KR100503713B1 - Apparatus for searching a electric leakage point on buried cable and the method - Google Patents

Abstract

The present invention is buried in the ground, but the ground leakage line is generated by the break point of the cable; A transmitter having a pulse generator for generating a high voltage pulse signal and applying the same to the earth leakage line, a pulse emission line connecting the pulse generator and the earth leakage line, and a ground rod connecting the pulse generator and the earth; And a detection frame having a shape of a substantially '∩' shape having a plurality of probes directly contacting the ground in order to sense an electric current emitted from the pulse generating device to the ground through an earth leakage point of an earth leakage line, and from the ground In order to facilitate the capture of the leakage current is installed on the lower end of the probe, the conduction member is moistened with the accelerating solution in contact with the ground, the earth leakage detection device is installed in the center of the upper end of the detection frame for detecting and amplifying the leakage current, and the Installed in the ground fault detecting device, the slope of the guideline is changed according to the direction and intensity of the current flowing through the probe, and has a measuring system for indicating the direction of the ground fault point. In this case, force the high-voltage pulse current to flow into the earth leakage line, and then detect the current leaking to earth through the earth leakage point to correct the earth leakage point. As identified by finding the exact leakage position without rip and replace a cable short circuit is suspected to repair only the leakage site provides a short circuit that underground exploration apparatus and method by which to reduce the physical, temporal loss.

Description

Grounding point exploration device and method thereof of underground line

The present invention relates to a ground fault point detection system of a underground line, and more particularly, by applying a high-voltage pulsed DC power supply to a ground line using a characteristic of a direct current flowing in one direction, the direction of the current flowing out from the ground fault point of the ground line. The present invention relates to a device and a method for detecting and finding an accurate leakage position.

The present invention is directed to underground cables which cannot be visually checked and cannot be directly identified and accessed due to the non-exposure characteristics of the function and installation specifications. It provides accurate and efficient exploration method to accurately find and repair the leakage point when leakage occurs by cutting, cutting and covering.

In general, in the case of an electric cable installed under the ground because the exposure on the ground is not desirable, when the electric leakage of the cable occurs, it is impossible to pinpoint the electric leakage position due to invisibility and lack of suitable equipment. Has been implemented.

As an example, when a ground leakage wire for a street lamp is leaked, it is confirmed as a mega tester, and the related tester equipment starts at one end of the earth leakage cable and detects the ground wire. Even the exploration work by correct setting did not have the efficiency and effectiveness by replacing it with a wide range of short-circuit prediction section instead of capturing the short-circuit point.

If the leakage point is correctly captured, the scope of follow-up work can be determined locally, but in the case of a short-circuit expected section, the follow-up work can be performed as if it was a front work, and there was no local work of the earth leakage site at the actual site. .

The earth leakage repair work according to the prior art has been a problem that brings a lot of material, time loss due to uneconomical and unreasonable work because it is replaced by an undamaged wire.

Therefore, the present invention has been made to solve the above problems of the prior art, the current leaked to the ground through the earth leakage point after forcing a high-voltage pulse current flows to the earth leakage line when the earth leakage cable occurs The purpose of the present invention is to provide an economical repair method that reduces the material and time loss by finding the exact location of the leakage and repairing the leakage area without replacing the cable suspected of short circuit.

Technical means of the present invention for achieving the above object, an earth leakage line which is buried in the ground, the earth leakage point is generated by the breakage of the cable; A transmitter having a pulse generator for generating a high voltage pulse signal and applying the same to the earth leakage line, a pulse emission line connecting the pulse generator and the earth leakage line, and a ground rod connecting the pulse generator and the earth; And a detection frame having a shape of a substantially '∩' shape having a plurality of probes directly contacting the ground in order to sense an electric current emitted from the pulse generating device to the ground through an earth leakage point of an earth leakage line, and from the ground In order to facilitate the capture of the leakage current is installed on the lower end of the probe, the conduction member is moistened with the accelerating solution in contact with the ground, the earth leakage detection device is installed in the center of the upper end of the detection frame for detecting and amplifying the leakage current, and the Characterized in that consisting of a receiving detector having a measuring system, which is installed in the ground fault detection device is inclined in accordance with the direction and intensity of the current flowing through the probe to indicate the direction of the ground fault point.

Technical method of the present invention for achieving the above object, in the method of exploring the ground fault point of the underground line: after checking whether the ground line to be explored whether the ground fault is separated from other lines and load Disconnecting from the ground line; Connecting a power line of the transmitter to the ground line and connecting a ground line of the transmitter to a ground and then applying a high voltage pulse current to the ground line; The high-voltage pulse current leaks to the ground surface at an earth leakage point and flows into the ground line of the transmitter; The leakage current is sensed using a reception detector on the ground where the leakage line is buried, and the instructions installed in the reception detector are directed to the leakage point by inducing a large amount of leakage current among the plurality of probes or by inclining the probe with the greater strength. Detecting; Moving the reception detector in a direction in which the guide is inclined and approaching the position of the ground fault when the guide is inclined to the right or left; Detecting a short circuit crossing point by rotating the reception detector by 90 ° when the inclination of the instruction while moving the reception detector is zero; And determining the position of the ground fault point of the ground fault line when the inclination of the guide line according to the current direction transmitted through the probe of the reception detector is zero as a result of the remeasurement.

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When the leakage point is detected, the reception detector detects the amount of leakage current flowing to the ground through a plurality of probes, and the guide is inclined toward the probe to which the amount of leakage current is applied.

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

1A and 1B illustrate a schematic configuration of an earth leakage point detecting apparatus for a underground line according to an exemplary embodiment of the present invention. FIG. 1A shows a transmitter and FIG. 1B shows a reception detector.

As shown in Figure 1a and Figure 1b, the present invention detects the flow of the high voltage pulse current applied from the transmitter 100 and the transmitter 100 for applying a momentary high voltage pulse current to the earth leakage line 300 It consists of a reception detector 200 to find the earth leakage position.

The transmitter 100 includes a pulse generator 110 (transmitter) including a predetermined pulse generator circuit, and a connection line connecting the pulse generator 110 and the leakage line 300 from the pulse generator 110. Signal discharged from the earth leakage point 310 at the same time as the grounding function as a connection line between the pulse emission line 120 and the pulse generating device 110 and the ground to apply the generated high-voltage pulse current to the earth leakage line 300 The ground wire 130 and the ground wire 130 to form a circuit to be introduced back into the pulse generator 110 through the ground, and the auger shape so that the ground wire 130 is directly connected to the ground to perform the grounding function and It consists of a grounding rod 140 formed in the shape of a pointed and long metal bar.

In addition, the power supply of the transmitter 100 may generate power by itself using a gel cell type rechargeable battery, and may apply a high voltage pulse current through the generated self power.

In addition, the reception detector 200 includes a ground fault detecting device 210 including a normal inspection circuit and an amplification circuit, and a plurality of direct contact with the ground to deliver pulses flowing to the ground to the ground fault detecting device 210. The detection frame 220 having the probes 221 and 225 and sensing the current flowing through the ground and applied to the ground fault detecting device 210 and when the ground is made of soil, can be directly measured on the ground. If the ground is composed of a sidewalk block, cement, asphalt, etc., the ground of the detection frame 220 is not activated, so that it is difficult to receive an accurate current, the conductive promoting member 230 is used to smoothly ground the detection frame 220. .

The detection frame 220 has a plurality of probes 221 and 225 in a substantially '∩' shape, and a ground fault detecting device 210 is installed at a central upper end of the plurality of probes 221 and 225. .

The conductive facilitating member 230 is made of a sponge material, and improves the conductivity by using salt water when used.

In addition, the ground fault detecting device 210 includes a galvanizing circuit and an amplifying circuit to sense a small current flowing through the earth and to amplify it through the amplifying circuit, and the amplified current passes through the galvanizing circuit to change the direction and intensity of the current. The measurement system 211 of the ground fault detecting device 210 is shown through the inclination of the guide 215.

FIG. 2 is a view schematically illustrating a basic principle of an earth leakage point exploration apparatus and a method thereof of a underground line according to an exemplary embodiment of the present invention.

In the present invention, a direct current power source is used, and the basic principle that the direct current flows from plus (+) to minus (-), that is, in one direction is applied.

As shown in FIG. 2, the present invention generates a high voltage pulse current in the pulse generator 110 including a pulse generation circuit and applies instantaneous high voltage pulse current to the earth leakage line 300.

When the high voltage pulse current is applied, an instantaneous electrical circuit is formed between the pulse generator 110 → pulse emission line 120 → earth leakage line 300 → earth leakage point 310 → earth 400 → ground rod 140. It is formed to locate the ground fault point 310 by the flow of current flowing through this circuit.

Here, the current of the high-voltage pulse generated through the pulse generator 110 is a safe current in the range that the voltage is high, but the size of the current is very small and does not affect the human body. In addition, the voltage alone does not affect the human body electric shock.

In order to find the ground fault point 310, the reception detector 200 including the ground fault detection device 210 is used.

The earth leakage detecting apparatus 210 of the reception detector 200 includes a predetermined galvanic circuit and an amplifying circuit. Since the high voltage pulse generated by the pulse generator 110 has a high voltage but a very small current, it is necessary to amplify the minute current signal through the amplification circuit to detect the signal in the ground fault detecting apparatus 210.

The signal amplified by the amplification circuit detects the flow of the DC current while passing through the inspection circuit. The guide 215 of the measuring system 211 of the ground fault detecting device 210 operates according to the direction and magnitude of the current sensed through the galvanic circuit.

3A to 3C are diagrams illustrating the movement of a guide of a measuring system corresponding to a position of a ground fault point according to an exemplary embodiment of the present invention, and FIG. 3A is a tilt of the guide of the measuring system when a ground fault detecting device is located to the left of the ground fault point. Figure 3b shows the slope of the guideline of the measuring system when the ground fault detection device is located to the right of the ground fault point, Figure 3c shows the slope of the guideline of the measurement system when the position of the ground fault point and the ground fault detection device is the same Each is shown.

The current flowing into the detection frame 220 of the reception detector 200 passes through the galvanic circuit of the ground fault detecting device 210 and detects its direction. When the direction of current is sensed, the guide 215 of the ground fault detecting device 210 moves in the direction of the incoming current, and the movement of the guide 215 also increases according to the magnitude of the incoming current.

That is, when the ground fault detecting device 210 is located at the left side of the ground fault point 310 as shown in FIG. 3A, the leakage current leaked at the ground fault point 310 is the second probe 225 and the ground fault detection device 210. And sequentially pass through the first probe 221 and then to the pulse generator 110. Here, since the second probe 225 of the reception detector 200 is closer to the leakage point 310 than the first probe 221, the direction of the current is the second probe 225 → the ground fault detecting device 210 → As the path of the first probe 221 flows, the guide 215 of the measurement system 211 is inclined toward the second probe 225, that is, to the right to indicate the position of the ground fault point 310. .

Meanwhile, when the ground fault detecting device 210 is located at the right side of the ground fault point 310 as shown in FIG. 3B, the leakage current leaked at the ground fault point 310 is the first probe 221 and the ground fault detecting device 210. And sequentially passing through the second probe 225 to the pulse generator 110. Here, since the first probe 221 of the reception detector 200 is closer to the earth leakage point 310 than the second probe 225, the direction of the current is the first probe 221 → the earth leakage detection device 210 → The second probe 225 flows along the path, so that the guide 215 of the measurement system 211 is inclined toward the first probe 221, that is, to the right, to indicate the location of the ground fault point.

3C illustrates a case where the locations of the ground fault point 310 and the ground fault detection device 210 coincide with each other, and the leakage current leaked at the ground fault point 310 may include a first probe 221 and a second probe ( Since 225 is located at the same distance, the amount of current applied to the ground fault detecting device 210 through the first probe 221 and the second probe 225 is the same. Thus, the guidance 215 of the measurement system 211 indicates a zero point (eg, when the guidance is vertical).

In this case, the larger the amount of current and the intensity of the leakage current, the larger the movement of the guide 215, the more the guide 215 moves closer to the location of the short-circuit or the short-circuit state can be seen.

In the method for receiving an electric leak position using the reception detector 200 described above, the reception detector 200 is moved in both directions in which the earth leakage line 300 extends from the point where the electric leak is suspected, and the guide 215 of the measurement system 211 is moved. Look in the direction.

If the guide 215 of the measurement system 211 is positioned in the middle while the reception detector 200 is moved, the x-axis or the y-axis of the ground fault position in the detection direction coincides. At the point where the guide 215 of the measurement system 211 is located in the center, the detection detector 200 is rotated in the 90 ° direction to repeat the detection in the same manner.

In this way, the leakage point 310 is detected, and if the guideline 215 of the measurement system 211 is also located in the middle of the position, the position is determined as the leakage point.

4 is a flow chart briefly illustrating a process for an earth leakage point exploration method of a underground line according to an exemplary embodiment of the present invention.

In the earth leakage point exploration device and method thereof as shown in the figure, first, the insulation resistance of the line to be explored is measured to check whether there is a short circuit, and then, the line having the short circuit is separated, separated from other lines, and supplied from the outside. The power and the load are disconnected from the ground line 300 (S110).

As described above, the earth leakage line 300 separated from other lines is connected to the pulse generator 110. The pulse generator 110 and the earth leakage line 300 are connected by a pulse emitter 120, in which the pulse emitter 120 is connected to the positive terminal (+) of the pulse generator 110. The negative terminal (-) of the pulse generator 110 is connected to the ground 400 through the ground wire 130, and the ground wire 130 is directly connected to the ground 400 through the ground rod 140 when the ground wire 130 is connected to the ground 400. It is plugged in (S120).

In this case, in a facility such as a street light 500, if there is a ground rod connecting the street light 500 and the ground 400 separately, the ground rod 140 may be grounded without the use of the ground rod 140.

In the reception detector 200, the ground fault detecting device 210 and the detection frame 220 or the conductive acceleration member 230 are installed according to need, and the guide 215 is provided in the measurement system 211 of the ground fault detecting device 210. Adjust to position at the center '0' (S130).

Turn on the power to the pulse generator 110 and instantaneously apply a high-voltage pulse current to the earth leakage line 300 to generate a pulse generator 110 → pulse emission line 120 → earth leakage line 300 → earth leakage point 310 → Earth 400 → to form a circuit consisting of the ground rod 140 of the pulse generator (S140).

In applying the high voltage pulse current from the pulse generator 110 to the leakage line 300, the pulse current is instantaneously applied but is periodically applied at intervals of several seconds. This is to distinguish the noise other than the pulse generated through the pulse generator 110 when the pulse current is applied.

In this way, the pulse current is periodically applied, and the ground fault detecting device 210 observes the position of the measurement system 211 and the guide 215 and moves the reception detector 200 to the material of the ground fault point based on the analysis of the movement of the pulse. Go out (S150).

When the measurement system 211 of the ground fault detecting device 210 is positioned at the zero point, the reception detector 200 is rotated by 90 ° to detect one more time as described above. In other words, by matching both the x-axis and y-axis of the ground fault position in the detection direction to find the correct ground fault position (S160).

As a result of the re-measurement, when the inclination of the guide 215 according to the current direction transmitted through the probes 221 and 225 of the reception detector 200 is zero, the position of the ground fault point 310 of the ground fault line 300 is determined. do.

When the leakage point 310 is explored using the slope of the guide 215, the guide 215 may be a probe 221 or 225 having a greater amount of leakage current or a higher strength among the plurality of probes 221 and 225. It is preferable to set to tilt.

The technical spirit of the present invention has been described above with reference to the accompanying drawings, which illustrate exemplary embodiments of the present invention by way of example and does not limit the present invention. In addition, it is obvious that any person skilled in the art may make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Therefore, as described above, when an earth leakage occurs in the underground cable, a high-voltage pulse current is forced through the earth leakage line, and then the current leaks to the ground through the earth leakage point to accurately detect the earth leakage point. The accuracy and promptness of the rational measures in the preliminary and follow-up work, and the accuracy and speed of the follow-up work, contribute to the excellent adaptability and stability in the field, and to decisively contribute to the prevention of safety accidents caused by the short-circuit cable in rainfall or flooded areas. have.

In addition, the present invention compared to the conventional method of replacing the cable suspected of leaking when a short circuit occurs, the present invention provides an economical repair method that finds the exact location of the earth leakage and repairs only the corresponding fault area, economical repair to reduce material and time loss There is also the effect of providing a method.

1A and 1B are diagrams schematically illustrating an earth leakage point exploration apparatus of a underground line according to an exemplary embodiment of the present invention.

Figure 2 is a simplified view showing the basic principle of the earth leakage point exploration device method of the underground line according to an embodiment of the present invention.

3A to 3C are diagrams illustrating a guide movement of a measurement system according to a position of a ground fault detecting apparatus corresponding to a ground fault point position according to an exemplary embodiment of the present invention.

4 is a flow chart briefly illustrating a process for an earth leakage point exploration method of a underground line according to an exemplary embodiment of the present invention.

     Explanation of symbols on main parts of drawing

100: transmitter 110: pulse generator

120: pulse emission line 130: ground line

140: ground rod 200: reception detector

210: ground fault detection device 211: measuring system

215: Needle 220: Detection frame

221, 225 probe 230: conductive member

300: leakage line 310: leakage point

400: earth 500: street light

Claims (6)

An earth leakage line buried in the ground but having a short circuit point due to breakage of the cable; A transmitter having a pulse generator for generating a high voltage pulse signal and applying the same to the earth leakage line, a pulse emission line connecting the pulse generator and the earth leakage line, and a ground rod connecting the pulse generator and the earth; And A detection frame of approximately '∩' shape having a plurality of probes in direct contact with the ground for detecting a current emitted from the pulse generator to the ground through an earth leakage point of an earth leakage line, and leakage from the ground In order to facilitate the capture of electric current, a conductive facilitating member is provided at the lower end of the probe wetted with the accelerating solution, and an electric leakage detecting device is installed at the center of the upper end of the detection frame and detects and amplifies leakage current. Earth leakage point detection device of the underground line, characterized in that consisting of a receiving device having a measuring system, which is installed in the sensing device is inclined in accordance with the direction and intensity of the current flowing through the probe indicating the direction of the earth leakage point; . delete delete delete In the way of exploring the leakage point of underground line: Checking whether the underground line to be probed is short-circuited and disconnecting the line from which the short-circuit has occurred and disconnecting the load from the ground line; Connecting a power line of the transmitter to the ground line and connecting a ground line of the transmitter to a ground and then applying a high voltage pulse current to the ground line; The high-voltage pulse current leaks to the ground surface at an earth leakage point and flows into the ground line of the transmitter; The leakage current is sensed using a reception detector on the ground where the leakage line is buried, and the instructions installed in the reception detector are directed to the leakage point by inducing a large amount of leakage current among the plurality of probes or by inclining the probe with the greater strength. Detecting; Moving the reception detector in a direction in which the guide is inclined and approaching the position of the ground fault when the guide is inclined to the right or left; Detecting a short circuit crossing point by rotating the reception detector by 90 ° when the inclination of the instruction while moving the reception detector is zero; And And determining the position of the ground fault point of the ground fault line when the inclination of the guide line according to the current direction transmitted through the probe of the reception detector is zero as a result of the re-measurement. delete