KR20180013458A - System and method for detecting water leak route - Google Patents

Abstract

The present invention relates to a system and method for detecting a path of water leak based on a finite expansion rate of a magnetic field generated by applying a current to a path of water leak of a waterproofing structure, wherein the system includes: a current applying means (10) for generating a magnetic field by flowing an electric current into an underground path (2) of water leak; a magnetic field detector (20) for acquiring, at a plurality of positions, a magnetic field detection delay time on the ground caused by a finite propagation velocity of the magnetic field by being visually synchronized with the current applying means (10); and a calculating means (30) for obtaining underground space coordinates of the path (2) of water leak based on a difference of the magnetic field detection delay time by each position.

Description

[0001] SYSTEM AND METHOD FOR DETECTING WATER LEAK ROUTE [

The present invention relates to a leakage path detection system and method for detecting a leakage path based on a finite expansion rate of a magnetic field generated by applying a current to a leakage path of a order structure.

Dam structures such as dams and bank walls are constructed by various purposes. Basically, they have a function of blocking one side of water from flowing to the other side as long as they are not discharged artificially.

If a leakage path occurs in such an order structure, the leakage path may gradually expand to lower the strength of the structure, or even to cause breakage or collapse of the order structure. Therefore, it is necessary to detect the leakage path at the beginning of the leakage and establish countermeasures.

As a conventional method for detecting water leakage in the order structure, Japanese Patent No. 10-1432453 discloses a method of embedding a substrate in which electrodes for detecting infiltration water are arranged at predetermined intervals in a water receiving structure, but it is difficult to apply, There is a problem in that the performance is deteriorated and it is hard to reuse if it is damaged or corroded.

Also, as a conventional method, it is possible to apply a ground analysis method for analyzing the order structure by deciphering elastic waves transmitted after applying vibration, but it is difficult to carry-in and install the field by using vibration means, It is difficult to precisely specify the leakage path.

KR 10-1432453 B1 2014.08.13.

Therefore, a problem to be solved by the present invention is to provide a water leakage detection system which can easily install and use, can move a seat to each part of the order structure, can detect a leakage path, and accurately detects a leakage path without influences by internal components of the order structure And to provide a path detection system and method.

According to an aspect of the present invention, there is provided a leakage path detection system comprising: current application means (10) for generating a magnetic field by flowing an electric current through an underground leakage path (2); A magnetic field detector (20) for acquiring a magnetic field detection delay time on the ground caused by a finite propagation velocity of the magnetic field in synchronization with the current application means (10) at a plurality of positions; Computing means (30) for acquiring the underground space coordinates of the leakage path (2) based on the difference of the magnetic field detection delay time by position; And a control unit.

The current application means 10 applies current between both sides of the order structure 1 to prevent the outflow of water so that current flows in the leakage path 2 formed in the ground under the order structure 1 or the order structure 1. [ The calculation means 30 collects the magnetic field detection delay time at a plurality of positions for each leak detection location from the magnetic field detector 20 and obtains the underground space coordinates for the minute section of the leakage path 2 for each leak detection location And the coordinates of the underground space for each leak detection location are interconnected to obtain the coordinates for the entire leak path (2).

The order structure (1) is a dam or a bank, and the calculation means (30) comprises a server connected to the magnetic field detector (20) via a communication network.

In order to achieve the above object, the present invention provides a leakage path detecting method, comprising the steps of: synchronizing a time between a current applying means (10) for flowing a current in a leakage path (2) and a magnetic field detector A time synchronization step (S10); The magnetic field detection delay time on the ground due to the finite propagation velocity of the magnetic field after the magnetic field generated by the current flowing in the leakage path 2 is caused to flow through the leakage path 2 by the current applying means 10, (S20) for acquiring a magnetic field detection delay time at a plurality of positions adjacent to each other, which are obtained by the step (S20); A leakage path acquisition step (S30) of collecting the magnetic field detection delay time by position in the calculation means (30) and calculating the underground space coordinates of the leakage path (2) based on the difference of the magnetic field detection delay time by position; .

As described above, the present invention uses a current applying unit and a magnetic field detector, so that it is easy to bring it into the field or install and use it. When a magnetic field due to current expands at a finite speed of light, Since the difference in time is used, it is possible to accurately detect the leakage path without the influence of the internal structure of the order structure.

1 is a conceptual diagram of a measurement of a leak path detection system according to an embodiment of the present invention;
FIG. 2 is a state diagram of a process of detecting a magnetic field by the magnetic field detector 20. FIG.
FIG. 3 is a block diagram of a leakage path detection system according to an embodiment of the present invention, and FIG.
FIG. 4 is a graph showing a detection time difference of a magnetic field detected at different positions. FIG.
5 is a flowchart of a leak path detection method using the configuration of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The leakage path detection system according to the present invention is a system for detecting the leakage path of the ground from the ground. The system generates a magnetic field around the leakage path by flowing current through the water flowing into the leakage path underground, A magnetic field detection delay time at a plurality of positions different from each other depending on the magnetic field detection position is obtained based on the finite propagation velocity of the magnetic field when the ground is detected on the ground, It is obtained as the value of coordinates.

Hereinafter, an embodiment will be described in which the present invention is applied to a drainage structure (1) which is a facility or a structure for preventing one of the water from flowing out to the other side like a dam or an embankment.

FIG. 1 is a view showing a concept of leakage path detection using a leakage path detection system according to an embodiment of the present invention. FIG. 2 is a view showing a detection site (a magnetic field detector) S in FIG.

1 and 2 schematically show the order structure 1 on the spatial coordinates 3 and show only the surface of the order structure 1 which is a position for detecting the magnetic field, An embodiment of the present invention in which the leakage path 2 generated at the spatial coordinate 3 is exemplarily shown to detect the magnetic field at the surface of the order structure 1 to detect the leakage path 2 as a coordinate value on the spatial coordinate 3 Making it easier to understand.

Here, the water leakage path 2 is a passage through which the water of the reservoir is introduced through the inlet 2a of the upstream side S1 and then discharged through the outlet 2b of the downstream side S2, It may be formed as a path passing through the bottom side ground or a path directly passing through the order structure 1. [ As another example, the leakage path 2 can be formed in the surrounding basement of the order structure 1, and the downstream side outlets 2b are not formed in the aeration structure 1, As shown in FIG.

Therefore, the position at which the magnetic field detection delay time is acquired by the magnetic field detector 20 is not limited to the surface of the order structure 1, but may extend to the periphery of the order structure 1. [ In the description of the embodiment of the present invention, for convenience of understanding, the magnetic field detector 20 is placed on the order structure 1 to acquire the magnetic field detection delay time.

1 and 2, the leakage path detection system according to the embodiment of the present invention applies an electric signal between the upstream side and the downstream side, A current applying means 10 for causing current to flow through the flowing water, a time required for the magnetic field generated by the current flowing in the leakage path 2 to propagate at a finite velocity and reach the surface of the order structure 1 The magnetic field detector 20 provided for detecting the in-magnetic-field detection delay time by changing the position above the order structure 1, and the underground space coordinates for the leakage path 2 based on the difference of the magnetic- And an arithmetic means (30) for acquiring the data.

According to the embodiment of the present invention, in order to accurately obtain the magnetic field detection delay time, time synchronization is performed between the current applying means 10 and the magnetic field detector 20, and the collecting convenience and overall management of the magnetic field detection delay time by position The computing means 30 is configured to be implemented in the server 40 and connected to the magnetic field detector 20 through a communication network.

FIG. 3 is a block diagram showing components of the present invention installed and used as shown in FIG. 1 and FIG. 2. Referring to FIG.

The current application means 10 includes a first electrode 11 provided on the upstream side S1 of the order structure 1, a second electrode 12 provided on the downstream side S2 of the order structure 2, And a power supply unit 13 for applying an electric signal between the first electrode 11 and the second electrode 12 to flow a current between both electrodes. Here, the first electrode 11 may be immersed in the water stored on the upstream side S1, and the second electrode 12 may be immersed in the leached water collected on the downstream side S2 by leakage, It can be buried in soil.

Since the water stored by the water-phase structure (1) contains ions or the like introduced from the soil, the electric conductivity is relatively larger than that of pure water. Therefore, the water-containing structure (1) The water flowing out from the upstream side S1 to the downstream side S2 through the water leakage path 2 passing through the surrounding ground flows a current by the electric signal between the first electrode 11 and the second electrode 12 As an electrical conductor. Thus, a magnetic field having a direction around the water leakage path (2) and matching a current change is generated. The electric signal applied between the first electrode 11 and the second electrode 12 may be an electrical signal of a predetermined pattern and an electric signal of the AC signal or the magnetic field detector 20 in consideration of the electrical conductivity of the reservoir.

The current application unit 10 is synchronized with the magnetic field detector 20 in time synchronization so that the magnetic field detector 20 can accurately recognize the application time point of the electric signal.

Here, the time synchronization is configured to include a built-in clock in the power supply unit 13 and the magnetic field detector 20 of the current application unit 10 and accurately coincide the times of the built-in clocks. It is also possible to employ a method of fitting to the time of the present time, or a method of synchronizing the time by mutual communication.

As a method of causing the magnetic field detector 20 to recognize the application timing of the electric signal, there are a method of applying an electric signal in accordance with a predetermined timing, a pattern of an electric signal to be applied at a time interval, A method of allowing the magnetic field detector 20 to recognize the application time of the electric signal according to the pattern, or a method of communicating with each other to find the application time point of the electric signal can be used.

The magnetic field detector 20 obtains the detection point of the magnetic field detected above the order structure 1 after the application of the electric signal by the current application means 10 so that the delay time which is the time difference from the electric signal application point to the magnetic field detection point As a component for obtaining time, it is used to change the detection location above the order structure (1) and to change the position within each detection location and obtain the position-specific delay time.

To this end, the magnetic field detector 20 includes a time synchronization unit 21 for synchronously synchronizing with the current application unit 10 to accurately recognize the time of application of the electric signal, a magnetic field detection unit A delay time detector 23 for accurately detecting the time when the magnetic field is detected by time synchronization and acquiring a delay time from the time of applying the electrical signal to the time of detecting the magnetic field, A GPS receiver 24 that acquires the position of the time (i.e., the position of the magnetic field detector) by the GPS signal, and a delay time by position obtained by the acquired delay time and position, to the server 40 provided with the calculation means 30 And a communication unit 25 for transmitting the data.

The leak path detection system according to the present invention utilizes a point where a magnetic field generated by an electric current gradually expands to the periphery and expands at a finite speed when it is propagated.

That is, since the magnetic field generated by the current flowing through the leakage path 2 propagates at a speed of light of a finite speed and gradually expands as it is physically known, the pattern of the current flowing through the leakage path 2 The change of the magnetic field due to the change does not appear instantaneously in the whole area, but it appears later in the far distance from the leakage path (2).

As shown in FIG. 2, after setting the detection site S on the order structure 1, the delay time is set at the different positions P1, P2, P3, and P4 in the detection site S The obtained delay time is obtained as a different value depending on the difference in distance from the leakage path 2.

Of course, when the magnetic field sensor 21 provided in the magnetic field detector 20 obtains the detected magnetic field signal by sampling, the detection point of the magnetic field propagating at a speed of about 3x10 ⁸ m / s, ), It is necessary to use a product having a large sampling rate or sampling frequency.

The delay time obtained at the plurality of positions (P1, P2, P3, P4) of a detection place (S) as described above depends on how far the position to obtain the delay time is from the leakage path (2) It is possible to detect the leakage path 2 based on the time difference between the respective magnetic field detection delay times. And this difference is used to obtain the underground space coordinates of any minute section during the entire section of the water leakage path 2.

Therefore, the magnetic field detector 20 changes the detection location S and uses it in such a manner that it moves in each detection location S and obtains a delay time.

Accordingly, the delay time of the plurality of positions is divided into the detection sites and transmitted to the server (40) provided with the calculation means (30) together with the position information.

The calculation unit 30 provided in the server 40 includes a collecting unit 31 for collecting delay time (delay time and position information) for each location transmitted through a communication network by the detection location, (32) for acquiring the underground space coordinates for the minute section of the leakage path (2) for each detection site based on the delay time of the leak path (2), and the entire leak path And a route generating unit 33 for completion.

2 and 4, the following description will be made with reference to a case where four delay times are obtained at a detection location S to obtain the micro-interval space coordinates of the leak interval.

When the alternating current is applied as one kind of electric signal pattern between the upstream side and the downstream side by the current applying means 10, the current flowing through the leakage path 2 is converted into an alternating current waveform as shown in FIG. 4 (a) And a magnetic field corresponding to this AC waveform is generated around the leakage path 2 and propagates to the ground.

When electric signals are applied at different positions P1, P2, P3 and P4 and a magnetic field is detected, the magnetic field detector 20 and the leakage path 2 are controlled by the finite propagation velocity (light velocity) D2, d3, and d4 corresponding to the distances R1, R2, R3, and R4, respectively,

Therefore, it is possible to obtain the distance to the leakage path (2) at each position by multiplying the difference of the delay time obtained at each position by the velocity of the light, and calculate the coordinates of the space coordinate of the leakage path Value can also be obtained. At this time, the coordinate value obtained becomes the coordinate value of any minute section in the whole section of the leakage path (2), and the more the position at which the delay time is obtained for each detection position, the more accurately the coordinate value can be obtained.

, 누수 경로(2)의 미소 구간 좌표를 V(x,y,z), 각각의 검출 위치의 좌표를 P₁(x₁,y₁,z₁), P₂(x₂,y₂,z₂), P₃(x₃,y₃,z₃), P₄(x₄,y₄,z₄) 라고 하면, 각각의 검출 위치에서 누수 경로(2)의 미소 구간까지의 거리 R₁,R₂,R₃,R₄는 지연시간 d₁,d₂,d₃,d₄ 를 적용하여 다음의 수학식 1로 계산할 수 있다.For example, the speed of light

(X ₁ , y ₁ , z ₁ ), P ₂ (x ₂ , y ₂ , z), the coordinate of the detection point is P _{1 2} ), P ₃ (x ₃ , y ₃ , z ₃ ) and P ₄ (x ₄ , y ₄ , z ₄ ), the distances R ₁ , R ₂ , R ₃ , and R ₄ can be calculated by the following Equation 1 by applying the delay times d ₁ , d ₂ , d ₃ , and d ₄ .

Then, by solving the equation by substituting the equation expressed by the following equation (2), V (x, y, z) can be obtained as the micro-section coordinate of the leakage path (2).

As another method, since the difference between the delay times obtained at the four locations is the difference between the magnetic field detection delay times by location, the distance difference is represented by R ₁ -R ₂ , R ₂ -R ₃ , R ₃ -R ₄ , R calculated as ₄ -R ₁ or the like, and two point-to-point distance when the difference is shown a trace of a certain point on the coordinate plane (or surface) so, between the plurality of planes to obtain according to the calculated distance difference (or surface) intersect (X, y, z) of the leakage path (2).

Since the micro-section coordinates of the leak path 2 thus obtained may differ from the actual coordinates according to the measurement error, the path generator 33 interconnects the micro-section coordinates obtained for each detection location, It is also possible to grasp the progress pattern of the leakage path 2 obtained by the connection of the minute section when completing the route 2 and to correct the coordinates of the minute section which largely deviates from the progress pattern to the progress pattern.

Hereinafter, a leakage path detection method using the leak path detection system will be described with reference to the flowchart of FIG.

The leak path detection method according to the embodiment of the present invention is characterized in that prior to detecting the leakage path 2 using the current application means 10 and the magnetic field detector 20, 20 in the time synchronization step (S10).

If the time synchronization is thus performed, a delay time acquisition step (S20) for acquiring a magnetic field detection delay time corresponding to a difference in distance from the leakage path at a plurality of locations is performed in the following order.

First, a detection site S is selected from the top of the order structure 1, and a magnetic field detector 20 is placed at that position by selecting any one of the detection sites S (S21).

Thereafter, a current is supplied to the water leakage path 2 by using the current applying means 10 to cause a magnetic field to be generated in the water leakage path 2, and at the same time, a point at which the magnetic field is detected by the magnetic field detector 20 is obtained (S22) .

As described above, by applying a current between the both sides of the water-distributing structure 1 for preventing the water from flowing out, water flowing out through the water-leakage path 2 formed on the ground below the water-distributing structure 1 or the water- A current is caused to flow as a conductor, and a magnetic field generated by the current in the water leakage path 2 is generated and propagated to gradually expand the region where the magnetic force is applied.

If a magnetic field is detected in the magnetic field detector 20 and a magnetic field detection point is obtained, the magnetic field detection delay time is detected based on the magnetic field detection point and the time synchronization (S24), and the position information is detected (S24).

After the current is applied and the magnetic field detection point is obtained, the process of detecting the delay time and obtaining the position information (S22, S23, and S24) moves to different positions within the detection position S by a predetermined number N Repeat for each position (S25, S26).

Thus, a magnetic field detection delay time at a plurality of mutually adjacent positions within a detection location S is obtained.

In addition, the process of acquiring the magnetic field detection delay time at the plurality of positions with respect to the detection location is repeated by changing the detection location (S27, S28).

The magnetic field detection delay times of the plurality of positions acquired for each detection location are temporarily stored in the magnetic field detector 20 together with the respective position information and are collected and transmitted to the server 40, 30 can perform the leak path acquisition step S30.

The calculation means 30 collects the magnetic field detection delay time for each position to be detected separately (S31), calculates the magnetic field detection delay time for each detected location, Coordinates are obtained (S32).

Finally, coordinates of the micro-section obtained for each detection site are correlated to obtain the coordinates of the entire section of the leakage path 2 between the micro-segments (S33).

However, in order to accurately obtain the minute section of the leakage path 2 for each detection location, the position of the magnetic field detector 20 at the time of obtaining the delay time must be accurately obtained as the coordinate value on the spatial coordinate.

Therefore, it is preferable that the GPS receiver 24 to be mounted on the magnetic field detector 20 be able to accurately obtain the position on the spatial coordinate formed by the x, y, z coordinates from the GPS signal. However, such GPS receivers are very expensive.

Therefore, by using a low-cost GPS receiver with a small error but using a commercially available low-cost GPS receiver, the magnetic field detector 20 is placed on top of it and a detection position to detect the magnetic field is specified in advance, Alternatively, a method of obtaining the position accurately may be used as an alternative.

That is, as shown in Figs. 1 and 2, detection positions P for detecting magnetic fields are displayed in advance on the order structure 1 at intervals. At this time, the displayed detection position P is stored in the computing means 30 as the coordinate value of the spatial coordinate system.

In the delay time acquiring step (S20), the magnetic field detector (20) is placed at the indicated detection position (P) when the detection position is changed and the position is moved within the detection position and the magnetic field is detected and the delay time is detected. Therefore, the GPS receiver 24 of the magnetic field detector 20 can obtain a position approximated to the coordinate value of at least the detection position P as a GPS signal.

The calculation means 30 calculates positional information received from the magnetic field detector 20 based on the coordinate values of the detection positions P1, P2, P3 and P4 stored as coordinate values of the spatial coordinate system, Is selected and used to obtain the micro-section coordinates of the leakage path.

Alternatively, instead of having the GPS receiver 24, instead of displaying the sequence number at each of the plurality of detection positions P indicated in the order structure 1 and inputting the sequence numbers to the magnetic field detector 20, There is also a way to specify.

In the description of the embodiment of the present invention, the calculation unit 30 is provided in the server 40 that can be connected to the magnetic field detector 20 through a communication network. However, the computer 40 may be connected to the magnetic field detector 20, It is also possible to install it manually.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, . ≪ / RTI > Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

S1: upstream side S2: downstream side
P, P1, P2, P3, P4: Detection position
1: order structure
2: Leakage path 2a: Arrival point 2b: Arrival point
3: Spatial coordinate system
10: current applying means
11: first electrode 12: second electrode 13:
20: magnetic field detector
21: time synchronization unit 22: magnetic field sensor 23: delay time detection unit
24: GPS receiver 25:
30:
31: collecting unit 32: path calculating unit 33: path generating unit

Claims (8)

A current applying means (10) for generating a magnetic field by flowing an electric current to a water leakage path (2) underground;
A magnetic field detector (20) provided for acquiring a magnetic field detection delay time at a plurality of positions on the ground caused by a finite propagation velocity of the magnetic field in synchronism with the current application means (10);
Computing means (30) for obtaining the underground space coordinates of the leakage path (2) based on the difference of the magnetic field detection delay time by position;
Wherein the leakage path detection system comprises: The method according to claim 1,
The current application means 10 applies current between both sides of the order structure 1 to prevent the outflow of water so that current flows in the leakage path 2 formed in the ground under the order structure 1 or the order structure 1. [ Shedding,
The calculation means 30 collects the magnetic field detection delay times at the plurality of positions for each leak detection location from the magnetic field detector 20 to acquire the underground space coordinates for the minute section of the leakage path 2 for each leak detection location, And acquiring coordinates for the entire leak path (2) by interconnecting the underground space coordinates for each detection location. 3. The method of claim 2,
The order structure (1) is a dam or a bank,
Wherein the calculation means (30) comprises a server connected to the magnetic field detection (20) via a communication network. A time synchronization step (S10) of synchronizing the time between the current application means (10) for flowing current to the leakage path (2) and the magnetic field detector (20) for detecting the magnetic field;
The magnetic field detection delay time on the ground due to the finite propagation velocity of the magnetic field after the magnetic field generated by the current flowing in the leakage path 2 is caused to flow through the leakage path 2 by the current applying means 10, (S20) for acquiring a magnetic field detection delay time at a plurality of positions adjacent to each other, which are obtained by the step (S20);
A leakage path acquisition step (S30) of collecting the magnetic field detection delay time by position in the calculation means (30) and calculating the underground space coordinates of the leakage path (2) based on the difference of the magnetic field detection delay time by position;
Wherein the leakage path is detected by the leak detection means. 5. The method of claim 4,
The delay time acquiring step (S20) changes the detection location and acquires a magnetic field detection delay time at a plurality of positions for each detection location,
Wherein the leakage path acquiring step S30 acquires the entire leakage path 2 by interconnecting the underground space coordinates of the minute section of the leakage path 2 acquired for each detection site. 6. The method of claim 5,
The delay time acquiring step S20 is a step of acquiring the delay time by applying a current between the both sides of the order structure 1 for preventing the outflow of water to form the water structure of the water flow path 2 formed on the ground under the order structure 1 or the order structure 1. [ And a magnetic field detection delay time is obtained by detecting a magnetic field by the magnetic field detector (20) above the order structure (1). The method according to claim 6,
The order structure (1) is a dam or a bank,
The delay time acquisition step (S20) transmits the obtained magnetic field detection delay time to the server through a communication network,
Wherein the leakage path acquisition step (S30) is performed in a server. 5. The method of claim 4,
Wherein the obtaining of the delay time (S20) obtains coordinates of a position at which the magnetic field detection delay time is acquired by the magnetic field detector (20) having the GPS receiver.

Images