RU192121U1 - Sensor interrogator - Google Patents

Abstract

The invention relates to the field of measurement technology and relates to a device for interrogating a sensitive element. The device includes a laser radiation generator with a pulsed laser and a fiber optic amplifier, a spectral filter of scattering components, at least two photodetector modules and a signal processing unit. The fiber optic amplifier contains an insulator, an active fiber, a multiplexer, and a pump laser. The spectral filter of the scattering components contains at least two demultiplexers with thin-film filters pigmented with optical fiber. The technical result consists in increasing the manufacturability of the device. 6 c.p. f-ly, 1 ill.

Description

[001] Technical Field

[002] The technical solution relates to the field of measurement technology and can be used in means for distributed temperature measurement, as well as for measuring the temperature distribution along a fiber optic cable in long objects used in areas related to safety, for example, fire alarm systems in automobile, railway or service tunnels; thermal control of power cables and overhead transmission lines to optimize production relations; improving the efficiency of oil and gas wells; ensuring the safe working condition of industrial induction melting furnaces; tightness control of containers with liquefied natural gas on ships in unloading terminals; leak detection at dams and dams; temperature control in chemical processes; leak detection in pipelines.

[003] Background Art

[004] A fiber-optic device for measuring the temperature distribution is known (patent RU 2413188 C2, IPC G01K 11/32, G02B 6/43, published February 27, 2011) comprising a pulsed probe radiation source, a directional optical coupler, a sensitive element, a recording system and a signal processing unit. The sensitive element is made in the form of a single-mode optical fiber. The directional optical coupler separates the Rayleigh component and is connected in series to one or more additional directional optical coupler that also separates the Rayleigh component. An additional directional optical coupler is connected in series with one or more directional optical couplers that separate the Stokes and anti-Stokes components of the scattered radiation. The radiation components are sent to the photodetector modules of the registration system. A fiber Bragg grating is integrated between the directional couplers. The pulse source of the probing radiation is a pulsed fiber laser or a pulsed semiconductor laser. To increase the power of a pulsed probe radiation source, a fiber optic amplifier or a semiconductor amplifier with fiber outputs is introduced in series. An option is a device in which a switch is additionally inserted, connected to the input of one of the photodetector modules. In this case, a pulsed semiconductor laser operates at a wavelength of the anti-Stokes component and is connected to one of the circulator inputs.

[005] A disadvantage of the known device is that the fiber filter on the Bragg grating is an unstable element that is influenced by temperature factors, which reduces the reliability of the device. In this case, when using a filter on a Bragg grating, the spectrum of the laser should approach the working spectrum (Bragg gratings should have the same wavelength as the pulsed laser). The spectra of pulsed lasers, as well as the spectra of gratings, are determined during production and sometimes can slightly deviate from the expected values. This affects the manufacturability of the device, since it is necessary to measure the spectra of lasers, spectra of gratings and select pairs of "laser filter". The spectra of the gratings depend on the fiber tension, which is difficult to control during the assembly process, which also impairs the manufacturability of the device. The use of Bragg gratings does not allow the use of different types of lasers with different spectra.

[006] Terms and definitions used in this application.

[007] A sensing element is an interrogated line in the form of an optical fiber, which can be included in various cable structures and is made both single-mode and multi-mode, including a standard telecommunication optical fiber.

[008] Spectral filter of scattering components — a spectral filter that separates components, for example, a Raman spectral filter that separates the Rayleigh, Stokes and anti-Stokes scattering components based on the Raman effect, including demultiplexers with thin-film filters pigmented with optical fiber.

[009] Fiber optic amplifier is a fiber optic amplifier based on a rare-earth element or rare-earth elements, the composition of the amplifier includes an active optical fiber mixed with a rare-earth element, for example, erbium fiber, ytterbium fiber, erbium-ytterbium fiber, etc.

[0010] An active fiber is a piece of fiber whose core is doped with rare earth ions or rare earth ions, for example, erbium, ytterbium, erbium-ytterbium, etc.

[0011] A brief description of a utility model.

[0012] The objective of this utility model is to create a high-tech and more simple and reliable device for interrogating a sensitive element.

[0013] The technical result is to increase the manufacturability of a device for interrogating a sensitive element.

[0014] The technical result is achieved by the fact that the interrogation of the sensitive element includes a laser radiation with a pulsed laser and a fiber optic amplifier, a spectral filter of scattering components, at least two photodetector modules, a signal processing unit, a fiber optic amplifier includes an active fiber, pump laser, multiplexer and isolator.

[0015] The spectral filter of the scattering components contains demultiplexers with thin-film filters pigmented with optical fiber, the use of which allows to increase the manufacturability of the device for interrogating the sensitive element due to the fact that such a filter is stable in characteristics during the assembly of the entire device, and it also makes it possible to use lasers of different types, since the working spectrum of the spectral filter of scattering components based on a thin-film filter allows you to work with a laser without spectrum matching, accordingly, it is not necessary to select “laser-filter” pairs, simplifying the assembly process of the device. In addition, the characteristics of such a filter depend little on temperature factors and do not affect the operating temperatures of the entire device.

[0016] On the other hand, the laser generator has oppositely directed pumping to a pulsed laser. For oppositely directed pumping to a pulsed laser along its optical path of radiation propagation in a fiber-optic amplifier, the active fiber is located in front of the multiplexer. In this case, the core of the active fiber is doped with ions of the rare-earth element, which can be used as erbium or ytterbium, or erbium-ytterbium. Opposite directional pumping increases the efficiency of the fiber-optic amplifier, less active fiber is required, and manufacturability is increased. The use of insulators increases the stability and reliability of the operation of a device for interrogating a sensitive element, which together leads to an increase in the manufacturability of the device.

[0017] Description of the drawings.

[0018] FIG. 1 shows a diagram of a device for interrogating a sensitive element.

[0019] Positions in the drawings:

[0020] 1 is a current driver of laser diodes,

[0021] 2 is a first fiber optic isolator,

[0022] 3 - active fiber,

[0023] 4 is a multiplexer,

[0024] 5 is a second fiber optic isolator,

[0025] 6 is a spectral filter of scattering components,

[0026] 7 - a thermostat,

[0027] 8 is a calibration segment of an optical fiber,

[0028] 9 - temperature sensor

[0029] 10 is a fiber optic switch,

[0030] 11 is a sensing element,

[0031] 12 is a pulsed laser,

[0032] 13 is a pump laser,

[0033] 14 is a second photodetector module,

[0034] 15 is the first photodetector module,

[0035] 16 - analog-to-digital Converter (ADC),

[0036] 17 is a microcontroller,

[0037] 18 is a first demultiplexer,

[0038] 19 is a second demultiplexer.

[0039] A detailed description of a utility model.

[0040] The following detailed description of a utility model implementation provides numerous implementation details to provide a clear understanding of the present utility model. However, it will be obvious to a specialist skilled in the subject field how to use a real utility model, both with and without these implementation details. In other cases, well-known methods, procedures, and components have not been described in detail so as not to impede unnecessarily understanding the features of this utility model.

[0041] Furthermore, it will be clear from the foregoing that the utility model is not limited to the foregoing implementation. Numerous possible modifications, changes, variations and replacements that preserve the essence and form of a real utility model will be obvious to qualified specialists in the subject field.

[0042] A sensing element interrogation device for distributed fiber optic temperature sensors, which makes it possible to obtain a temperature distribution profile along the optical fiber. In the housing of the device for interrogating a sensing element in the form of an optical fiber (Fig. 1), a laser radiation generator, a spectral filter of scattering components, at least two photodetector modules, a signal processing unit, a thermostat, and a fiber optic switch are located.

[0043] The laser radiation generator comprises a current driver of laser diodes 1, pigmented with an optical fiber, a pulsed laser 12, a fiber optic amplifier, in which the first fiber optic insulator 2, active fiber 3, multiplexer 4 and the second fiber optic insulator 5 are arranged in series and the pump laser 13 is connected to at least one output of the multiplexer 4. The current driver of the laser diodes 1 is connected to the signal processing unit by a high-frequency cable.

[0044] As a pulsed laser 12, for example, laser diodes, fiber lasers, LEDs can be used without additional matching of the amplification circuit.

[0045] The first fiber optic insulator 2 allows you to protect the laser from spontaneous emission from the active fiber 3, it works with minimal attenuation in the forward direction and maximum attenuation in the opposite. The second fiber optic isolator 5 further protects the pulsed laser. The use of insulators increases the manufacturability of the polling device of the sensitive element.

[0046] The core of the active fiber is doped with ions of a rare-earth element or rare-earth elements, which can be used erbium or ytterbium, or erbium-ytterbium, etc. Thus, the active fiber can be represented as erbium fiber or ytterbium fiber, or erbium-ytterbium fibers, etc. The most commonly used fiber optic amplifiers with active fiber in the form of erbium fiber. The principle of oppositely directed pumping and active fiber is given below. Erbium fiber is chosen as an example. At the beginning of the path of radiation from a pulsed laser through an erbium fiber, the lowest gain is observed, toward the end of the erbium fiber, the highest intensity of pulsed radiation and the highest gain. Due to the fact that the intensity of pulsed radiation increases as it passes through an erbium fiber, at which the gain increases at the same time, which increases the efficiency of the amplifier, less erbium fiber is required, and manufacturability is increased. Also, this arrangement affects the fact that the pump laser operates at lower currents through the laser, which increases its durability and the reliability of the operation of the interrogation device of the sensitive element.

[0047] The spectral filter of the scattering components 6 contains two demultiplexers 18 and 19 with thin film filters pigmented with an optical fiber. The input of the first demultiplexer 18 is connected to the output of the second fiber optic isolator 5. One of the outputs of the first demultiplexer 18 is connected to the input of the second demultiplexer 19, and the other output is connected to the first photodetector module 15, which receives the anti-Stokes component. One of the outputs of the second demultiplexer 19 is connected to the thermostat 7, and the other output is connected to the second photodetector module 14, which receives the Stokes component. To simplify the procedure for calibrating temperature readings, the Stokes and anti-Stokes Raman components are used simultaneously.

[0048] The signal processing unit includes an analog-to-digital converter (ADC) 16 and a computer (microcontroller) 17. The ADC digitizes the signals from the photodetectors. The microcontroller performs the mathematical calculation of the digitized signals in the temperature readings. The photodetector modules 14, 15 are connected to the ADC 16. The thermostat 7 is connected to the microcontroller 17 and contains a calibration segment of the optical fiber 8, a temperature sensor 9.

[0049] The fiber-optic switch 10 contains one input and many outputs, allowing the sensing elements 11 to be connected using an electrical control signal. The fiber-optic switch 10 allows sequentially measuring the temperature in N sensitive elements 11, and to interrogate more lines (sensitive elements) with one device .

[0050] Principle of operation of a device for interrogating a sensing element.

[0051] The radiation from the pulsed laser 12, for example, in the form of a pulsed laser diode, propagates to the input of the first fiber optic insulator 2. After the insulator, erbium fiber 3 is located in the form of a fiber segment, the core of which is doped with erbium ions, so that the fiber is capable of absorbing energy transported by light at a wavelength of 980 nm and reemit it at 1550 nm. Erbium fiber 3, on the other hand, is connected to a spectral multiplexer 4, which has one port at the input and two ports at the output. On the other hand, where it has one port, two wavelengths propagate in the fiber, and at the output of multiplexer 4, each of the wavelengths propagates through its own separate port. The output spectral multiplexer 4 is connected by one port to a pump laser at a wavelength of 980 nm 13, the radiation of which pumps erbium fiber 3, and by the second port it is connected to the first demultiplexer with thin-film filters pigmented with an optical fiber, between the multiplexer 4 and the spectral filter of components scattering 6 is a second fiber optic insulator 5. Demultiplexers break down the backscattering into components: stokes, antistokes and Rayleigh. The stokes and antistokes are sent to the photodetector modules 14, 15. From the line of the optical fiber (sensing element 11), three scattering components fall into the input of the first demultiplexer 18 with thin-film filters pigmented with optical fiber: the Stokes component of Raman scattering, the Rayleigh component and the anti-Stokes component of scattering. The demultiplexer divides the spectrum into two parts and everything below the cutoff wavelength falls into one channel, everything that is larger than the cutoff wavelength falls into the other. Thus, the first demultiplexer 18 divides the spectrum so that only the anti-Stokes component falls into one channel, and the Stokes and Rayleigh components fall into the other. The anti-Stokes component is fed to the first photodetector 15. The Stokes and Rayleigh scattering components propagate into the second demultiplexer 19, but with a different cut-off wavelength, which divides the spectrum into two parts, separating the Stokes component and the Rayleigh component. The Stokes component is fed to the second photodetector 14.

[0052] After the spectral filter of the scattering components, there is a thermostat 7 with a calibration segment of the optical fiber 8, the temperature of which is measured by the temperature sensor 9. Reflectograms from the segment in the thermostat 7 allow the calculation of calibration coefficients.

[0053] At the photodetector modules 14, 15, the optical signal of the OTDR signals is converted to electric. Also, photodetector modules amplify the signal. Then the amplified signal via high-frequency cables goes to the input of the ADC 16. The ADC transmits data to the microcontroller 17, the information from the temperature sensor 9 is also transmitted there. The computer recalculates the scatter traces to the temperature distribution along the optical fiber.

[0054] In the present application materials, a preferred disclosure was provided for the implementation of the claimed technical solution, which should not be used as limiting other, private embodiments of its implementation, which do not go beyond the scope of the requested legal protection and are obvious to specialists in the relevant field of technology.

Claims (9)

1. A device for interrogating a sensitive element, including a laser radiation generator with a pulsed laser and a fiber optic amplifier, a spectral filter of scattering components, at least two photodetector modules, a signal processing unit, fiber optic amplifier contains an insulator, active fiber, multiplexer, a laser pump; The spectral filter of the scattering components contains at least two demultiplexers with thin-film filters pigmented with an optical fiber. 2. The device for interrogating a sensitive element according to claim 1, characterized in that the laser radiation generator has oppositely directed pumping by a pulsed laser. 3. The device for interrogating a sensitive element according to claim 1, characterized in that in the fiber optic amplifier of the laser radiation generator, the active fiber is located in front of the multiplexer. 4. A device for interrogating a sensitive element according to claim 1, characterized in that the core of the active fiber is doped with rare-earth ions. 5. The device for interrogating a sensitive element according to claim 4, characterized in that erbium, or ytterbium, or erbium-ytterbium is used as a rare-earth element. 6. The device for interrogating a sensitive element according to claim 1, characterized in that erbium fiber is used as an active fiber in a fiber optic amplifier. 7. The device for interrogating a sensitive element according to claim 1, characterized in that the fiber-optic amplifier of the laser radiation generator further comprises an insulator.

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