KR102684750B1 - Optical fiber sensor, optical fiber sensor fixing device, and underground pipe monitoring device equipped with the same - Google Patents

Abstract

The present invention relates to an optical fiber sensor, an optical fiber sensor fixture, and an underground pipe monitoring device equipped with the same. More specifically, an optical fiber sensor capable of accurately and precisely measuring temperature changes, vibration amount, and deformation amount of pipe facilities buried underground. , relates to an optical fiber sensor fixture and an underground pipeline monitoring device equipped with the same.
The underground pipe monitoring device according to the present invention can directly measure temperature changes due to cracks and water leaks due to damage to the underground pipe through a distributed optical fiber temperature sensor, and can detect the effect of leakage in the gas pipe around the upper part of the underground pipe. It is possible to detect the effect of leakage from the liquid pipe around the lower part of the underground pipe. In addition, the underground pipe monitoring device according to the present invention can directly measure the condition of the underground pipe, such as the state of deposition inside the underground pipe, whether cracks occur, water leaks, etc., through a distributed optical fiber vibration sensor, and can directly measure the condition of the underground pipe, such as gas and water around the upper part of the underground pipe. The impact of external third-party infringements, such as leaks in liquid pipes and ground excavation, can be detected. In addition, the underground pipe monitoring device according to the present invention can directly measure the external deformation state of the underground pipe through a distributed optical fiber strain sensor, and can detect the deformation effect of the soil layer constituting the strata on the left and right sides of the underground pipe. It is possible to detect subsidence and uplift of the soil layer due to leakage after damage.

Description

Optical fiber sensor, optical fiber sensor fixture, and underground pipe monitoring device equipped with the same {Optical fiber sensor, optical fiber sensor fixing device, and underground pipe monitoring device equipped with the same}

The present invention relates to an optical fiber sensor, an optical fiber sensor fixture, and an underground pipe monitoring device equipped with the same. More specifically, the present invention relates to temperature changes and vibration amounts of pipe facilities buried in the ground or underground pipes exposed to the outside by excavation during construction. , relates to an optical fiber sensor that can accurately and precisely measure the amount of deformation, an optical fiber sensor fixture, and an underground pipeline monitoring device equipped with the same.

In general, optical fibers can be used as sensors because they are sensitive to changes in their own characteristics due to changes in the external environment, for example, external physical quantities such as temperature or stress. In addition, due to the characteristics of the optical fiber itself, it is insensitive to external electromagnetic waves, strong in harmful environments such as gases or solutions, light, flexible, and miniaturized.

Because of these advantages, optical fibers are easy to install and mount on structures, making them very suitable for sensors.

As an optical fiber sensor, there is an optical grid sensor manufactured by changing the refractive index of the core within the optical fiber, but this has the problem of being relatively weak compared to distributed optical fiber sensors because only the part with the grid engraved acts as a sensor.

Republic of Korea registered patent 10-2169504 Republic of Korea registered patent 10-0456485 Republic of Korea Public Patent No. 10-2012-0026937

The present invention is intended to solve the conventional problems described above, and utilizes a distributed optical fiber sensor to determine the internal deposition state of pipe facilities buried in the ground or underground pipes exposed to the outside by excavation during construction, whether cracks occur, etc. We provide an underground pipeline monitoring device that can precisely detect the state of the underground pipeline, such as the state of structural deformation, pipeline leakage, soil layer deformation due to excavation, subsidence, or uplift, through a distributed sensing device throughout the entire section. It has a purpose.

To achieve the above object, the optical fiber sensor according to the present invention includes a first distribution type optical fiber temperature sensor for measuring temperature, a first distribution type optical fiber vibration sensor for measuring vibration, and a first distribution type optical fiber vibration sensor for measuring deformation. A single comprising a first sensor unit including at least one of the optical fiber strain sensors, a first protective layer formed to surround the first sensor unit, and a first covering part formed to surround the first protective layer. mode sensor; A second sensor unit comprising a pair of second distribution optical fiber temperature sensors for measuring temperature and a pair of second distribution optical fiber vibration sensors for measuring vibration, and a second sensor unit formed to surround the second sensor unit. A multi-mode sensor including a second protective layer and a second covering formed to surround the second protective layer.

The first protective layer and the second protective layer are characterized in that they are formed of Kevlar.

The first coating portion and the second coating portion are characterized in that they are formed of polyurethane.

The optical fiber sensor fixture according to the present invention for achieving the above object includes a fixing bracket for installing and fixing the optical fiber sensor along the underground pipe while in contact with the pipe facility buried in the ground, and the fixing bracket is connected to the underground pipe. An optical fiber sensor fixture including a fixing band for fixing the optical fiber sensor, wherein the optical fiber sensor includes a first distribution type optical fiber temperature sensor for measuring temperature, a first distribution type optical fiber vibration sensor for measuring vibration, and a first distribution type optical fiber vibration sensor for measuring the amount of deformation. A first sensor unit configured to include at least one of the first distributed optical fiber strain sensors, a first protective layer formed to surround the first sensor unit, and a first coating formed to surround the first protective layer. A second sensor unit comprising a single mode sensor having a unit, a pair of second distribution type optical fiber temperature sensors for measuring temperature and a pair of second distribution type optical fiber vibration sensors for measuring vibration, and A multi-mode sensor including a second protective layer formed to surround the second sensor portion, and a second covering portion formed to surround the second protective layer.

The optical fiber sensor fixture includes a cover portion formed to surround a portion of the single-mode sensor or the multi-mode sensor in contact with the underground pipe, and a wing portion that extends a certain length from both ends in the width direction of the cover portion and contacts the underground pipe. It is characterized by including.

To achieve the above object, the underground pipeline monitoring device according to the present invention includes a first distributed optical fiber temperature sensor for measuring temperature, a first distributed optical fiber vibration sensor for measuring vibration, and a first distributed optical fiber vibration sensor for measuring the amount of deformation. A first sensor unit configured to include at least one of distributed optical fiber strain sensors, a first protective layer formed to surround the first sensor unit, and a first covering part formed to surround the first protective layer. a second sensor unit comprising a single mode sensor, a pair of second distribution type optical fiber temperature sensors for measuring temperature, and a pair of second distribution type optical fiber vibration sensors for measuring vibration, and the second An optical fiber sensor consisting of a multi-mode sensor including a second protective layer formed to surround the sensor unit and a second covering part formed to surround the second protective layer; a fixture including a fixing bracket for installing and fixing the optical fiber sensor along an underground pipe while in contact with a pipe facility buried in the ground, and a fixing band for fixing the fixing bracket to the underground pipe; a light detection unit that outputs a reference light signal to the optical fiber sensor and receives a reflected light signal that is refracted and returned inside the optical fiber sensor; and a measuring unit that analyzes the reflected light signal received by the light detection unit and measures the temperature change, vibration amount, and deformation amount of the underground pipe.

At the top of the underground pipe, a first single mode sensor including the first distribution type optical fiber temperature sensor, the first distribution type optical fiber vibration sensor, and the first distribution type optical fiber strain sensor is installed in contact with the underground pipe line. On a trajectory connecting points spaced a certain distance from the center, a second single mode sensor including the first distributed optical fiber temperature sensor and the first distributed optical fiber vibration sensor or a pair of the second distributed optical fiber temperature sensor and one A multi-mode sensor having a pair of the second distribution type optical fiber vibration sensors is installed, and the first distribution sensor is installed at a point that is horizontal with the first single mode sensor and is spaced a certain distance to the left and right from the first single mode sensor. A third single mode sensor having a fluorescent optical fiber strain sensor is installed, and the first distributed optical fiber temperature sensor is installed at a point that is parallel to the bottom of the underground pipe and is spaced a certain distance to the left or right from the bottom of the underground pipe. A fourth single mode sensor including the first distributed optical fiber strain sensor is installed.

The underground pipe monitoring device according to the present invention can directly measure temperature changes due to cracks and water leaks due to damage to the underground pipe through a distributed optical fiber temperature sensor, and can detect the effect of leakage in the gas pipe around the upper part of the underground pipe. It is possible to detect the effect of leakage from the liquid pipe around the lower part of the underground pipe.

In addition, the underground pipe monitoring device according to the present invention can directly measure the condition of the underground pipe, such as the state of deposition inside the underground pipe, whether cracks occur, water leaks, etc., through a distributed optical fiber vibration sensor, and can directly measure the condition of the underground pipe, such as gas and water around the upper part of the underground pipe. The impact of external third-party infringement, such as leaks in liquid pipes and ground excavation, can be detected.

In addition, the underground pipe monitoring device according to the present invention can directly measure the external deformation state of the underground pipe through a distributed optical fiber strain sensor, and can detect the deformation effect of the soil layer constituting the strata on the left and right sides of the underground pipe. It is possible to detect subsidence and uplift of the soil layer due to leakage after damage.

1 is a diagram showing a single-mode sensor of an optical fiber sensor according to the present invention.
Figure 2 is a diagram showing a multi-mode sensor of an optical fiber sensor according to the present invention.
Figure 3 is a diagram showing the combined structure of an optical fiber sensor, an optical fiber sensor fixture, and an underground pipe according to the present invention.
Figure 4 is a diagram showing the installation structure of an optical fiber sensor according to an embodiment of the present invention.
Figure 5 is a diagram showing the installation structure of an optical fiber sensor according to another embodiment of the present invention.
Figure 6 is a diagram showing the installation structure of an optical fiber sensor according to another embodiment of the present invention.

Hereinafter, an optical fiber sensor, an optical fiber sensor fixture, and an underground pipeline monitoring device equipped with the same according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

Since the optical fiber sensor and the optical fiber sensor fixture according to the present invention are included in the underground pipe monitoring device according to the present invention, they will be described together in the underground pipe monitoring device according to the present invention.

1 to 6 show an underground pipeline monitoring device according to the present invention. Referring to Figures 1 to 6, the underground pipeline monitoring device according to the present invention includes an optical fiber sensor, an optical fiber sensor fixture 200, an optical detection unit (not shown), and a measurement unit (not shown).

The optical fiber sensor includes a single mode sensor 110 and a multimode sensor 150.

The single mode sensor 110 includes a first sensor unit 120, a first protective layer 130, and a first covering unit 140.

The first sensor unit 120 includes a first distribution type optical fiber temperature sensor 121 for measuring temperature, a first distribution type optical fiber vibration sensor 122 for measuring vibration, and a first distribution type optical fiber vibration sensor 122 for measuring the amount of deformation. It is configured to include at least one of the type optical fiber strain sensors (not shown).

As an example, the first sensor unit 120 may be composed of a first distribution type optical fiber temperature sensor 121 and a first distribution type optical fiber vibration sensor 122, and may include a first distribution type optical fiber temperature sensor 121 and a first distribution type optical fiber temperature sensor 122. It may be composed of a first distribution optical fiber strain sensor, a first distribution optical fiber vibration sensor 122 and a first distribution optical fiber strain sensor, or a first distribution optical fiber temperature sensor 121 and a first distribution optical fiber strain sensor. It may be configured to include both a type optical fiber vibration sensor 122 and a first distributed optical fiber strain sensor. In this embodiment, a first distributed optical fiber temperature sensor 121 and a first distributed optical fiber vibration sensor 122 were used.

The first protective layer 130 is formed in a circular shape to surround the first sensor unit 120, and the first sensor unit 120 is embedded therein. The first protective layer 130 is made of Kevlar.

The first covering portion 140 is formed to surround the first protective layer 130, and is formed with the first protective layer 130 buried therein. The first covering portion 140 is made of polyurethane.

A separate buffer layer may be further provided between the first protective layer 130 and the first covering part 140, and the first covering part 140 may be composed of a plurality of layers.

The multi-mode sensor 150 includes a second sensor unit 160, a second protective layer 170, and a second covering unit 180.

The second sensor unit 160 includes a pair of second distribution type optical fiber temperature sensors 161 for measuring temperature and a pair of second distribution type optical fiber vibration sensors 162 for measuring vibration. do.

Here, the second distribution type optical fiber temperature sensor 161 and the second distribution type optical fiber vibration sensor 162 are the same as the first distribution type optical fiber temperature sensor 121 and the first distribution type optical fiber vibration sensor 122 described above. applied.

The second protective layer 170 is formed in a circular shape to surround the second sensor unit 160, and the second sensor unit 160 is embedded therein. The second protective layer 170 is formed of Kevlar.

The second covering portion 180 is formed to surround the second protective layer 170, and the second protective layer 170 is embedded therein. The second covering portion 180 is made of polyurethane.

A separate buffer layer may be further provided between the second protective layer 170 and the second covering portion 180, and the second covering portion 180 may be composed of a plurality of layers.

The optical fiber sensor fixture 200 is for installing and fixing the optical fiber sensor along the underground pipeline 300 while in contact with the pipeline facility buried in the ground, and includes a fixing bracket 210 and a fixing band 220. do.

The fixing bracket 210 includes a cover part 211, a wing part 212, and a fastening fixing part.

The cover portion 211 is formed in a semicircular structure to surround a portion of the upper side of the single mode sensor 110 or multimode sensor 150 installed in contact with the underground pipe 300.

The wing portion 212 extends a certain length from both ends of the cover portion 211 in the width direction, and is installed in contact with the underground pipe 300. Although not shown in the drawing, adhesive or silicone may be applied or welded to the portion in contact with the underground pipeline 300 so that the wing portion 212 can be fixed in contact with the underground pipeline 300.

The fixing band 220 fixes the fixing bracket 210 to the underground pipe 300. It is formed in the form of a circular band with one end cut, and can be fastened and fixed using fastening bolts and fastening nuts at both ends. A fastening portion 222 is provided. On one side of the fixing band 220 that is in contact with the fixing bracket 210, a seating area is formed in a shape corresponding to the fixing bracket 210 to wrap around the fixing bracket 210 and allow the fixing bracket 210 to enter and be seated inside. Government (221) is provided.

The fastening fixture may include a fastening bolt penetrating fastening parts provided at both ends of the fixing band 220, and a fastening nut fastened to the ends of the fastening bolts.

The light detector (not shown) outputs a reference light signal to the optical fiber sensor and receives a reflected light signal that is refracted and returned inside the optical fiber sensor.

The measurement unit (not shown) analyzes the reflected light signal received by the light detection unit and measures the temperature change, vibration amount, and deformation amount of the underground pipe 300.

The underground pipe 300 extends to a certain length and has a pipe body 310 provided with a flow path for fluid to pass through, and other pipe bodies 310 can be connected to both ends of the pipe body 310 in the longitudinal direction. It is configured to include a formed coupling flange portion 320. The pipe body 310 on one side is connected to the pipe body 310 on the other side by a coupling flange portion 320.

Figure 4 shows the installation structure of an optical fiber sensor according to an embodiment.

Referring to Figure 4, at the top of the underground pipe 300 of the underground pipe monitoring device according to the present invention, there is a first distribution type optical fiber temperature sensor 121, a first distribution type optical fiber vibration sensor 122, and a first distribution type optical fiber temperature sensor 121. A first single mode sensor 110A including an optical fiber strain sensor may be installed in contact with the underground pipe 300.

And, on a cylindrical trajectory connecting points spaced a certain distance from the center of the underground pipe 300, a second single device is provided with a first distributed optical fiber temperature sensor 121 and a first distributed optical fiber vibration sensor 122. A multi-mode sensor 150 including a mode sensor 110B or a pair of second distribution type optical fiber temperature sensors 161 and a pair of second distribution type optical fiber vibration sensors 162 may be installed.

In this embodiment, the first distribution type optical fiber temperature sensor 121 and the second single mode sensor 110B including the first distribution type optical fiber vibration sensor 122 were installed. However, unlike this, a pair of A multi-mode sensor 150 including a second distribution type optical fiber temperature sensor 161 and a pair of second distribution type optical fiber vibration sensors 162 may be installed.

Meanwhile, Figure 5 shows the installation structure of an optical fiber sensor according to another embodiment. Referring to Figure 5, at the top of the underground pipe 300 of the underground pipe monitoring device according to the present invention, there is a first distribution type optical fiber temperature sensor 121, a first distribution type optical fiber vibration sensor 122, and a first distribution type optical fiber temperature sensor 121. A first single mode sensor 110A including an optical fiber strain sensor may be installed in contact with the underground pipe 300.

In addition, on a cylindrical trajectory connecting points spaced a certain distance away from the center of the underground pipe 300 (for example, 15 cm to 30 cm), a first distribution type optical fiber temperature sensor 121 and a first distribution type optical fiber vibration sensor ( A second single-mode sensor (110B) having a second single-mode sensor (110B) or a pair of second distribution-type optical fiber temperature sensors (161) and a multi-mode sensor (150) having a pair of second distribution-type optical fiber vibration sensors (162). ) can be installed.

In addition, a first distribution type optical fiber temperature sensor 121 and a first distribution type optical fiber strain sensor are installed at a point that is parallel to the bottom of the underground pipe 300 and is spaced a certain distance to the left or right from the bottom of the underground pipe 300. A fourth single mode sensor 110D having a can be installed.

Meanwhile, Figure 6 shows the installation structure of an optical fiber sensor according to another embodiment. Referring to Figure 6, at the top of the underground pipe 300 of the underground pipe monitoring device according to the present invention, there is a first distribution type optical fiber temperature sensor 121, a first distribution type optical fiber vibration sensor 122, and a first distribution type optical fiber temperature sensor 121. A first single mode sensor 110A including an optical fiber strain sensor may be installed in contact with the underground pipe 300.

In addition, a second single device is provided with a first distributed optical fiber temperature sensor 121 and a first distributed optical fiber vibration sensor 122 on a cylindrical trajectory connecting points spaced a certain distance away from the center of the underground pipe 300. A multi-mode sensor 150 including a mode sensor 110B or a pair of second distribution type optical fiber temperature sensors 161 and a pair of second distribution type optical fiber vibration sensors 162 may be installed.

In addition, a third single mode sensor (110C) is parallel to the first single mode sensor (110A) and has a first distributed optical fiber strain sensor at a certain distance from the left and right from the first single mode sensor (110A). can be installed.

In addition, a first distribution type optical fiber temperature sensor 121 and a first distribution type optical fiber strain sensor are installed at a point that is parallel to the bottom of the underground pipe 300 and is spaced a certain distance to the left or right from the bottom of the underground pipe 300. A fourth single mode sensor 110D having a can be installed.

The underground pipe monitoring device according to the present invention, which has the installation structure of the optical fiber sensor as described above, cracks due to damage to the underground pipe 300 through the first distributed optical fiber temperature sensor 121 of the first single mode sensor 110A. Temperature changes due to water damage, water leakage, etc. can be directly measured. A gas pipe around the upper part of the underground pipe 300 through the first distribution type optical fiber temperature sensor 121 of the second single mode sensor 110B or the second distribution type optical fiber temperature sensor 161 of the multi-mode sensor 150. The effects of leakage can be detected. The effect of leakage of the underground pipe 300 can be detected through the first distributed optical fiber temperature sensor 121 of the fourth single mode sensor 110D.

In addition, the underground pipe monitoring device according to the present invention, which has the installation structure of the optical fiber sensor as described above, is installed inside the underground pipe 300 through the first distributed optical fiber vibration sensor 122 of the first single mode sensor 110A. The condition of the underground pipe 300, such as deposition condition, crack occurrence, water leakage, etc., can be directly measured. Leakage of gas and liquid pipes around the upper part of the underground pipe 300 through the first distributed optical fiber vibration sensor 122 of the second single mode sensor 110B or the second distributed optical fiber vibration sensor of the multi-mode sensor 150. , the impact of external third-party infringement, such as ground excavation, can be detected.

In addition, the underground pipe monitoring device according to the present invention, which has the installation structure of the optical fiber sensor as described above, monitors the external strain state of the underground pipe 300 through the first distributed optical fiber strain sensor of the first single mode sensor 110A. Direct measurement is possible, and the deformation effect of the soil layer constituting the left and right strata of the underground pipe 300 can be detected through the first distributed optical fiber strain sensor of the third single mode sensor, and the deformation effect of the soil layer constituting the left and right strata of the underground pipe 300 can be detected through the first distributed optical fiber strain sensor of the third single mode sensor (110D). Through the first distributed optical fiber strain sensor, it is possible to detect the settlement and uplift of the soil layer due to leakage after damage to the underground pipe 300.

The optical fiber sensor, the optical fiber sensor fixture, and the underground pipe monitoring device equipped with the same according to the present invention described above have been described with reference to the attached drawings, but these are merely examples, and those skilled in the art can refer to this. It will be understood that various modifications and equivalent other embodiments are possible.

Therefore, the true scope of technical protection of the present invention should be determined only by the technical spirit of the attached claims.

110: single mode sensor
120: first sensor unit
130: first protective layer
140: first covering part
150: Multi-mode sensor
160: second sensor unit
170: second protective layer
180: second covering part
200: Fiber optic sensor fixture
210: fixing bracket
220: fixed band
300: Underground pipe

Claims (7)

delete delete delete delete delete A first sensor configured to include at least one of a first distribution type optical fiber temperature sensor for measuring temperature, a first distribution type optical fiber vibration sensor for measuring vibration, and a first distribution type optical fiber strain sensor for measuring deformation amount. a single-mode sensor including a portion, a first protective layer formed to surround the first sensor portion, and a first covering portion formed to surround the first protective layer, and a pair of second distributions for measuring temperature. A second sensor unit including a type optical fiber temperature sensor and a pair of second distributed optical fiber vibration sensors for measuring vibration, a second protective layer formed to surround the second sensor unit, and the second protective layer. An optical fiber sensor consisting of a multi-mode sensor including a second covering formed to surround the;
A fixture including a fixing bracket for installing and fixing the optical fiber sensor along an underground pipe while in contact with a pipe facility buried in the ground, and a fixing band for fixing the fixing bracket to the underground pipe;
a light detection unit that outputs a reference light signal to the optical fiber sensor and receives a reflected light signal that is refracted and returned inside the optical fiber sensor;
A measuring unit that analyzes the reflected light signal received by the light detection unit and measures the temperature change, vibration amount, or deformation amount of the underground pipe,
At the top of the underground pipe, a first single-mode sensor including the first distribution optical fiber temperature sensor, the first distribution optical fiber vibration sensor, and the first distribution optical fiber strain sensor is installed in contact with the first distribution optical fiber temperature sensor,
A multi-mode sensor including a pair of the second distribution type optical fiber temperature sensor and a pair of the second distribution type optical fiber vibration sensor is installed on a trajectory connecting points spaced a certain distance away from the center of the underground pipe,
A third single mode sensor including the first distributed optical fiber strain sensor is installed at a point that is parallel to the first single mode sensor and is spaced a certain distance left and right from the first single mode sensor,
A fourth single mode sensor provided with the first distribution type optical fiber temperature sensor and the first distribution type optical fiber strain sensor at a point that is horizontal to the bottom of the underground pipe and is spaced a certain distance to the left or right from the bottom of the underground pipe. An underground pipeline monitoring device, characterized in that installed.
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