EA026181B1 - Device for optical identification of measurement channels of a built-in non-destructive control system based on fiber-optic bragg gratings - Google Patents

Abstract

The invention relates to devices for registering signals from a set of fiber-optic Bragg gratings in a built-in non-destructive object control system. The device for optical identification of measurement channels in a built-in non-destructive control system comprises a source of optical radiation, a tripolar optical splitter, a reference Bragg grating having a known reflected radiation wavelength, several measurement channels with fiber Bragg gratings located on the object being tested, a system for insulating the reference Bragg grating from external disturbing effects, a photodetector device and a unit for registering and converting signals, said unit being connected to a computer. One addressable reference Bragg gratings having non-repeating reflected radiation wavelengths is built into each measurement channel. All reference gratings are placed in a body insulated for protection against external disturbing effects. A superluminescent diode (SLD) is used as a continuous broad-band source of optical radiation. The device further includes an optical insulator and an optical switch, the optical insulator being installed between the output of the source and the input pole of the tripolar optical splitter, one output pole of which is connected to the common input of the optical switch. Each connectable output of the optical switch is connected to its own measurement channel. The other output pole of the splitter is connected to an input of the photodetector device and of the signal registering and converting unit. The technical result is simultaneous significant simplification of the device circuit with warranted assurance of reliability of identification (addressing) of measurement channels connected to the computer, and an increase in dynamic range of optical signals being measured.

Description

The invention relates to devices for measuring devices with optical measuring instruments, and in particular to devices for recording signals from a set of fiber-optic Bragg sensors of the integrated non-destructive testing (WSS) system of an object.

State of the art

There are many VNK devices based on fiber-optic Bragg sensors, in particular, in RF patent No. 2377497 DEVICE FOR MEASURING DEFORMATIONS BASED ON QUASI-DISTRIBUTED FIBER-OPTICAL SENSORS ON BREGG SIZES 11 MPK0116. 12/27/2009.

However, the patent describes a single-channel device for measuring deformations (including, possibly, temperature deformations) of an object. It should be noted that for a multi-channel system, an additional device is necessary for reliable identification of the measuring channels of the VNK system.

There are schemes with the use of optical switches, which carry out the address-based connection of the measuring channels, one at a time, to the basic measuring system. The switches switch the channel according to the address signals coming from the computer. However, the reliability of this switching method is insufficient for use in VNK systems, since there is a certain probability of incorrect operation of the switch due to the unreliability of the transmission of electrical signals from a computer.

Existing typical multichannel measuring systems based on fiber-optic Bragg sensors are often built using optical splitters that simultaneously connect the measuring channels to the measuring system, and because of this there is no problem of erroneous addressing of the measuring channels.

The authors consider the closest analogue of the proposed device to be a wavelength polling device (US Pat. Nos. 7,157,693, publ. 02/01/2007, and 7,060,967, publ. 06/13/2006) with a system of optical splitters (and without the use of optical switches). The scheme is based on a configuration of one reference and several measuring units. An analog device contains several fiber-optic measuring lines with fiber Bragg gratings, a reference (calibration) block with a reference (calibration) fiber Bragg grating for calibrating the signals of the measuring channels on a wavelength scale, an optical source tunable along the wavelength, for example, a tunable laser to generate radiation, which separated by an optical splitter and enters the reference block and into several measuring lines with fiber Bragg gratings.

The support unit is a calibration system on a wavelength scale, the role of the calibration system can be performed by a fiber Bragg grating, an interference filter with a fixed free spectral range, for example, a Fabry-Perot etalon, gas absorption cells, or any combination of these elements. The reference block determines the reference wavelength of the tunable source; for this, the output signal of the reference block is used for feedback in order to adjust and stabilize the wavelength of the source, which makes it possible to measure the absolute values of the wavelengths of the gratings of the measuring channels. For this, part of the radiation from the source is allocated by the first splitter along the chain of the splitters system to a photodetector (FPU) of the reference block. One of the branches of the splitters system directs part of the radiation to the reference fiber Bragg grating with predetermined characteristics, which is under constant external conditions for high wavelength stability of the radiation reflected from it. Radiation reflected from the support grating passes through a splitter in the FPU of the support block.

The output signals from the fiber-optic measuring lines are connected to a number of measuring blocks separately from the reference block. A complex system of optical splitters diverts part of the source radiation in the line of fiber Bragg gratings (sensors). The optical signals reflected from the fiber Bragg gratings pass back through the couplers and pass to the FPU of the measuring units. The number of the connected channel is determined by the FPU number of the corresponding measuring unit, the signal from which is read and processed in the computer.

The disadvantage of this device should be considered the complexity of its circuit, including, for example, the presence of a complex tunable laser source and feedback of the output signal of the reference block in order to adjust and stabilize the wavelength of the source, and a reduced dynamic range of the measured signals of the circuit due to the fact that measuring channels are connected to the outputs simultaneously (and the more measuring channels, the proportionally lower will be the dynamic range of the measured signals. Dynamic range is the power level spine in dB signals, which is capable of measuring the measurement system).

Disclosure of invention

The complex task of the proposed solution is the simultaneous substantial simplification of the device circuit with guaranteed reliability of identification (addressing) of the measuring channels connected to the computer, and an increase in the dynamic range of the measured optical signals.

The technical result is achieved by using a continuous wide-band source of radiation in the device, for example, a superluminescent diode (SLD), an optical switch, and integrating into each measuring channel one reference fiber Bragg grating with a wavelength previously known and not repeated in other channels reflected radiation, and all the supporting lattices are placed in a separate housing with a thermal stabilization system and possible isolation from other external disturbing conditions. At the same time, guaranteed reliability of the measuring system is ensured due to the optical identification of the measuring channel connected via an optical switch to the common measuring system and then to the computer. The signal of the reference Bragg grating with a stable wavelength of reflected radiation will unambiguously give information about the number (address) of its measuring channel in which this reference grating is placed in series with other working measuring Bragg gratings. Since the device uses an optical switch that connects to the measuring system through a single measuring channel by the signal from the computer, from the point of view of simplifying the circuit, this makes it possible to use only one FPU for receiving signals, unlike many FPUs in the closest analogue circuit.

Thus, the proposed device for optical identification of the measuring channels of the built-in non-destructive testing system based on fiber-optic Bragg sensors contains an optical radiation source, a three-pole optical splitter, a support Bragg grating with a known characteristic of the reflected wavelength, several measuring channels with measuring fiber Bragg gratings located at the control object, the insulation system of the support grid from external disturbing air actions, including a thermal stabilization system; FPU and block registration and conversion of signals, which is connected to a computer. Moreover, address support gratings with non-repeating characteristics of the reflected radiation wavelengths are one built into each measuring channel. All support grids are housed in a housing with a system of isolation from external disturbing conditions. A superluminescent diode (SLD) is used as a continuous broadband optical radiation source. Additionally, there is an optical isolator and an optical switch, and an optical isolator is installed between the source output and the input pole of a 1x2 three-pole splitter, one output pole of which is connected to a common input of the optical switch. Each connected output of the optical switch is connected to its measuring channel. The other output pole of the splitter is connected to the input of the FPU and the unit for recording and converting signals.

The drawing shows a structural block diagram of the proposed device.

The implementation of the invention

As a continuous broadband radiation source, a superluminescent diode (SLD) 1 is used. Insulator 2, installed in series with the SLD, prevents back reflection in the SLD. The output of the insulator 2 is optically connected to the input pole of a 1x2 3-pole splitter, labeled 3 in FIG. 1, and through its output pole, with the input of the 1xY 4 optical switch, to the outputs of which are connected N (for example, N = 16) measuring channels 7 containing fiber Bragg gratings. One measuring Bragg grating 5 and several measuring Bragg gratings, for example, for measuring temperatures and deformations, are built into each measuring channel 7. Each reference fiber Bragg grating 5 has known characteristics and is integrated in the housing with a thermal stabilization system 6, thereby eliminating the influence of external factors, and the wavelength of the reflected radiation from each reference grating remains stably constant. The second output pole of the three-pole splitter 3 is connected to the input of the FPU and the signal recording and conversion unit 8, the output of which is connected to a computer 9, which displays and processes the measurement results.

The device operates as follows. When a measuring channel is connected (via an addressable electrical signal from a computer) through an optical switch, the FPU captures the reflection spectrum of all fiber Bragg gratings located in the measuring channel, including the reference grating, and the wavelengths of reflected radiation from all the gratings in this channel are determined, including and from the supporting Bragg grating. An addressable electrical signal from a computer does not have the required level of reliability, therefore, by the value of the wavelength of the reflected radiation from the reference grating, the number (address) of the connected measuring channel is uniquely determined with the guaranteed level of reliability. Obtained in block 8 according to the characteristics of the reference lattice, a guaranteed reliable address (number) of the channel is taken into account in the computer 9 during the subsequent reading of the measurement information from the connected measuring channel of the VNK system.

Thus, in the proposed device provides a simultaneous significant simplification of the device circuit with guaranteed reliability of identification (addressing) of the measuring channels connected to the computer, and an increase in the dynamic range of the measured optical signals.

Claims (1)

CLAIM An optical identification device for measuring channels of an integrated non-destructive testing system based on fiber-optic Bragg sensors, comprising an optical radiation source, a three-pole optical splitter, several measuring channels with fiber measuring Bragg gratings placed on the test object; photodetector (FPU) and a unit for recording and converting signals for communication with a computer, characterized in that each measuring channel includes an address reference grid with a different wavelength for reflected radiation than other reference grids, all address reference grids being housed in an enclosure with an insulation system from external disturbing conditions, including those with a thermal stabilization system; A superluminescent diode is used as a continuous broadband optical radiation source; additionally there is an optical isolator and an optical switch, and an optical isolator is installed between the source output and the input pole of a three-pole splitter, one output pole of which is connected to the common input of the optical switch, each connected output of which is connected to its measuring channel and the other output pole of the splitter is connected to the input FPU and block registration and conversion of signals.