiation transmitter for several sensitive elements, which, with an increase in the total length of all sensitive elements and their number, preserves the main technical result while simplifying the design as a whole.

In the first embodiment, to solve the problem with achieving the specified technical result in a known device for monitoring the vibroacoustic characteristics of an extended object, comprising an optical radiation transmitter, an optical radiation receiver, a sensing element made in the form of an optical fiber located longitudinally relative to the extended object, a splitter, the optical radiation transmitter and the optical radiation receiver are connected via fibers through the splitter to the sensor element according to the invention, the communication channels of a fiber optic transmission line (FOCL) are used as fibers, the length of which is not less than half the length of the sensor element, and one optical radiation transmitter, at least two sensitive elements, two optical radiation receivers are used and two splitters, and three FOCL communication channels, while the output of the optical radiation transmitter is connected by only one first FOCL communication channel to each of the inputs of the two splitters nd, each of which is respectively connected to one of the sensitive elements, the output of one of splitters respectively connected via a second communication channel FOL to an input of a receiver of optical radiation, and the output of another splitter via a third communication channel - to the input of another receiver of optical radiation.

There may be additional embodiments of the device for the first embodiment, in which it is advisable that:

- optical couplers and an optical amplifier were introduced into the first communication channel of the fiber-optic transmission line, the output of the optical radiation transmitter is connected by the first communication channel of the fiber-optic transmission line to each of the inputs of the two splitters through optical couplers, and the optical amplifier is installed in the first communication channel - optical transmission lines between optical couplers;

- optical amplifiers were introduced and the outputs of the splitters are respectively connected to the inputs of the optical radiation receivers through optical amplifiers;

- the lengths of all sensitive elements were equal.

In the second embodiment, to solve the problem with the achievement of the specified technical result in a known device for monitoring the vibro-acoustic characteristics of an extended object containing an optical radiation transmitter, an optical radiation receiver, a sensing element made in the form of an optical fiber located longitudinally relative to the extended object, a splitter, the optical radiation transmitter and the optical radiation receiver are connected via fibers through h splitter to the sensitive element, according to the invention, fiber optic communication channels are used as fibers, the length of which is not less than half the length of the sensitive element, and one optical radiation transmitter, at least two sensitive elements, two optical radiation receivers and two splitters, and three channels are used FOCL connection, while the output of the optical radiation transmitter is connected only by one first FOCL communication channel to the input of the first splitter, which is connected to one end of the first of the sensing element, which is connected at the opposite end to the input of the second splitter connected to the second sensitive element, the output of one of the splitters is respectively connected via the second FOLP communication channel to the input of one optical radiation receiver, and the output of the other from the splitters via the third communication channel to the input of the other receiver optical radiation.

Additional embodiments of the device for the second embodiment are possible, in which it is advisable that:

- the outputs of the splitters were respectively connected to the inputs of the receivers of optical radiation through optical amplifiers;

- the first sensitive element was connected to the input of the second splitter through an optical amplifier.

These advantages of the invention, as well as its features are explained with the help of options for its implementation with reference to the accompanying drawings.

FIG. 1 depicts a generalized functional diagram of the claimed device.

FIG. 2 is the same as FIG. 1, one of the options for using several sensitive elements.

FIG. 3 is the same as FIG. 1, another of the options for using several sensitive elements when using one sensitive element as a medium for transmitting probe radiation to another sensitive element.

The device (Fig. 1) for monitoring the vibro-acoustic characteristics of an extended object contains a transmitter 1 of optical radiation, a receiver 2 of optical radiation, a sensing element 3 made in the form of an optical fiber located longitudinally relative to the extended object (inside or outside), a splitter 4. Transmitter 1 optical radiation and the optical radiation receiver 2 are connected via fibers through a splitter 4 to the sensing element 3. As the fibers, fiber communication channels 5, 6 are used but-optic transmission line 7 (FOCL). The length L _{1 of the} FOCL 7 is selected not less than half the length L of the sensing element 3 (L ₁ ≥L / 2).

At least one optical amplifier 8 can be introduced, which is installed in the FOCL 7 communication channel.

The splitter 4 can be made in the form of an optical circulator or an optical coupler, as in the closest analogue.

For the convenience of monitoring, the transmitter 1 of the optical radiation and the receiver 2 of the optical radiation are placed in a single housing 9.

The device (Fig. 2) for monitoring the vibro-acoustic characteristics of an extended object contains one optical radiation transmitter 11, at least two optical radiation receivers 12, 13, two sensing elements 14, 15, two splitters 16, 17 and three channels 18, 19, 20 connection of the fiber-optic transmission line 21. The output of the optical radiation transmitter 11 is connected by only one first communication channel 18 of the FOCL 21 to each of the inputs of the two splitters 16, 17 (first arm). Each of the two splitters 16, 17 is respectively connected (by the second arm) to one of the sensing elements 14, 15. The output of one of the splitters 16 (third arm) is respectively connected by means of the second FOLP communication channel 19 to the input of one optical radiation receiver 12. The output of the other of the splitters 17 (third arm) through the third communication channel 20 is connected to the input of another receiver 13 of optical radiation.

Optical couplers 22, 23 and an optical amplifier 24 are introduced into the first communication channel 18 of the FOCL 21. The output of the optical radiation transmitter 11 is connected by the first communication channel 18 of the fiber optic link 21 to each of the inputs of the two splitters 16, 17 (first arms) through the optical couplers 22, 23, and the optical amplifier 24 is installed in the first channel 18 of the communication link of the fiber optic link 21 between the optical couplers 22, 23 .

The outputs of the splitters 16, 17 (third shoulders) can be respectively connected to the inputs of the optical radiation receivers 12, 13 through optical amplifiers 25, 26.

The lengths of the sensing elements 14, 15 can be chosen equal.

The device (Fig. 3) for monitoring the vibro-acoustic characteristics of an extended object contains one optical radiation transmitter 31, at least two optical radiation receivers 32, 33, two sensing elements 34, 35, two splitters 36, 37 and three channels 38, 39, 40 FOCL 41 communication. The output of the optical radiation transmitter 31 is connected only by one first FOCL 41 communication channel 38 to the input of the first splitter 36 (first arm). The first splitter 36 (second arm) is connected to one end of the first sensor 34.

The first sensor 34 is connected at the opposite end through an optical amplifier 42 to the input of the second splitter 37 (first arm). The second splitter 37 is connected (second arm) to the second sensor element 35. The output of one of the splitters 36 (third arm) is respectively connected through the second FOLP communication channel 39 to the input of one optical radiation receiver 32, and the output of the other from the splitters 37 (third arm) through the third communication channel 40 is connected to the input of another receiver 33 of optical radiation.

The first sensor element 34 may be connected to the input of the second splitter 37 through an optical amplifier 42.

The outputs of the first and second splitters 36, 37 (third shoulders), respectively, can be connected to the inputs of the optical radiation receivers 32, 33 through optical amplifiers 43, 44.

The device operates (Fig. 1) as follows.

The probe radiation in the form of an optical pulse from the optical radiation transmitter 1 through the communication link 5 of the FOCL 7 is transmitted through a splitter 4 to the input of the sensing element 3. When passing through the optical fiber of the sensing element 3, Rayleigh scattering occurs, a useful signal appears, which propagates in the opposite direction and enters through a splitter 4 in the communication channel 6 of the fiber optic communication link 7 and then to the receiver 2 of optical radiation, where it is registered. Moreover, the communication channels 5, 6 of the FOCL 7 provide the transmission of optical radiation (transmitter pulse and useful signal) with the required characteristics without distortion.

The transmitter 1 of the optical radiation can be made in the same way as in the closest analogue, and comprise a cw laser and an optical modulator connected in series. The receiver 2 of optical radiation can be made in the same way as in the closest analogue, and contain a series-connected photodetector, analog-to-digital converter, processor.

In the transmission technique for transmitting and receiving an optical signal, fiber optic transmission line 7 (FOCL) is widely used. The mandatory channel-forming elements of the FOCL 7 are optical fibers, single-mode or multi-mode, including those supporting the state of signal polarization, and one optical fiber can provide signal transmission through several optical communication channels due to spectral multiplexing. Optical fibers are characterized by the attenuation parameter of the optical signal and dispersion characteristics. Typical attenuation of radiation with a wavelength of 1550 nm in connected optical fibers is 0.19-0.22 dB / km and the chromatic dispersion is about 20 ps / (nm · km). When transmitting optical radiation through the communication channels 5, 6 of the FOCL 7, the amplitude of the optical signal decreases due to attenuation, and the temporal shape of the signal may be distorted due to the contribution of chromatic dispersion.

To restore the amplitude of the optical signal, optical amplifiers 8 (UO) are used, for example, Erbiev or Ramanovsky amplifiers, which are installed in the communication channel 5 and / or 6 over a certain distance so that the gain of UO 8 compensates for the total attenuation and loss of optical power in the previous section of the FOCL 7 , including the branched part of the optical power of the signal in the case of installing an optical coupler in the FOCL section 7. The typical length of the FOCL section 7 without amplifiers is 50 km, which corresponds to the loss of optical power signal at 10 dB. Thus, in the present invention, UO 8 is understood to mean one or several optical amplifiers 8 installed over a certain distance, which together with FOL 7 form a system of linear paths of fiber-optic transmission systems having a common optical cable, linear structures and devices for their maintenance within actions of service devices.

In addition to service devices in the form of UO 8, FOCL 7 can be supplemented by spectral optical filters that filter the optical useful signal from the spectral noise of UO 8, for example, from spontaneous emission of an Erbium amplifier, by the wavelength spectrum. To restore the temporary waveform of the signal, dispersion compensators (fiber or semiconductor) can be used to compensate for the dispersion accumulated in the previous section of the FOCL 7. The use of optical fibers supporting the state of polarization of the signal allows one to get rid of the polarization-mode dispersion and reduce distortion in the transmission line. The combination of UO 8 with a dispersion compensator sequentially installed behind it in the communication channel 5 or 6 is a repeater. Thus, the use of a VO 8 and dispersion compensators (not shown in FIG. 1) over a certain distance on the fiber-optic transmission line 7, allows to restore the shape of the signal transmitted through channel 5 and / or 6 to the original state, that is, to repeat the signal.

The amplifier 8 can be installed both in the communication channel 5 of the FOCL 7, and in channel 6, or in both communication channels 5 and 6 of the FOCL 7, which depends on the type of extended object, its length L and the problem to be solved, for example, the mode of movement of the transported product or determining the location of the intrusion. The amplifier 8 is expediently mounted in the communication channel 5 of the fiber optic communication link 7 with a small power of the optical radiation transmitter 1 or, for example, with L ₁ close to the length L, in the communication channel 6 with a very large length L of the sensing element 3, in two communication channels 5 and 6 for large lengths, both L ₁ and L.

The length L _{1 of the} FOCL 7 is selected not less than half the length L of the sensing element 3 (L ₁ ≥L / 2). This allows you to increase the length of the sensitive element, especially when it is removed from the transmitter 1 and / or receiver 2 of optical radiation, to increase the distance from the receiver 2 and / or transmitter 1 to the farthest end of the sensitive element 3, to increase accuracy by expanding the frequency range of recorded vibrations, which explained as follows.

Experiments show that the sensitive elements 3 made of optical fiber (with mechanical connection with the outer sheath) have a sensitivity several times higher than the standard cables used in fiber optic cables 7 with free laying of fibers. However, the imposition on the optical fiber of the sensitive element 3 of the mechanical connection of dense shells of polymers increases the kilometer attenuation in it. In particular, at a widely used wavelength of 1550 nm, the kilometer attenuation in the sensor 3 with a single-mode fiber in a dense buffer shell increases to 0.3 ÷ 0.6 dB / km compared to the initial attenuation of 0.22 dB / km in optical channels 5, 6 communication, in standardly used in fiber optic cable 7 cables with free fiber laying.

Consider an example when the dynamic range of the device is 11 dB and the monitoring object is 18.5 km away from transmitter 1 / receiver 2. Then, with the standard layout of the receiver 2, transmitter 1, splitter 4 in one housing and the laying of the sensitive element 3 (with kilometric attenuation of 0.3 dB / km), the length of the entire sensitive element 3 will not exceed 37 km (dynamic range 11 dB divided by kilometric attenuation 0.3 dB), and the maximum length of the sensor 3, laid along the object, will be 18.5 km. The maximum distance from transmitter 1 / receiver 2 to the most distant end of the sensor will be 37 km. The maximum interrogation frequency in this case will be ~ 2700 Hz (the group speed of light in an optical fiber is ~ 200000 km / s divided by the doubled length of the entire sensitive element 2 × 37 km). When using fiber optic link 7 (in accordance with Fig. 1) with a length of 18.5 km, we get that the loss in fiber optic link 7 with a kilometric attenuation of 0.22 dB / km is 4.07 dB, so that the maximum length L of the sensing element 3, which is the whole laid along the object will exceed 23.1 km (so that the total losses in the FOCL of 7 ~ 4.07 dB and a sensitive element of 3 ~ 23.1 km × 0.3 dB / km = 6.93 dB would be a value corresponding to the dynamic range ) The maximum distance from the transmitter 1 / receiver 2 to the farthest end of the sensor 3 will be 41.6 km. In this case, the maximum interrogation frequency will be ~ 4300 Hz (the group speed of light in an optical fiber is ~ 200000 km / s divided by the doubled length of the entire sensitive element 3 ~ 2 × 23.1 km).

Thus, to achieve the specified technical result, the length L _{1 of the} FOCL 7 must be selected not less than half the length L of the sensing element 3 (L ₁ ≥L / 2).

Simplification of the design as a whole is achieved by reducing the number of elements and functional connections between them compared with the closest analogue.

In addition, the placement of the transmitter 1 / receiver 2 in the immediate vicinity of the sensing element 3, as is done in the closest analogue, is not always possible, since the power supply of the transmitter 1 / receiver 2, which can be expensive and difficult to implement, for example, when monitoring a pipeline laid in sparsely populated areas, in the extreme north, or when monitoring oil and gas strata in production wells, or when monitoring subsea pipelines.

Optical amplifier 8 is expediently mounted in the FOCL communication channel 7 in the case when the attenuation of the optical signal leads to a deterioration in the technical characteristics of the device.

The device (Fig. 2) for monitoring the vibro-acoustic characteristics of an extended object works as follows.

The probe radiation in the form of an optical pulse from the optical radiation transmitter 11 is propagated through the communication channel 18 of the FOCL 21 and one part enters through the splitter 16 to the input of the sensing element 14, and the other part through the splitter 17 to the input of the sensing element 15. To remove part of the probing radiation optical couplers 22, 23 may be used installed in the communication channel 18. With the passage of the probe radiation in the optical fiber of the first sensitive element 14, Rayleigh scattering occurs, a useful signal arises, which propagates in the opposite direction and enters through the splitter 16 into the second communication channel 19 of the FOCL 21 and then to the first receiver 12 of optical radiation, where it is detected. With the passage of the probe radiation in the optical fiber of the second sensitive element 15, Rayleigh scattering occurs, a useful signal appears, which propagates in the opposite direction and enters through the splitter 17 into the third communication channel 20 of the FOCL 21 and then to the second receiver 13 of optical radiation, where it is detected. Moreover, the communication channels 18, 19, 20 of the fiber optic link 21 provide the transmission of optical radiation (transmitter pulse and useful signal) with the required characteristics.

The location of the vibro-acoustic impact on the first sensitive element 14 is determined by analyzing the signal of the first receiver 12 of optical radiation by the delay T _{s1 of the} optical signal:

T _s1 = t ₁ + t ₂ + 2z ₁ / ν,

where z ₁ is the distance along the optical fiber from the side of the splitter 16 from the end of the first sensor 14 to the place of vibroacoustic impact, t ₁ , t ₂ are the delay times in the fiber optic link 21 during the propagation of the optical signal from the transmitter 11 to the first sensor 14 and from the first sensitive element 14 to the first receiver 12, respectively, ν is the group speed of light in the optical fiber. Thus, the location of the vibroacoustic impact on the first sensing element 14 is determined uniquely, provided that when

where L _1E is the length of the first sensor 14.

The location of the vibro-acoustic effect on the second sensitive element 15 is determined by analyzing the signal of the second receiver 13 of optical radiation by the delay T _{s2 of the} optical signal:

where z ₂ is the distance along the optical fiber from the side of the splitter 17 from the end of the second sensitive element 15 to the place of vibroacoustic impact, t ₃ , t ₄ are the delay times in the FOCL 21 when the optical signal propagates from the transmitter 11 to the second sensitive element 15 and from the second sensitive element 15 to the second receiver 13, respectively. Thus, the location of the vibro-acoustic impact on the second sensing element 15 is determined uniquely, provided that when

where L _2E is the length of the second sensing element 15.

The lengths of all the sensitive elements 14, 15 can be chosen equal to achieve the maximum total length of the sensitive elements 14, 15 with a fixed delay between pulses, which determines the range of recorded frequencies.

The location of the vibro-acoustic impact is determined by the number of receivers 12, 13 of the optical radiation and the delay of the optical signal.

Thus, unlike the closest analogue, with the same total length of the monitored section of the extended object, the device (Fig. 2) allows to increase the pulse repetition rate, which leads to an increase in the frequency range of recorded vibrations, which, in turn, increases the accuracy of detecting the location of the intrusion.

The use of only one optical radiation transmitter 11 for several sensitive elements 14, 15 with an increase in the total length of all sensitive elements 14 and / or 15 and their number leads to the preservation of the main technical result while simplifying the design as a whole.

Since in the claimed device the delay times for all communication channels are constant, it is possible to uniquely determine the location of the vibroacoustic impact with a minimum time delay T _min between the probe pulses of the optical signal

where L is the length of the largest sensing element 14 or 15.

And since L can be several times smaller than the total length of the sensitive elements 14 and 15, and the length of the controlled extended object, T _min can be reduced by several times, and thereby increase the range of recorded frequencies of vibroacoustic effects.

The device (Fig. 3) for monitoring the vibro-acoustic characteristics of an extended object works as follows.

The probe radiation in the form of an optical pulse from the optical radiation transmitter 31 is propagated through the FOCL communication channel 38 and enters through the first splitter 36 to the input of the first sensing element 34 and then, passing through the sensing element 34, enters through the second splitter 37 to the input of the second sensing element 35 . With the passage of probe radiation in the optical fiber of the first sensing element 34, Rayleigh scattering occurs, a useful signal appears, which propagates in the opposite direction. direction and enters through the first splitter 36 into the second communication channel 39 of the fiber optic link 41 and then to the first receiver 32 of optical radiation, where it is registered. With the passage of the probe radiation in the optical fiber of the second sensing element 35, Rayleigh scattering occurs, a useful signal arises, which propagates in the opposite direction and enters through the third splitter 37 into the third communication channel 40 of the FOCL 41 and then to the second receiver 33 of optical radiation, where it is detected. Moreover, the communication channels 38, 39, 40 of the fiber optic link 41 provide the transmission of optical radiation (transmitter pulse and useful signal) with the required characteristics.

The location of the vibro-acoustic effect on the first sensitive element 34 is determined by analyzing the signal of the first receiver 32 of optical radiation by the delay Τ _{s11 of the} optical signal:

T _s11 = t ₁₁ + t ₁₂ + 2z ₁₁ / ν,

where z ₁₁ is the distance along the optical fiber from the side of the first splitter 36 from the end of the first sensor element 34 to the place of vibroacoustic impact,

t ₁₁ , t ₁₂ - delay times in the fiber optic link 41 during the propagation of the optical signal from the transmitter 31 to the first sensor 34 and from the first sensor 34 to the first receiver 32, respectively.

The location of the vibro-acoustic effect on the second sensitive element 35 is determined by analyzing the signal of the second receiver 33 of optical radiation by the delay T _{z12 of the} optical signal:

where z ₁₂ is the distance along the optical fiber from the side of the second splitter 37 from the end of the second sensitive element 35 to the place of vibroacoustic impact, t ₁₃ , t ₁₄ are the delay times in the fiber optic link 41 during the propagation of the optical signal from the transmitter 31 to the second sensitive element 35 and from the second the sensing element 35 to the second receiver 33, respectively.

The device shown in FIG. 3, uses three communication channels 38, 39, 40 of the FOCL 41, and the device of FIG. 2 - three communication channels 18, 19, 20 of the FOCL 21. But in the device of FIG. 2, the communication channel 18 serves to supply a signal from the transmitter 11 to both the first sensor 14 and the second sensor 15. In the device shown in FIG. 3, the communication channel 38 of the FOCL 41 serves to supply a signal to the first sensor 34. Therefore, the device shown in FIG. 3 is comparatively simpler, while the devices of FIG. 2 is more complex, but also more reliable, since in the device of FIG. 3, the pulse, before entering the second sensor element 35, propagates through the first sensor element 34, where it may experience various kinds of distortions, while in the device of FIG. 2, the pulse enters the second sensitive element 15, bypassing the first sensitive element 14, passing through the first communication channel 18 of the FOCL 21, which is capable of transmitting the pulse without distortion. The splitters 16, 17 (FIG. 2) and 36, 37 (FIG. 3) are known components that do not introduce additional pulse distortions.

Thus, the claimed device allows, including segmented, to monitor the vibro-acoustic characteristics of an extended object, unlimited length associated with the attenuation of the optical signal in the optical fiber, and / or monitoring an extended object, remote at a significant distance of several hundred kilometers from the registration point .

Using the invention allows you to quickly detect violations of the integrity of the shell of an extended object or to fix any effects from the inside or from the outside to an extended object. Moreover, the device allows you to determine the coordinates of the location of the defect or the point of impact on the object.

The most successfully declared “Device for monitoring the vibro-acoustic characteristics of an extended object (options) is industrially applicable in production wells, during transportation of well products, as well as for determining the location of intrusion into an extended object.

Claims (7)

1. A device for monitoring the vibro-acoustic characteristics of an extended object, comprising an optical radiation transmitter, an optical radiation receiver, a sensing element made in the form of an optical fiber longitudinally relative to the extended object, a splitter, the optical radiation transmitter and the optical radiation receiver being connected via fibers to the splitter to sensitive element, characterized in that the fiber channels used are fiber-optic communication channels transmission line, the length of which is not less than half the length of the sensitive element, and one optical radiation transmitter, two sensitive elements, two optical radiation receivers and two splitters, and three communication channels of the optical fiber transmission line are used, while the output of the optical radiation transmitter is connected only one first communication channel of the fiber-optic transmission line to each of the inputs of two splitters, each of which is respectively connected to one of the sensitive elements On the other hand, the output of one of the splitters is respectively connected through the second communication channel of the fiber-optic transmission line to the input of one receiver of optical radiation, and the output of the other from the splitters through the third communication channel to the input of another receiver of optical radiation. 2. The device according to claim 1, characterized in that optical couplers and an optical amplifier are inserted into the first communication channel of the fiber-optic transmission line, the output of the optical radiation transmitter is connected by the first communication channel of the fiber-optic transmission line to each of the inputs of the two splitters through optical couplers and the optical amplifier is installed in the first communication channel of the fiber-optic transmission line between the optical couplers. 3. The device according to claim 1, characterized in that the optical amplifiers are introduced and the coupler outputs are respectively connected to the inputs of the optical radiation receivers through optical amplifiers. 4. The device according to p. 1, characterized in that the lengths of all sensitive elements are equal. 5. A device for monitoring the vibro-acoustic characteristics of an extended object, comprising an optical radiation transmitter, an optical radiation receiver, a sensing element made in the form of an optical fiber located longitudinally relative to the extended object, a splitter, the optical radiation transmitter and the optical radiation receiver being connected via fibers to the splitter to sensitive element, characterized in that the fiber channels used are fiber-optic communication channels transmission line, the length of which is not less than half the length of the sensitive element, and one optical radiation transmitter, two sensitive elements, two optical radiation receivers and two splitters, and three communication channels of the optical fiber transmission line are used, while the output of the optical radiation transmitter is connected only one first communication channel of the fiber optic transmission line to the input of the first splitter, which is connected to one end of the first sensor element, which is opposite the false end is connected to the input of the second splitter connected to the second sensitive element, the output of one of the splitters is respectively connected through the second communication channel of the fiber-optic transmission line to the input of one optical radiation receiver, and the output of the other from the splitters by the third communication channel to the input of another receiver optical radiation. 6. The device according to p. 5, characterized in that the outputs of the splitters are respectively connected to the inputs of the optical radiation receivers through optical amplifiers. 7. The device according to claim 5, characterized in that the first sensitive element is connected to the input of the second splitter through an optical amplifier.

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