KR20100024743A - Interrogator for structure using fiber bragg grating - Google Patents

Abstract

PURPOSE: An interrogator for structure using optical fiber rating is provided to accurately measure the displacement caused by the deformation ratio of a structure in a prompt way. CONSTITUTION: A relay unit(22) compares and reads out various frequencies of light sources received through a circulator(14), and a displacement calculating unit(30) receives and stores the signal transmitted from the relay unit. The display calculating unit calculates the displacement of the stored signal, and a wireless transmission unit(40) transmits a signal, which is received to the displacement unit, through wireless communication. The relay unit, the display calculating unit and the wireless transmission unit is integrated with the inner portion of the housing.

Description

INTERROGATOR FOR STRUCTURE USING FIBER BRAGG GRATING}

The present invention relates to an interrogator of a structure using an optical fiber grating sensor, and in particular, an optical fiber grating capable of measuring displacement by analyzing strain caused by external forces such as load, stress, and temperature applied to the structure using the optical fiber grating sensor. The present invention relates to an interrogator of a structure using a sensor.

As the society is advanced and the industrial infrastructure is enlarged, the necessity of safety diagnosis technology to effectively judge the safety of bridges, dams, tunnels, large buildings, etc., and to take proper maintenance is increasing.

Such large structures can cause catastrophic catastrophes, including industrial damage and casualties, during collapse and accidents.

Currently, safety diagnosis is mainly performed using existing electrical strain gauges, but this has the disadvantage of inconvenient construction and long time to observe several points at the same time.

In addition, the strain gages are affected by the electrical noises of the surroundings, so that accurate measurement is difficult and there are technical limitations depending on the length of the electric cable.

In addition, there is a problem that the sensor is damaged by lightning and corrosion when the strain gauge is placed on the structure for a long time for constant measurement.

The present invention has been made in order to solve the problems of the prior art as described above, the object of the present invention is to inject a predetermined light source from a wide-area light source to a plurality of optical fiber grating sensor mounted on the structure and to the external force applied to the structure Accordingly, the present invention provides an interrogator of a structure using an optical fiber grating sensor, which analyzes a light source that is deformed and reflected from the optical fiber grating sensor using an interrogator to measure displacement due to strain of the structure.

In order to solve the above technical problem, the present invention,

The optical fiber lattice sensor is mounted on the structure and the optical fiber lattice sensor incident through the circulator comes out of the light source of a predetermined wavelength from the broadband light source during displacement measurement, and

And including an interrogator for measuring the strain of the structure by receiving a light source reflected from each specific wavelength of the optical fiber grating sensor through a circulator according to the external force applied to the structure after the light source is incident to the optical fiber grating sensor,

The interrogator may include a relay unit for reading and transmitting various frequencies of a light source received through a circulator in comparison with a pre-input signal;

A displacement calculator for receiving and storing a signal transmitted from the relay unit and calculating a displacement of the stored signal, and

It is composed of a wireless transmitter for transmitting the signal received by the displacement calculator via wireless communication.

In addition, the relay unit, the displacement calculation unit, and the wireless transmission unit is provided integrally inside the housing.

The displacement calculator may include a receiver for receiving a signal transmitted from the relay unit;

A memory unit for storing the signal received by the receiving unit;

A control unit for calculating a displacement of the signal stored in the memory unit and converting the signal into an image signal;

A printed circuit board on which the receiving unit, the memory unit, and the control unit are mounted;

It is composed of a power supply for supplying power to the printed circuit board.

In addition, the housing is provided with a display unit for outputting the displacement calculated from the displacement calculator as an image.

In addition, the display unit is made of a touch LCD.

In addition, the wireless transmission unit performs communication of any one of wireless LAN, WiBro, code division multiple access, Zigbee, Bluetooth, and ultra-wideband.

In addition, the displacement calculator is provided with a LAN connection for transmitting a signal stored in the memory unit via a wired communication.

In addition, the housing is further provided with a temperature control device.

The interrogator of the structure using the optical fiber stop sensor according to the present invention is a light source having a specific wavelength reflected from the optical fiber grating sensor according to the external force applied to the structure, the broadband light source is incident on a plurality of optical fiber grating sensors mounted on the structure By receiving and analyzing in real time, it has a useful effect to quickly and accurately measure the displacement caused by the strain of the structure under external force.

In addition, by transmitting a signal of the light source received from the optical fiber grating sensor by wireless or wired communication, it is possible to easily measure the displacement of the structure by the signal transmitted in the field even in a short distance or long distance.

In addition, by the temperature control of the displacement measuring apparatus, the displacement due to the deformation of the structure can be accurately and measured regardless of the ambient temperature in an outdoor place.

Hereinafter, an interrogator of a structure using an optical fiber grating sensor according to each preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the interrogator of the structure using the optical fiber grating sensor according to an embodiment of the present invention, as shown in Figures 1 to 3, a large number is mounted on the structure and the predetermined light source in the broadband light source 12 during displacement measurement The optical fiber grating sensor 10 incident through the circulator 14 and the light source is incident on the optical fiber grating sensor 10 and then reflected at specific wavelengths unique to the optical fiber grating sensor 10 according to the external force applied to the structure. Receiving the light source through the circulator 14 is composed of an interrogator 20 for measuring the strain of the structure.

In more detail, the optical fiber grating sensor 10 is also called Fiber Bragg Grating (FBG), each has its own reflected wavelength, and receives a light source from the broadband light source 12 through the circulator 14. Reflection occurs at its own wavelength, and its own wavelength changes in the +/- direction depending on the direction of stress or the temperature due to the load applied to the optical fiber grating sensor 10 when the structure is subjected to an external force. Will occur linearly.

Since the optical fiber grating sensor 10 is made of a general optical fiber for optical communication, it is small and light, and can be mounted on the outside or inserted into the inside without affecting the function of the structure, thereby manufacturing a compact structure in which the sensor and the structure are integrated. In addition, it can be used in places where it cannot be measured by the existing electric sensor such as the environment where the electromagnetic wave is severe or the reinforcement of the composite material without being affected by the electromagnetic wave.

When the optical fiber grating sensor 10 is mounted on the structure and the light source from the broadband light source 12 is incident through the circulator 14 according to the displacement measurement of the structure, external force such as load, stress, temperature, etc. applied to the structure. By using this method, each specific wavelength (Bragg wavelength) is linearly transformed and reflected.

The structure here consists of artificial structures, including bridges, dams, tunnels, large buildings, and the like.

The broadband light source 12 is preset as a light source that may include the intrinsic reflection wavelength of the optical fiber grating sensor 10, the light source is incident to the optical fiber grating sensor 10 through the circulator 14 during the displacement measurement of the structure. At this time, the broadband light source 12 is set to have a wavelength range of approximately 1520 nm to 1590 nm.

The circulator 14 determines the optical path so that the light source from the broadband light source 12 is incident to the optical fiber grating sensor 10 and the light source incident to the optical fiber grating sensor 10 is received by the interrogator 20. Passive element to do.

That is, the passive element is a device that performs the function of the light incident in the A direction proceeds to B, the light incident in the B direction proceeds to C.

Therefore, the circulator 14 enters a predetermined light source from the broadband light source 12 toward the optical fiber grating sensor 10, and transmits the light source for measurement reflected from the optical fiber grating sensor 10 to be received by the interrogator 20. Has the function to

The interrogator 20 serves to measure the displacement according to the strain of the structure by receiving and analyzing the light source of the modified specific wavelength reflected from the optical fiber grating sensor 10, and for this purpose is received through the circulator 14. Repeater 22 for reading and transmitting various frequencies of the light source compared to the input signal, and displacement calculator 30 for receiving and storing the signal transmitted from the repeater 22 and calculating the displacement of the stored signal. And a wireless transmitter 40 for transmitting a signal received by the displacement calculator 30 through wireless communication.

In this case, the relay unit 22, the displacement calculator 30, and the wireless transmitter 40 are integrally provided inside the housing 50.

The relay unit 22 has a function of reading the frequencies of various light sources received through the circulator 14 by comparing them with previously stored signals and sending them to the displacement calculator 30.

The displacement calculator 30 receives the signal read out from the relay 22 and calculates the displacement of the stored and stored signal. For this purpose, the displacement calculator 30 receives the signal transmitted from the relay 22. (32), a memory unit (34) for storing signals received by the receiving unit (32), a control unit (36) for calculating displacements of signals stored in the memory unit (34), a receiving unit (32), The memory unit 34 includes a printed circuit board 38 including a memory unit 34, a control unit 36, and a power supply unit 39 for supplying power to the printed circuit board 38.

The receiving unit 32 is a sensor for receiving a signal transmitted from the relay unit 22 and is composed of a known receiving sensor.

The memory 34 stores the signal received by the receiver 32 under the control of the controller 36.

The control unit 36 has a function of calculating a signal stored in the memory unit 34 by a previously inputted displacement calculation module or a displacement calculation program.

In addition, the control unit has a function of converting the calculated displacement into an image signal and transmitting the same.

The printed circuit board 38 is equipped with a receiver 32, a memory 34, a controller 38, and the like.

The power supply 39 is electrically connected to the printed circuit board 38 and supplies power to operate the receiver 32, the memory 34, the controller 38, and the like.

The wireless transmitter 40 transmits a signal received by the displacement calculator 30 through wireless communication, and is provided with a wireless antenna 42 for short-range or long-range wireless communication.

That is, the wireless transmitter 40 may transmit a signal received by the displacement calculator 30 to another computer at a short distance or a long distance as needed to measure the displacement according to the strain of the structure at a place other than the site. In this case, the radio transmission of the signal by the radio transmitter 40 is performed under the control of the controller 36.

The wireless transmitter 40 is a wireless transmitter that performs wireless communication through the wireless antenna 42.

Accordingly, the wireless transmitter 40 may transmit a signal received by the receiver 32 of the displacement calculator 30 to the outside through wireless communication under the control of the controller 36.

Such a wireless transmitter 40 is composed of sensors constituting a wireless sensor network (WSN), the wireless sensor network is the information generated by the micro-sensors detect changes from various environments and wirelessly connected to the network A communication network that transmits, utilizes, and manages them in real time. Wireless communication technologies that make up a network include wireless LAN, WiBro, code division multiple access (CDMA), Zigbee, Bluetooth, and ultra wideband (UWB).

In addition, the housing 50 is provided with a LAN connection unit 56 for transmitting a signal stored in the memory unit 34 via wired communication. In this case, the LAN connection portion 56 is disposed on the front surface of the housing 50.

The LAN line may be connected to the LAN connection unit 56 to transmit a signal stored in the memory unit 34 to another computer at a short distance or a long distance to measure the displacement of the structure. At this time, the wired transmission of the signal by the LAN connection unit 56 is performed under the control of the control unit 36.

The housing 50 is provided with a display unit 52 for reproducing the video signal transmitted from the control unit 36. The display unit 52 reproduces the video signal transmitted under the control of the controller 36. The display unit 52 is disposed on the front surface of the housing 50 and is formed of a touch LCD so that each component can be manipulated by the display unit 52 as well as playback of an image signal.

On the other hand, reference numeral "57A" indicates an instruction LED that is turned on when an operation instruction of a signal stored in the memory unit 34 occurs, and "57B" indicates a sensing LED that is turned on when a result is generated after processing according to the operation instruction. , "57C" represents a memory LED that is lit to indicate the state of the memory unit 34, "57D" represents a power LED that is lit to indicate the power state.

The memory LED 57C lights up when an abnormality occurs in the memory 34, and the power LED 57D lights up when power is supplied.

The command LED 58A, the sensing LED 58B, the memory LED 58C, and the power LED 58D are controlled by the control unit 38.

In addition, "58" represents an LCD power button for turning on the display unit 40, "59A" represents a USB switch, and "59B" represents an external USB.

The displacement measuring unit 20 configured as described above may perform a function of accurately measuring and displaying the change of the peak wavelength reflected from the optical fiber grating sensor 10 up to +/− 5 pm, and the measurement is performed in real time on the program. It is possible.

Referring to the operation of the present invention having such a configuration as follows.

When measuring the displacement of the structure by the displacement measuring device of the structure using the optical fiber grating sensor according to an embodiment of the present invention, the predetermined light source first emitted from the broadband light source 12 is mounted to the structure through the circulator 14 A plurality of optical fiber grating sensor 10 is incident. At this time, the broadband light source 12 has a wavelength range of 1520 nm to 1590 nm.

As described above, when an external force such as a load, a stress, or a temperature is applied to the structure while the light source emitted from the broadband light source 12 is incident on the optical fiber grid sensor 10, the external force of the structure is transmitted to the optical fiber grid sensor 10. Will be. Then, the optical fiber grating sensor 10 has a linear deformation of its own wavelength according to the external force transmitted, that is, the load, the direction of stress, and the temperature of the structure. Reflected by the terrogator (20).

Subsequently, the light source reflected from the optical fiber grating sensor 10 to the interrogator 20 through the circulator 14 is received by the relay unit 22. At this time, the various frequencies of the light source received by the relay unit 22 are compared and read by the signals input to the relay unit 22 to be sent to the displacement calculator 30.

Subsequently, the displacement calculator 30 receives the signal transmitted from the relay unit 22 to the receiver 32 and stores the signal in the memory 34, and the signal stored in the memory 34 is controlled by the controller 36. The calculated and calculated signal is converted into an image signal, and the signal converted into the image signal is sent to the display unit 52 provided in the housing 50 to be reproduced.

At this time, the control unit 36 controls each component such that a signal stored in the memory unit 34 is calculated by a previously inputted displacement calculation module or a displacement calculation program, and is converted into an image signal and reproduced by the display unit 52.

The displacement measuring apparatus of the structure using the optical fiber lattice sensor is incident a predetermined broadband light source 12 to the plurality of optical fiber lattice sensor 10 mounted on the structure, the optical fiber lattice sensor 10 according to the external force applied to the structure By receiving and calculating a light source having only a specific wavelength reflected from it in real time and outputting it as an image, it is possible to quickly and accurately measure displacement due to strain of a structure to which external force is applied.

In addition, since the display unit 52 is configured as a touch LCD, the user can manipulate each component of the device according to the displacement measurement of the structure through the touch of the display unit 52.

This can be done by the controller 36 detecting this when the display 52 is touched and controlling each component.

In addition, the housing 50 is provided with a radio transceiver 40 having a radio antenna 42, thereby receiving the path received by the receiver 32 of the displacement calculator 30 through radio communication by the radio transmitter 40. According to the control of the control unit 36 can be sent to another computer at a short or long distance to easily measure the displacement according to the strain of the structure at a place other than the site.

In addition, the housing 50 is provided with a LAN connection unit 56 for wired communication, so that when the wireless communication is not smooth, the LAN line is connected to the LAN connection unit 56 to store a signal stored in the memory unit 34 at a short distance. By sending it to another computer 30 that is present, it is possible to easily measure the displacement according to the strain on the structure at a place other than the site.

On the other hand, the displacement measuring device of the structure using the optical fiber grating sensor according to another embodiment of the present invention, as shown in Figure 4, except that the temperature control device 60 is provided in the housing 50 of the present invention Same as in one embodiment.

That is, in the present embodiment, the temperature controller 60 is connected to the housing 50 so that it can be used in an outdoor place.

The temperature control device 60 controls the temperature so that the interrogator 20 can be used without being influenced by the surrounding temperature according to the input information. At this time, the use range of the interrogator 20 according to the temperature control of the temperature control device 60 is approximately -25 ° C to + 70 ° C.

The displacement measuring apparatus of the structure using the optical fiber grating sensor according to another embodiment of the present invention configured as described above is external temperature is applied regardless of the surrounding temperature in the outdoor place through the temperature control by the temperature control device 60 The displacement caused by the deformation of the structure can be accurately measured.

The present invention has been described above by way of example, but the present invention is not limited to the above-described embodiment, and those skilled in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Anyone can make a variety of variations.

1 is a perspective view showing an interrogator of a structure using an optical fiber grating sensor according to an embodiment of the present invention;

2 is a flowchart illustrating a displacement measurement process of an interrogator of a structure using an optical fiber grating sensor according to an embodiment of the present invention;

3 is a flowchart illustrating a displacement measurement process of an interrogator of a structure using an optical fiber grating sensor according to another embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

10 fiber optic lattice sensor 12 broadband light source

14: circulator 20: interrogator

22: relay unit 30: displacement calculation unit

40: wireless transmission unit 50: housing

52 display unit 56 LAN connection

60: temperature control device

Claims (8)

The optical fiber lattice sensor 10 is mounted on the structure and the light source of the predetermined wavelength is emitted from the broadband light source 12 when the displacement measurement is incident through the circulator 14, and After the light source is incident on the optical fiber grating sensor 10, the light source reflected from each specific wavelength of the optical fiber grating sensor 10 is received through the circulator 14 to measure the strain of the structure according to the external force applied to the structure. Including an interrogator 20 for The interrogator 20 includes a relay unit 22 for reading and transmitting various frequencies of the light source received through the circulator 14 in comparison with the input signal, A displacement calculation unit 30 for receiving and storing the signal transmitted from the relay unit 22 and calculating the displacement of the stored signal, and An interrogator using an optical fiber grating sensor, characterized in that consisting of a wireless transmitter 40 for transmitting a signal received by the displacement calculator 30 through wireless communication. The method according to claim 1, The relay unit 22, the displacement calculation unit 30, and the wireless transmitter 40 is an interrogator using an optical fiber grating sensor, characterized in that integrally provided in the housing (50). The method according to claim 2, The displacement calculator 30 includes a receiver 32 for receiving a signal transmitted from the relay unit 22, A memory unit 34 for storing a signal received by the receiving unit 32, A control unit 38 for calculating a displacement of the signal stored in the memory unit 34 and converting the signal into an image signal; A printed circuit board 38 on which the receiver 32, the memory 34, and the controller 38 are mounted; An interrogator of a structure using an optical fiber grating sensor, characterized in that consisting of a power supply for supplying power to the printed circuit board (38). The method according to claim 3, The housing 50 is an interrogator of a structure using an optical fiber grating sensor, characterized in that the display unit 52 for outputting the displacement calculated from the displacement calculation unit 30 as an image. The method according to claim 4, The display unit 52 is an interrogator of a structure using an optical fiber grating sensor, characterized in that consisting of a touch LCD. The method according to any one of claims 1 to 5, The wireless transmitter 40 is an interrogator of a structure using an optical fiber grating sensor, which performs any one of wireless LAN, WiBro, code division multiple access, Zigbee, Bluetooth, and ultra-wideband communication. The method according to claim 6, The displacement calculator 30 is an interrogator of a structure using an optical fiber grating sensor, characterized in that the LAN connection unit 56 for transmitting a signal stored in the memory unit 34 through a wired communication. The method according to claim 1, The housing 50 is an interrogator of a structure using an optical fiber grating sensor, characterized in that the temperature control device 60 is further provided.

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