KR100486814B1 - Leakage Detection System - Google Patents

Abstract

A plurality of linear electrodes arranged parallel to each other at predetermined intervals above the order film, and a plurality of linear electrodes arranged parallel to each other at a predetermined interval so as to intersect the upper linear electrodes below the order film An electrode, an AC power supply, and one of the plurality of linear electrodes above are selected, and one of the plurality of linear electrodes below is selected to select one of the selected linear or lower linear electrodes. An electrode selector for connecting only one to one AC power source and all other linear electrodes to the other side of the AC power source, a linear electrode connected to the one AC power source, and one linear electrode selected on the opposite side A current detecting circuit for detecting a current flowing through the insulating film between the detector and a detection circuit for detecting the current through the output of the current detecting circuit; When the plurality of linear electrodes on the lower side are sequentially selected and the linear electrodes in the position close to the position where the leakage occurs due to breakage of the membrane are combined, the output of the detection circuit rises or falls below the value of the other electrode combinations. Has a processing circuit for detecting a leak occurrence position based on the

Description

Leakage Detection System

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a leak occurrence position detection system of a managed terminal disposing equipment formed by laying a membrane of a synthetic resin sheet, a synthetic rubber sheet, or asphalt.

Background Art Conventionally, in an artificially managed end disposition facility using a barrier film, damage such as cracks may occur in the barrier film, and contaminants in the disposal site may leak. If the contaminated liquid leaks, groundwater contamination or pollution problems will occur. Therefore, it is necessary to check the insulation film on a regular basis. If the insulation film is broken, it is necessary to detect the leak location and properly repair it.

As described above, in order to detect the position where the leak occurs in the water curtain, the following leak occurrence position detection system is employed.

In such a detection system, electrodes in which a plurality of linear electrodes are laid in parallel at predetermined intervals at the lower end of the order film, and electrodes in which a plurality of linear electrodes are laid in parallel at predetermined intervals in the direction intersecting the lower electrode at the upper end of the order film Use a batch configuration. Then, one of the linear electrodes above and below the order film is selected, and a current is passed between the upper and lower linear electrodes by an AC power supply, and a current detection circuit detects the current flowing between the upper and lower linear electrodes, thereby applying an applied voltage. Phase is detected by a phase and a synchronization signal of. Then, the position where the leakage is detected is detected by comparing the output voltage of the phase detection circuit generated at each intersection of the upper and lower linear electrodes.

If there is no damage to the liner film, the current flowing between the linear electrodes selected above and below the liner film becomes a current flowing through the capacitive component of the liner film. Therefore, the absolute value of the current is small and the phase of the applied voltage of the AC power source is advanced. It becomes (進 相).

On the other hand, when the insulation film is broken, current easily flows between the linear electrodes selected above and below the damaged place. For this reason, when the combination intersection of the linear electrodes above and below the order film is close to the damaged place, the absolute value of the current increases, and the phase of the current tends to approach the phase of the applied voltage. Therefore, by measuring the current at each intersection of the upper and lower linear electrodes, it is possible to detect the place where the order film is broken.

That is, in the conventional leak occurrence position detection system, the phase detection circuit detects the phase with respect to the output of the current detection circuit in a phase synchronized with the applied voltage of the AC power supply, and extracts the in-phase component of the AC power supply.

However, in the above-mentioned conventional leak occurrence position detecting system, when a plurality of places, such as two places, are damaged in the curtain film, the measurement result for the first broken place is affected by the second broken place. In addition, the second broken place is also affected by the first broken place. For this reason, in the case where two or more of the barrier films are broken, there is a drawback that the accuracy of specifying the broken place is lowered.

In particular, when the upper and lower sides each have a rectangle defined as a linear electrode adjacent to each other as a measurement range of one unit, when damage occurs in two adjacent measurement ranges or when two or more measurement ranges close to each other occur, There is a drawback that the accuracy of specifying the location is lowered.

Accordingly, it is an object of the present invention to provide a leak occurrence position detection system capable of detecting each breakage point with high accuracy even when breakage occurs in a plurality of places in the insulation film.

According to the present invention, there is provided a leak occurrence position detection system applied to a managed end disposition device formed by laying a barrier film, a plurality of linear electrodes arranged in parallel at predetermined intervals on an upper end of the barrier film, and at the lower end of the barrier film. A plurality of linear electrodes arranged in parallel at predetermined intervals so as to intersect the upper linear electrodes, an AC power supply, and one of the plurality of linear electrodes at the upper end are selected, An electrode selector for selecting one of the linear electrodes, connecting only one of the selected top or bottom linear electrodes to one AC power supply, and all other linear electrodes to the other of the AC power supply; For detecting current flowing through the line between the linear electrodes connected to one side of the power supply and one linear electrode selected on the opposite side A detection circuit and a detection circuit for detecting through the output of the current detection circuit, and a plurality of linear electrodes at the top and bottom of the insulation film is sequentially selected to linearly close to the position where the leakage occurs due to breakage of the insulation film. A leak generating position detection system is obtained, which has a processing circuit for detecting a position where a leak occurs based on the output of the detecting circuit rising or falling below the value of other electrode combinations when the electrodes are combined.

According to the present invention, there is also provided a leakage occurrence position detection system applied to a managed end disposition device formed by laying a curtain, a plurality of linear electrodes arranged in parallel at predetermined intervals on the top of the curtain, and at the bottom of the curtain. A plurality of linear electrodes arranged in parallel at predetermined intervals so as to intersect the upper linear electrodes, an AC power supply, an odd number of electrodes adjacent to each other among the plurality of linear electrodes at the top, and the lower ends of the linear electrodes Select an odd number of electrodes adjacent to each other from among a plurality of linear electrodes, and connect only the linear electrodes that are the centers of one of the odd numbered electrodes at the selected top or bottom to one side of the AC power source, and the other linear electrodes An electrode selector for connecting to the other side of the AC power source, a linear electrode serving as a center connected to one side of the AC power source, A current detecting circuit for detecting a current flowing through the order film between the linear electrodes that are the centers of the odd number of linear electrodes selected on the opposite side, and a detection circuit for detecting the output through the output of the current detection circuit, When the plurality of linear electrodes at the bottom are sequentially selected and the linear electrodes close to the position where the leak occurs due to breakage of the membranes are combined, the output of the detection circuit is raised or lowered than the values of other electrode combinations. It is possible to obtain a leak generation position detection system, characterized in that it has a processing circuit for detecting the leak occurrence position. In any leak occurrence position detection system in the system, the detection circuit may detect a phase with respect to the output of the current detection circuit based on the applied voltage of the AC power supply.

In order to facilitate understanding of the present invention, a conventional leak occurrence position detection system will be described with reference to FIG.

Referring to FIG. 1, in the conventional water leakage generating position detection system, the linear electrodes A1 to A5 are disposed at the upper end of the order film 10, and the linear electrodes A1 to A5 at the lower end of the order film 10. The linear electrodes B1 to B5 are arranged in the direction intersecting with each other. The sinusoidal wave output generated from the AC power source 81 is supplied to the power amplifier circuit 82 to amplify the power. The power amplified output passes through the current detection circuit 83 and is a line at the top of the order film 10 through the first electrode selector 84 that selects one of the upper linear electrodes A1 to A5. It is applied to one of the shape electrodes A1 to A5. The power amplifier circuit 82 is further connected to one linear electrode selected from among linear electrodes B1 to B5 at the lower end via the second electrode selector 85.

According to such a configuration, the power amplification is performed by sine wave output generated from the AC power source 81 between one electrode selected from the linear electrodes A1 to A5 at the top and one electrode selected from the lower linear electrodes B1 to B5. The voltage amplified by the circuit 82 is applied, and the current flowing therebetween is detected by the current detection circuit 83.

The phase detection circuit 86 detects the phase of the current detection circuit 83 in a phase synchronized with the applied voltage of the AC power source 81. This phase-detected output is converted into a digital signal by the A / D converter 87 and given to a computer 88 such as a personal computer.

In the above configuration, when there is no damage to the order film 10, since the current flowing between the linear electrodes selected above and below the order film 10 is a current flowing through the capacitive component of the order film 10, the absolute value of the current Is small and the phase advances with respect to the phase of the applied voltage of the AC power supply 81.

On the other hand, when the order film 10 is broken, electric current tends to flow between the linear electrodes selected above and below the damaged place. For this reason, when the combination intersection of the linear electrodes above and below the order film 10 is close to the damaged place, the absolute value of the current becomes large, and the phase of the current tends to be close to the phase of the applied voltage. Therefore, by measuring the current at each intersection of the linear electrodes above and below, it is possible to detect the place where the order film 10 is damaged.

In the conventional detection system, the phase detection circuit 86 is used to measure the current, and the phase detection is performed on the output of the current detection circuit 83 in a phase synchronized with the applied voltage of the AC power source 81 to generate the AC power. The in-phase component of (81) is extracted.

First embodiment

Referring to FIG. 2, in the leak generating position detecting system according to the first embodiment of the present invention, as in the conventional example described with reference to FIG. 1, the linear electrodes A1 to A5 are disposed on the top of the order film 10. The linear electrodes B1 to B5 are arranged at the lower end of the order film 10 in the direction crossing the linear electrodes A1 to A5.

In this embodiment, the first and second electrode selectors 14 and 15 are used. The first electrode selector 14 selects one of the linear electrodes A1 to A5 (in FIG. 2, the linear electrode A3), and has the function of connecting all the remaining linear electrodes in common. The same applies to the second electrode selector 15.

The sinusoidal wave output of the two-phase AC power supply 11 is supplied to the power amplifier circuit 12 so that power is amplified. Between the two-phase AC power source 11 and the linear electrodes A1 to A5 at the upper end, and between the two-phase AC power source 11 and the lower linear electrodes B1 to B5, the first and second electrode selectors ( 14 and 15) are connected as follows.

Referring to FIG. 7, in the linear electrodes A1 to A5 at the upper end, the first electrode selector 14 (not shown in FIG. 7) is shown on one side of the power amplifier circuit 12 connected to the two-phase AC power source 11. One linear electrode A3 selected by the " n " is connected, and the other linear electrodes A1, A2, A4, and A5 are all connected to the other side of the power amplifier circuit 12. In the lower linear electrodes B1 to B5; only B2 to B4 are shown, one linear electrode B3 selected from the second electrode selector 15 (not shown in Fig. 7) is the current detection circuit 13. Is connected to the other side of the power amplifier circuit 12, and the remaining linear electrodes B1, B2, B4, and B5 are all directly connected to the other side of the power amplifier circuit 12.

As a result, current flows between the linear electrode A3 at the upper end and all the other linear electrodes, but the current detection circuit 13 is connected between the linear electrode A3 at the upper end and the linear electrode B3 selected at the lower end. Only current flowing is detected.

Next, a processing circuit for processing the detection result of the current detection circuit 13 will be described. In this embodiment, the processing circuit is a computer 21 according to the first and second phase detection circuits 16 and 17, the square circuit 18, the division circuit 19, the A / D converter 20, and a personal computer. ).

When the current is measured, the first phase detection circuit 16 performs a first phase detection in synchronization with the phase of the two-phase AC power supply 11, and at the same time, the second phase detection circuit 17 performs a two-phase alternating current. The second phase detection is performed in synchronization with the phase 90 degrees ahead of the phase of the power source 11. The division circuit 19 performs the square circuit 18 based on the output of the square circuit 18 and the output of the second phase detection circuit 17 which are squared based on the output of the first phase detection circuit 16. The output of is divided by the output of the second phase detection circuit 17. The calculation result of the division circuit 19 is converted into a digital signal by the A / D converter 20 and given to the computer 21. In addition, since this processing circuit is disclosed in Japanese Patent Application No. 1996-95024, a description of the principle of operation is omitted.

In the case where there is no damage to the order film 10, since the current flowing between the linear electrodes above and below the order film 10 becomes a current flowing through the capacitive component of the order film 10, the absolute value of the current is small, The phase of the applied voltage of the two-phase AC power source 11 is advanced.

On the other hand, when the insulation film 10 is broken, since the current easily flows in the damaged place, the absolute value of the current flowing between the intersections of the linear electrodes located above and below the damage film 10 becomes large, resulting in a two-phase increase. The phase with respect to the phase of the applied voltage of the AC power source 11 tends to be close to the applied voltage. Thus, by using the first and second phase detection circuits 16 and 17, the square circuit 18, and the division circuit 19, current is measured at each intersection of the selected up and down linear electrodes, and thus the current value and Through the phase change, the place where the order film 10 is damaged can be detected with high accuracy.

Further, the linear electrode selection method is such that even if the linear electrodes above and below the order film 10 are reversed, that is, as shown in FIG. 2, the current of the linear electrode A3 is detected by the current detection circuit 13. It goes without saying that even the same measurement accuracy can be obtained.

Second embodiment

Referring to Fig. 3, the leak occurrence position detecting system according to the second embodiment of the present invention has the same parts as the first embodiment using the same numbers as in Fig. 2.

Also in this embodiment, the linear electrodes A1 to A5 are arranged at the upper end of the order film 10, and the linear electrodes A1 to A5 are intersected with the linear electrodes A1 to A5 at the lower end of the order film 10. B1-B5) are arrange | positioned.

In the present embodiment, the first electrode selector 24 selects three adjacent electrodes (linear electrodes A2 to A4 in Fig. 3) among the linear electrodes A1 to A5, and the center of the selected three is selected. An electrode selector having a function of selecting a linear linear electrode (linear electrode A3 in FIG. 3) and connecting the remaining linear electrodes A2 and A4 in common is used. Similarly, the second electrode selector 25 selects three electrodes adjacent to each other (linear electrodes B2 to B4 in FIG. 3), and a linear electrode serving as a center among the selected three (linear in FIG. 3). Electrode B3), and the remaining linear electrodes B2 and B4 are connected in common.

In the present invention, the number of linear electrodes selected by the first and second electrode selectors is not limited to three, but may be odd.

The power of the AC power supply 22 is amplified by the power amplifier circuit 23. The AC power supply 22, the upper linear electrodes A1 to A5 and the lower linear electrodes B1 to B5 are connected by the first and second electrode selectors 24 and 25 as follows. In the linear electrode at the upper end, the linear electrode A3 which becomes the center among three selected by the 1st electrode selector 24 is connected to one side of an AC power supply, and all the other linear electrodes A2 and A4 are connected. It is connected to the other side of AC power. In the lower linear electrode, the linear electrode B3, which is the center of three selected by the second electrode selector 25, is connected to one side of the AC power supply via the current detection circuit 13, and the other linear The electrodes B2 and B4 are both directly connected to the other side of the AC power source.

As a result, current flows between the upper linear electrode A3 and the linear electrodes A2, A4, B2, B3, and B4, but in the current detection circuit 23, the upper linear electrode A3 and the lower end are present. Only the current flowing between the linear electrodes B3, which is the center selected in the step, is detected.

The processing circuit which processes the detection result of the current detection circuit 26 includes a detection circuit 27, an A / D converter 20, and a computer 21.

When there is no damage to the order film 10, since the current flowing between the linear electrodes above and below the order film 10 becomes a current flowing through the capacitive component of the order film 10, the absolute value of the current is small and the The phase of the applied voltage is advanced.

On the other hand, when the damage occurs in the order film 10, since the current easily flows in the damaged place, the absolute value of the current increases when the intersection of the linear electrodes above and below the order film 10 is close to the location where the damage occurs. The phase of the applied voltage of the AC power supply 22 tends to be close to the applied voltage. Thus, by measuring the current at each intersection of the linear electrodes above and below, it is possible to accurately detect the place where the order film 10 is damaged from the output of the detection circuit 27 indicating the absolute value of the current.

Moreover, the processing circuit of FIG. 3 can also be used as the processing circuit of the first embodiment described with reference to FIG.

Third embodiment

Referring to FIG. 4, the leak detection position detecting system according to the third embodiment of the present invention is different from the phase detection circuit 28 in the processing circuits, and is otherwise identical to the second embodiment described with reference to FIG. . Therefore, only the operation of the processing circuit will be described.

In this embodiment, the phase detection circuit 28 detects the phase and the synchronous phase of the AC power supply 22.

When there is no damage to the order film 10, since the current flowing between the linear electrodes above and below the order film 10 becomes a current flowing through the capacitive component of the order film 10, the absolute value of the current is small and the AC power supply 22 The phase of the applied voltage of is advanced.

On the other hand, when the insulation film 10 is broken, since the damaged place is likely to flow current, when the combined intersection point of the linear electrodes above and below the insulation film 10 is close to the damaged place, the absolute value of the current becomes large and the AC power source ( The phase of the applied voltage of Fig. 22) tends to be close to the applied voltage. In this way, the phase detection circuit 28 is used to measure the current at each intersection of the linear electrodes on the upper and lower sides, whereby the order film 10 is damaged by the alternating current power supply 22 and the in-phase component current. It becomes possible to detect with high precision.

The processing circuit of FIG. 4 can also be used as the processing circuit of the first embodiment.

Fourth embodiment

Referring to Fig. 5, in the leak occurrence position detecting system according to the fourth embodiment of the present invention, the main part of the processing circuit of the first embodiment described with reference to Fig. 2 instead of the processing circuit of the second embodiment described with reference to Fig. 3 Addition is used. Therefore, the same reference numerals as those in FIG. 2 or FIG. 3 are used for the same parts as those in the first or second embodiment in FIG.

In the present embodiment, the processing circuit includes the first and second phase detection circuits 16 and 17, the division circuit 29, the A / D converter 20, and the computer 21.

In the processing circuit, the first phase detection circuit 16 synchronizes the phase of the two-phase AC power supply 11 with the phase and the second phase detection circuit 17 of the two phase AC power supply 11. A second phase detection is made in synchronization with the phase advancement 90 degrees from the phase. Through the outputs of the first phase detection circuit 16 and the second phase detection circuit 17, the division circuit 29 converts the output value of the first phase detection circuit 16 to the output value of the second phase detection circuit 17. Divide

When there is no damage to the order film 10, since the current flowing between the linear electrodes above and below the order film 10 becomes a current flowing through the capacitive component of the order film 10, the absolute value of the current is small and the two-phase AC power supply ( The phase of the applied voltage of 11) is advanced.

On the other hand, when the breakage occurs in the insulation film 10, since the current easily flows to the damaged place, the absolute value of the current becomes large when the combination intersection of the linear electrodes on the top and bottom of the insulation film 10 is close to the damage place. The phase advance of the applied voltage of the AC power supply 11 tends to be close to the applied voltage. Accordingly, by using the first and second phase detection circuits 16 and 17 and the division circuit 29, the current value and phase change are measured by measuring the ratio of the current phase components to the intersections of the linear electrodes on the upper and lower sides. Through it, it is possible to detect the place where the order film 10 is damaged with high accuracy.

The processing circuit can also be used in place of the processing circuit of the first embodiment.

Fifth Embodiment

Referring to Fig. 6, in the leak generating position detecting system according to the fifth embodiment of the present invention, the processing circuit of the first embodiment described with reference to Fig. 2 is used instead of the processing circuit of the second embodiment described with reference to Fig. do. Therefore, the same reference numerals as those in FIG. 2 or FIG. 3 are used for the same portions as those in the first or second embodiment in FIG.

In the processing circuit, as described with reference to FIG. 2, the first phase detection circuit 16 performs first phase detection in synchronization with the phase of the two-phase AC power source 11, and the second phase detection circuit 17. As a result, the second phase detection such as the phase synchronized with the 90-degree phase advance from the phase of the two-phase AC power source 11 is performed. The division circuit 19 performs the square circuit 18 according to the output of the square circuit 18 and the output of the second phase detection circuit 17 which perform square calculation according to the output of the first phase detection circuit 16. The output value is divided by the output value of the second phase detection circuit 17.

When there is no damage to the order film 10, since the current flowing between the linear electrodes above and below the order film 10 becomes a current flowing through the capacitive component of the order film 10, the absolute value of the current is small and the two-phase AC power supply ( The phase of the applied voltage of 11) is advanced.

On the other hand, when the insulation film 10 is broken, since the damaged place tends to flow current, when the combination intersection of the linear electrodes above and below the insulation film 10 is close to the place where the damage is broken, the absolute value of the current becomes large and the two-phase alternating current is increased. The phase of the applied voltage of the power supply 11 tends to be close to the applied voltage. For this reason, the current value is measured by measuring current at each intersection of the linear electrodes on the upper and lower sides by using the first and second phase detection circuits 16 and 17, the square circuit 18, and the division circuit 19. Through the phase change, the place where the order film 10 is damaged can be detected with high accuracy.

FIG. 7 is a diagram for explaining a current path that is commonly applied not only to the first embodiment but also to the second to fifth embodiments. However, the two-phase AC power supply 11, the power amplification circuit 12, and the current detection circuit 13 are read by the AC power supply, the power amplification circuit, and the current detection circuit of each embodiment. Referring to FIG. 7, there is waste at the top of the shielding film 10. The current flowing through the disposal site is a current flowing through the waste by a voltage applied between one linear electrode A3 selected at the upper end of the order film 10 and the other upper linear electrodes A1, A2, A4, and A5. And a combined current of the current flowing through the order film 10.

In the case where there is no damage in the order film 10, a current flowing through the waste exists. On the other hand, since the current flowing through the order film 10 flows through the capacitive component of the order film 10, the current becomes relatively very small. When the current is measured, since the current flowing through the selected linear electrode B3 at the lower end of the order film 10 is measured, when there is no damage in the order film 10, a very fine current is detected as a measurement result. .

8A and 8B are diagrams showing an example of measurement results when the processing circuit of the first, fourth, or fifth embodiment described with reference to FIGS. 2, 5, or 6 is used. Even if two places are damaged in the order film 10, since the current value increases at each of the damaged places, the breakage of the two places is clearly distinguished.

As described above, in the water leakage generating position detection system according to the present invention, the current path flowing through the insulation film is centered on the linear electrode at the upper end of the insulation film connected to one side of the AC power supply (power amplifier connected to the AC power supply). The width of both linear electrodes is defined as the width of both linear electrodes, and the measurement of current is also performed at the lower end of the order film, centering on one linear electrode selected from the linear electrodes connected to the other side of the AC power supply. It is limited to. As a result, the measurement area is limited, and mutual influences due to a plurality of breakages are eliminated.

Furthermore, since a linear electrode is provided for the measurement in the vicinity of the shielding film, the difference in electrical characteristics and the depth of embedding according to the type of waste to be treated in the disposal site do not affect the detection accuracy.

Therefore, the leak position detecting system according to the present invention is not only economically effective, but also detects the leak occurrence position at an early time and can minimize the environmental damage.

1 is a configuration diagram showing an example of a conventional leak occurrence position detection system.

Fig. 2 is a diagram showing the configuration of the leak occurrence position detecting system according to the first embodiment of the present invention.

3 is a diagram showing the configuration of a leak occurrence position detecting system according to a second embodiment of the present invention.

4 is a diagram showing the configuration of a leak occurrence position detecting system according to a third embodiment of the present invention.

5 is a diagram showing the configuration of the leak occurrence position detecting system according to the fourth embodiment of the present invention.

Fig. 6 is a diagram showing the configuration of the leak occurrence position detecting system according to the fifth embodiment of the present invention.

7 is a diagram for explaining the current paths in the first to fifth embodiments.

8A and 8B show an example of the measurement result of the processing circuit according to the present invention.

Explanation of symbols on the main parts of the drawings

10: shield film 11: two-phase AC power supply

12: power amplifier circuit 13: current detection circuit

14: first electrode selector 15: second electrode selector

16. First Phase Detection Circuit 17: Second Phase Detection Circuit

18: square circuit 19: division circuit

20: A / D Converter 21: Computer

Claims (4)

In the leak occurrence position detection system used in the management type end disposal equipment formed by laying a curtain, A plurality of linear electrodes arranged in parallel at predetermined intervals on top of the order film; A plurality of linear electrodes arranged at a lower end of the order film in parallel at predetermined intervals so as to intersect the upper linear electrodes; AC power supply; One of the plurality of linear electrodes at the top is selected, and one of the plurality of linear electrodes at the bottom is selected, and only one of the selected top or bottom linear electrodes is connected to one side of the AC power supply. An electrode selector for connecting all the other linear electrodes to the other side of the AC power source; A current detection circuit for detecting a current flowing through the order film between the linear electrode connected to one side of the AC power supply and one linear electrode selected on the opposite side; And And a detection circuit for detecting through the output of the current detection circuit, and sequentially selecting a plurality of linear electrodes at the top and bottom of the insulation film so that the insulation film is broken so that the linear electrode close to the position where the leakage occurs is combined. And a processing circuit for detecting a position at which leakage occurs based on the output of the detection circuit rising or falling below values of other electrode combinations. The leak detection position detection system according to claim 1, wherein the detection circuit performs phase detection of an output of the current detection circuit on the basis of an applied voltage of the AC power supply. In the leak detection position detection system applied to the managed end disposal equipment formed by laying a curtain, A plurality of linear electrodes arranged at predetermined intervals in parallel to an upper end of the order film; A plurality of linear electrodes arranged at predetermined intervals to be parallel to a lower end of the order film and to intersect the upper linear electrodes; AC power supply; While selecting an odd number of electrodes adjacent to each other among the plurality of linear electrodes at the top, and selecting an odd number of electrodes adjacent to each other among the plurality of linear electrodes at the bottom, one of the odd number of electrodes at the selected top or bottom An electrode selector for connecting only the linear electrode serving as the center of the power supply to one side of the AC power supply, and all the other linear electrodes to the other side of the AC power supply; A current detection circuit for detecting a current flowing through the order film between a linear electrode serving as a center connected to one side of the AC power supply and a linear electrode serving as a center among an odd number of linear electrodes selected on the opposite side; And A detection circuit for detecting through the output of the current detection circuit, and sequentially selecting a plurality of linear electrodes at the top and bottom of the insulation film so that the insulation film is broken so that the linear electrodes close to the position where the leakage occurs are combined. And a processing circuit for detecting a leak occurrence position on the basis of the output of the detection circuit rising or falling below values of other electrode combinations. The leak detection position detection system according to claim 3, wherein the detection circuit performs phase detection of an output of the current detection circuit on the basis of an applied voltage of the AC power supply.