KR100764932B1 - Deformation and temperature sensor of underground pipe-line - Google Patents

Abstract

The present invention relates to a strain measuring sensor that can quickly detect the deformation of the buried pipe on the ground without damaging the buried pipe, buried in the lower portion of the buried pipe buried in the ground to measure the deformation of the buried pipe through the measuring means In the measuring sensor, the measuring sensor is provided with a plurality of insertion holes into which at least one displacement measuring optical fiber and at least one thermometer-side optical fiber are buried in the same direction as the buried pipe under the buried pipe buried in the ground. It is characterized by including a case strip.

Buried pipe, measuring sensor, optical fiber

Description

Buried pipe deformation measurement sensor {Deformation and temperature sensor of underground pipe-line}

1 shows an overall configuration of a measuring device including a measuring sensor according to a first embodiment of the present invention.

       1A is a perspective view,

       1B is a cross-sectional view taken along the line A-A of FIG. 1A.

2 shows a state in which the measurement sensor according to the first embodiment of the present invention is buried in the ground,

       2a is a section view of the underground,

       2B is a cross-sectional view taken along the line B-B in FIG. 2A.

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Figure 3 shows another embodiment of the first embodiment measuring sensor according to the present invention,

       3A is a section of the underground,

       3B is a cross-sectional view taken along the line C-C in FIG. 3A.

4 shows the overall configuration of a measuring device according to a second embodiment of the present invention.

       4a is a perspective view,

       4B is a cross-sectional view taken along the line D-D in FIG. 4A.

5 shows a state in which a measurement sensor according to a second embodiment of the present invention is embedded in the ground,

       5A is a section view of the underground,

       5B is a cross-sectional view taken along the line E-E in FIG. 5A.

Figure 6 shows another embodiment of a second embodiment measuring sensor according to the present invention,

       6A is a section view of the underground,

       6B is a cross-sectional view taken along the line F-F in FIG. 6A.

<Explanation of symbols for main parts of the drawings>

1: Measurement sensor

    11: displacement measurement optical fiber

    12: thermometer side optical fiber

    13: case strip

         131: insertion hole

2: measuring means

    21: light source generator

    22: strain measurement analysis unit

    23: thermometer side analysis unit

    24: heating wire

    25: power supply

3: buried pipe

The present invention relates to a buried pipe strain measuring sensor, and more particularly, to a strain measuring sensor that can quickly grasp the deformation of the buried pipe on the ground without damaging the buried pipe.

In general, the buried pipe refers to a pipe for moving fluids. The use of the buried pipe is classified according to the type of the fluid. The buried pipes have water and sewage pipes that are closely related to our lives. In addition, there are industrial tubes and chemicals through tubes.

In the buried pipe, the most important thing is the replacement and repair of the pipe due to deformation and leakage, and since the buried pipe is buried in the ground, it is difficult to identify the deformation and leakage of the buried pipe.

In the related art, an apparatus for measuring deformation and leakage of a buried pipe without developing the naked eye has been developed. As an embodiment, "Measurement method using an optical fiber" of Patent No. 339634, which has been previously filed and registered by the present applicant, and Devices thereof are known.

That is, the conventional measuring method using the optical fiber and the apparatus thereof, the optical fiber representing the change of the light transmitted by the deformation of the tube is integrally attached over the entire length of the tube along the portion not in contact with the fluid passing through the inside of the tube. And measuring the amount of deformation of the tube with the reflected light by allowing the light passing through the optical fiber to be reflected at the end point.

In addition, the optical fiber that is integrally attached over the entire length of the tube along the portion that is not in contact with the fluid passing through the inside of the tube and reflects light at the end, a light source generator for irradiating light to the starting point of the optical fiber and the end of the optical fiber Characterized in that the measuring device for measuring the amount of deformation of the tube consisting of a measuring instrument for receiving and reflecting the light reflected from.

Therefore, by using the measurement method and the device as described above is to have the advantage that can measure the deformation and breakage of the pipe buried in the ground without visual identification.

By the way, when manufacturing a tube wound the optical fiber, a spiral groove is formed along the outer surface of the tube over the entire length of the tube and the optical fiber is buried in the groove, or epoxy or the like is formed on the surface of the tube. Since the method of winding the optical fiber integrally through the adhesive is used, the production of the tube had a very difficult problem.

That is, as described above, when a spiral groove is formed in the tube and an optical fiber is embedded in the groove, the tube has a problem in that a lot of cost and manpower are consumed in forming the groove on the outside of the tube.

In addition, when the groove is formed on the outer side of the tube, the overall strength of the tube is lowered, so that the tube is easily damaged.

On the other hand, when manufacturing a tube for attaching the optical fiber to the outside through the adhesive, such as the epoxy as described later had to have a problem in that a lot of cost and manpower is consumed by applying the optical fiber while applying the adhesive.

Accordingly, the present invention is invented to solve the above problems, by embedding a measuring sensor for measuring the deformation and temperature of the buried pipe in the lower part of the buried pipe to analyze the deformation and leakage of the buried pipe from the ground, It is an object of the present invention to provide a buried pipe deformation measuring sensor capable of quickly identifying and taking action on the deformation and leakage of the buried pipe without damaging the outer surface of the buried pipe.

In addition, the purpose of this is to accurately analyze the deformation and leakage of the buried pipe by section.

In order to achieve the above object, the present invention is a measurement sensor which is buried in the lower part of the buried pipe buried in the ground to measure the deformation of the buried pipe through the measuring means, the measuring sensor is buried pipe buried underground And a case strip having a plurality of insertion holes into which at least one displacement measuring optical fiber and at least one thermometer-side optical fiber are buried in the same direction as the buried tube.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 shows an overall configuration of a measuring device including a measuring sensor according to a first embodiment of the present invention, in which FIG. 1A is a perspective view and FIG. 1B is a cross-sectional view taken along line A-A of FIG. 1A; 2 is a view illustrating a state in which a measurement sensor according to the first embodiment of the present invention is embedded in the ground. FIG. 2A is a cross-sectional view of the ground, and FIG.

Thus, the measuring sensor 1 according to the first embodiment of the present invention is embedded in the lower part of the buried pipe 3 buried in the ground measuring sensor 1 for measuring the deformation of the buried pipe 3 through the measuring means (2) In the measurement sensor 1, at least one displacement measurement optical fiber 11 and at least one thermometer side buried in the same direction as the buried pipe 3 in the lower part of the buried pipe 3 buried in the ground And a case strip 13 provided with a plurality of insertion holes 131 into which the optical fiber 12 is inserted.

That is, the case strip 13 constituting the measurement sensor 1 is made of a material that can flow so that the flow with deformation of the buried pipe.

And the displacement measurement optical fiber 11 and the thermometer-side optical fiber 12 is composed of a communication optical fiber that reflects the wavelength of light at the other end when the light is irradiated to one end.

In addition, the measuring means 2 is connected to one end of the displacement measurement optical fiber 11 and the thermometer-side optical fiber 12, the light source generator 21 for irradiating light, and is reflected from the displacement measurement optical fiber 11 The strain measurement analyzer 22 analyzes the deformation of the buried pipe 3 by measuring the wavelength of the light in real time to measure the change of the displacement measuring optical fiber 11, and the wavelength of the light reflected by the thermometer-side optical fiber 12. It is comprised by the thermometer side analysis part 23 which analyzes the change of the thermometer side optical fiber 12, and analyzes the leak of the buried pipe 3, while measuring in real time.

The measuring means 2 analyzes the wavelength of the light reflected from the displacement measuring optical fiber 11 and analyzes the change of the displacement measuring optical fiber 11 to analyze the deformation of the buried pipe 3, and the thermometer-side optical fiber. It is characterized in that it is configured to analyze the leakage of the buried pipe (3) by analyzing the wavelength of the light reflected and input from (12) to analyze the change in the thermometer-side optical fiber (12).

Below. The measurement means configured as above will be described in more detail as follows.

The light source generator 21 of the measuring means 2 is known to irradiate a light source from one end of the displacement measuring optical fiber 11 and the thermometer-side optical fiber 12 is known.

The strain measurement analyzer 22 and the thermometer analyzer 23 constituting the measurement means 2 analyze the wavelength of the light reflected from the displacement gauge optical fiber 11 and input the displacement gauge optical fiber 11. The change of the buried tube 3 is analyzed by analyzing the change of, and the wavelength of the light reflected from the thermometer-side optical fiber 12 is input to analyze the change of the thermometer-side optical fiber 12.

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Hereinafter, the construction process and the operation relationship of the measurement device including the measurement sensor of the first embodiment according to the present invention configured as described above are as follows.

First, in the case of constructing the measuring sensor according to the present invention, as shown in Fig. 1 to 2, the underground depression portion in which the buried pipe 3 is embedded in the plate state in the lower part of the underground depression portion and The integrated displacement measurement optical fiber 11 and the thermometer side optical fiber 12 to be connected are constructed. Then, the soil is embedded in the upper part of the displacement measuring optical fiber 11 and the thermometer-side optical fiber 12, and then the embedding pipe 3 is embedded in the upper part of the embedded soil to complete the construction of the measuring apparatus according to the present invention. .

And, when explaining the operation relationship of the measuring device constructed as described above, first, when the ground subsides due to external causes and the buried pipe (3) is lowered as shown in Figure 1 and 2, The displacement measuring optical fiber 11 provided in the lower part of the pipe 3 causes deformation.

Then, the position of the wavelength reflected by the displacement measuring optical fiber 11 is changed, and the change of the reflected wavelength is analyzed by the strain measurement analyzing unit 22 constituting the measuring means 2 to grasp the current strain quickly. I can figure it out.

Therefore, it is possible to take measures to prevent damage to the buried pipe 3 by quickly grasping the deformation of the buried pipe 3 at an early stage when the buried pipe 3 causes deformation.

In addition, when the buried pipe 3 is damaged due to internal pressure or external ground subsidence and a portion of the buried pipe is leaked, as shown in FIGS. 1 and 2, the buried pipe through the leaking liquid The temperature is changed in the thermometer side optical fiber 12 located below (3).

Then, the amplitude of the wavelength reflected from the thermometer-side optical fiber 12 is changed, and the current buried pipe 3 is analyzed by analyzing the change in amplitude of the reflected wavelength by the thermometer-side analyzer 23 constituting the measuring means 2. ) Can quickly identify leaks.

Therefore, it is possible to minimize the spread of leakage of the buried pipe (3) by quickly grasping the leak of the buried pipe (3) at an early stage.

3 shows another embodiment of the measurement sensor of the first embodiment according to the present invention. FIG. 3A is a cross-sectional view of the underground, and FIG. 3B is a cross-sectional view taken along the line C-C of FIG. 3A.

Accordingly, the measuring device of another embodiment according to the first embodiment of the present invention includes the configuration of the first embodiment, and the case strip is an upper portion of the insertion hole 131 provided with the thermometer-side optical fiber 12. The upper portion of the 13 is further provided with a hot wire 24 in close contact, the measuring means 2 is a power supply 25 for supplying power to the hot wire to increase the temperature of the thermometer-side optical fiber 12 is further It is characterized by including.

That is, in general, when the temperature of the optical fiber is raised, the optical fiber medium is changed, and when the reflected signal is analyzed, the change in temperature is increased. Therefore, when the temperature of the thermometer-side optical fiber 12 is increased, the amplitude of the reflected light wavelength is increased. If leakage occurs and the temperature of the optical fiber is lowered or raised, the change in temperature is different from the surroundings.

Therefore, it is possible to precisely analyze and measure the leakage of the temperature change of the thermometer-side optical fiber 12.

Figure 4 shows the overall configuration of a measuring device including a measuring sensor according to a second embodiment of the present invention, Figure 4a is a perspective view, Figure 4b is a cross-sectional view taken along the line D-D of Figure 4a; 5 is a view illustrating a state in which a measurement sensor according to a second embodiment of the present invention is embedded in the ground. FIG. 5A is a cross-sectional view of the ground, and FIG. 5B is a cross-sectional view taken along the line E-E of FIG.

Thus, the measurement sensor according to the second embodiment of the present invention, except for the configuration of the displacement measurement optical fiber 11 and the thermometer-side optical fiber 12 is assumed to be the same as the configuration of the first embodiment described above.

That is, the displacement measuring optical fiber 11 and the thermometer-side optical fiber 12 are configured as distributed (lattice) optical fibers that reflect light for each section when a plurality of lights having different frequency bands are irradiated at one end.

In addition, the measuring means 2 is connected to one end of the displacement measurement optical fiber 11 and the thermometer-side optical fiber 12, the light source generator 21 for irradiating light and the period reflected by the displacement measurement optical fiber 11 Strain measurement analyzer 22 for analyzing the deformation of the displacement measuring optical fiber 11 by measuring the wavelength of the star light in real time to analyze the deformation of the buried pipe 3, and for each section reflected by the thermometer-side optical fiber 12 It is comprised by the thermometer side analysis part 23 which analyzes the change of the thermometer side optical fiber 12, and measures the leakage of the buried pipe 3, while measuring the wavelength of light in real time.

In addition, the displacement measuring optical fiber 11 is formed of a plurality, the measuring means 2 is provided with a plurality of insertion holes 131 into which a plurality of displacement measuring optical fibers 11 and a thermometer-side optical fiber 12 is inserted. The case band 13 is included, and the plurality of insertion holes 131 into which the displacement measuring optical fibers 11 are inserted among the plurality of insertion holes 131 are formed to have different diameters and are inserted into each of the displacement measuring optical fibers ( 11) is mounted to be inserted in a straight line so as to vary the length of the measurement section.

In addition, the measuring means 2 analyzes the respective wavelengths of light reflected from the respective displacement measuring optical fibers 11 by section through irradiation of a plurality of light beams having different frequency bands to each of the plurality of displacement measuring optical fibers 11. The variation of each section of the buried pipe 3 is analyzed by analyzing the change in each section of each displacement measuring optical fiber 11. In addition, the measuring means (2), by analyzing the wavelength of each light reflected by the input section from the at least one thermometer-side optical fiber 12 to analyze the change in each section of the thermometer-side optical fiber 12 to leak the buried pipe (3) To analyze.

Accordingly, the light source generator 21 of the measuring means 2 irradiates a plurality of lights with different frequency bands to each displacement measuring optical fiber 11, and also has a wrong frequency band at one end of the at least one thermometer-side optical fiber 12. Various types are known for irradiating a large number of lights.

The strain measurement analyzer 22 and the thermometer analyzer 23 constituting the measuring means 2 are reflected from the displacement measurement optical fiber 11 at respective sections according to irradiation of a plurality of lights having different frequency bands. Analyze the variation of the displacement measurement optical fiber 11 in each section by analyzing the multiple light wavelengths of each input section to analyze the deformation of the buried pipe 3, and at least one thermometer-side optical fiber according to the irradiation of a plurality of lights having different frequency bands. It is possible to analyze the temperature change of the thermometer-side optical fiber 12 by analyzing a plurality of light wavelengths in each section reflected and input from (12).

Therefore, when the ground subsides due to external causes and the buried pipe 3 sinks to the bottom, as shown in FIGS. 4 and 5, a displacement measurement of a distribution type provided in the lower part of the buried pipe 3. The optical fiber 11 causes deformation.

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Then, the position of the wavelength reflected by each section in each displacement measurement optical fiber 11 is changed, and the variation measurement analysis unit 22 constituting the measuring means 2 analyzes the positional change of the wavelength reflected by each section. By grasping, it is possible to quickly grasp the change for each section of the current displacement measurement optical fiber 11.

Therefore, it is possible to prevent damage to the buried pipe 3 in advance by quickly grasping the deformation of the buried pipe 3 in each section at an early stage when the buried pipe 3 causes deformation.

In addition, when the buried pipe 3 is partially damaged due to internal pressure or external ground subsidence, and leakage occurs, as shown in FIGS. 4 and 5, the buried pipe 3 is provided through the leaked liquid. The temperature is changed in one or more of the thermometer-side optical fibers 12 located below.

Then, the amplitude of the wavelength reflected by each section in the distributed thermometer-side optical fiber 12 is changed, and the change in amplitude of the wavelength reflected in each section is analyzed by the thermometer-side analyzing unit 23 constituting the measuring means 2. By grasping it, it is possible to quickly know the leakage of the current buried pipe (3).

Therefore, it is possible to minimize the spread of leakage of the buried pipe (3) by quickly grasping the leak of the buried pipe (3) at an early stage.

On the other hand, as shown in Figure 4, when the plurality of distributed displacement measurement optical fibers 11, through a plurality of insertion holes 131 of varying sizes formed in the case band 13 that can be deformed in a straight line The following phenomenon occurs.

First, in the distributed displacement measuring optical fiber 11 inserted into the small insertion hole 131, the inner surface of the insertion hole 131 is in close contact with the distributed displacement measuring optical fiber 11 even though the case strip 13 is slightly curved. As the number of parts increases, bending occurs severely in each section.

On the contrary, in the distributed displacement measurement optical fiber 11 inserted into the insertion hole 131 having a large diameter, when the case strip 13 is slightly curved, the inner surface of the insertion hole 131 becomes the lattice type displacement measurement optical fiber 11. On the other hand, the distributed displacement measurement optical fiber 11 causes deformation only when it is severely bent.

Therefore, when the space between the inner surface of the insertion hole 131 and the distributed displacement measurement optical fiber is run, the buried through the change of the wavelength of each section of the distributed displacement measurement optical fiber 11 inserted in the small insertion hole The initial displacement of the tube (up to the breaking point of the optical fiber) can be measured and inserted into a small insertion hole through the change of the wavelength of each section of the distributed displacement measuring optical fiber 11 inserted in the large insertion hole. By measuring the displacement beyond the measurement range of the distributed displacement measurement optical fiber sensor, the deformation of the buried pipe 3 can be measured more precisely by measuring the large deformation of the buried pipe 3.

FIG. 6 shows another embodiment of the measuring device of a second embodiment according to the present invention. FIG. 6A is a sectional view taken along the ground, and FIG. 6B is a sectional view taken along the line F-F in FIG. 6A.

Therefore, the measurement device of another embodiment according to the second embodiment of the present invention, on the premise that it includes the configuration of the second embodiment, the insertion hole provided with the at least one grating-type thermometer side optical fiber 12 ( A heating wire 24 is further provided on the upper part of the case strip 13, which is the upper part of the 131, and the measuring means 2 supplies power to the heating wire 24 so that the temperature of the thermometer-side optical fiber 12 is increased. The power supply 25 for increasing the temperature is further characterized in that it is included.

Therefore, in general, when the temperature of the optical fiber is raised, the optical fiber medium is changed, and when the reflected signal is analyzed, the change in temperature is increased. Therefore, when the temperature of the thermometer-side optical fiber 12 is increased, the amplitude of the reflected light wavelength is increased. If leakage occurs and the temperature of the optical fiber is lowered or raised, the change in temperature is different from the surroundings.

Therefore, it is possible to precisely analyze and measure the leakage of the temperature change of the thermometer-side optical fiber 12.

As described above, the present invention prevents the strength of the buried pipe from being weakened by not damaging the outside of the buried pipe, while the buried pipe is rapidly deformed and leaked by analyzing the deformation and leakage of the buried pipe. It is effective to provide a buried pipe deformation measuring sensor that can prevent a disaster in advance.

In addition, by accurately analyzing the deformation and leakage of the buried pipe by section, it is also effective to shorten the repair time of the buried pipe.

While the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the invention from this description. Therefore, the scope of the invention should be construed by the claims described to include many such variations.

Claims (8)

In the measurement sensor 1 which is buried in the lower part of the buried pipe 3 embedded in the ground and measures the deformation of the buried pipe 3 through the measuring means 2, The measuring sensor (1) is at least one displacement measuring optical fiber (11) which is buried in the same direction as the buried pipe (3) below the buried pipe (3) buried in the ground; At least one thermometer side optical fiber 12; It is configured to include a case strip 13 provided with a plurality of insertion holes 131 into which the optical fibers 11 and 12 are inserted, The heating wire 24 is further provided on the upper part of the insertion hole 131 provided with the thermometer-side optical fiber 12, which is the upper part of the case strip 13, to be in close contact with the insertion hole 131. The measuring means (2) is buried pipe deformation measuring sensor further comprises a power supply for supplying power to the heating wire (24) to increase the temperature of the thermometer-side optical fiber (12). According to claim 1, wherein the displacement measuring optical fiber 11 and the thermometer-side optical fiber 12, Buried pipe strain measurement sensor, characterized in that composed of a communication optical fiber that reflects the wavelength of light at the other end once the light is irradiated. The method of claim 2, wherein the measuring means 2, Analyzes the deformation of the buried pipe 3 by analyzing the wavelength of the light reflected from the displacement measuring optical fiber 11 and leaks the buried pipe 3 by analyzing the wavelength of the light reflected from the thermometer-side optical fiber 12. Buried pipe deformation measuring sensor characterized in that the analysis. delete According to claim 2, wherein the displacement measuring optical fiber 11 and the thermometer-side optical fiber 12, Buried pipe strain measurement sensor, characterized in that consisting of a grating optical fiber that reflects light for each section when a plurality of lights of different frequency bands at one end is irradiated. 6. The displacement measuring optical fiber (11) is formed in plural. The measuring means 2 includes a case strip 13 having a plurality of insertion holes 131 into which a plurality of displacement measuring optical fibers 11 and thermometer-side optical fibers 12 are inserted, Among the plurality of insertion holes 131, the plurality of insertion holes 131 into which the displacement measuring optical fiber 11 is inserted are formed to have different diameters so that the displacement measuring optical fiber 11 inserted into each of them may vary the length of the measurement section. Buried pipe deformation measuring sensor, characterized in that mounted so as to be inserted in a straight line. The method of claim 5 or 6, wherein the measuring means (2) Deformation of each section of the buried pipe 3 by analyzing the optical wavelength of each section reflected from each displacement measurement optical fiber 11 through the irradiation of a plurality of lights having different frequency bands to each of the plurality of displacement measuring optical fibers 11. Buried pipe strain measurement sensor, characterized in that for analyzing the leakage of each section of the buried pipe (3) by analyzing the optical wavelength of each section that is reflected and input from the thermometer-side optical fiber (12). The method of claim 7, wherein the measuring sensor 1, The heating wire 24 is provided in close contact with the upper portion of the insertion hole 131 provided with the thermometer-side optical fiber 12, and included in the measuring means (2) to supply power to the heating wire 24 to the thermometer-side optical fiber ( Buried pipe deformation measuring sensor further comprises a power supply unit 25 for raising the temperature of 12).

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