KR101986827B1 - Apparatus and method for service wire identify using leakage current - Google Patents

Abstract

The present invention relates to an apparatus and method for detecting a lead-in line using a leakage current, comprising: a leakage current generating unit provided in a lead line to be identified and generating a leakage current by dividing a component; A leakage current circuit part provided in parallel to the ground of the lead-in line to flow the leakage current; And a leakage current detector for detecting the leakage current to the earthing point of the lead-in line at the branch point and determining that the lead-in line for identifying the lead-in line in which the detected leakage current exists is to be identified.

Description

[0001] APPARATUS AND METHOD FOR SERVICE WIRE IDENTIFY USING LEAKAGE CURRENT [0002]

The present invention relates to a lead-in line identification apparatus and method using leakage current, and more particularly, to a lead-in line identification apparatus and a method thereof, in which a circuit through which a leakage current artificially generated in a lead- Device and method thereof.

A tester is used to identify a desired wire in a state where a large number of wires are installed during the construction and repair work of fire fighting, electricity, and communication lines in the identification work of a wire to be searched in a place where a large number of wires are installed.

In order to find a desired wire among the wires using such a tester, the current flowing through the wire must be blocked, and in some cases, the wire must be peeled off or short-circuited to damage the wire.

In the case where the electric wires are long, two workers are arranged. One worker is located at one end and the other worker is located at the other end, using a tester resistance detection function as disclosed in Korean Patent Application No. 10-2009-0120561 I had to find and find one of several strands.

This work is not efficient because it takes a lot of time as the number of wires increases, and when the distance between one worker and the other worker is long, a separate walkie-talkie must be used to work while talking.

Therefore, it is possible to quickly and easily identify the desired wire even when the wire is electrically connected, without removing the cover or shorting the wire in identifying the wire to which the wire is installed. There is a demand for a device capable of locating a location.

SUMMARY OF THE INVENTION The present invention has been developed in order to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for detecting a leakage current by detecting a leakage current flowing through the ground through a circuit through which a leakage current generated artificially, The present invention is directed to a lead line identification apparatus and method using the leakage current that can quickly and easily identify the configuration and components of a lead line.

Another object of the present invention is to provide a lead-in line identifying apparatus and a method thereof, which can quickly and easily identify a lead line to be searched among lead-in lines in which a large number of wires are installed, without removing or short- .

In addition, the present invention converts the leakage current into a coded signal by a short or long time difference in identifying the components and configuration of the customer's incoming lead through the detected leakage current component, and allows the field workers to quickly and easily identify And an object thereof is to provide an apparatus and method for detecting a lead line using a leakage current.

According to an aspect of the present invention, there is provided a lead line identification apparatus using leakage current, the lead line identification apparatus comprising: a leakage current generation unit provided in a lead line to be identified, A leakage current circuit part provided in parallel to the ground of the lead-in line to flow the leakage current; And a leakage current detector for detecting the leakage current flowing back to the ground of the lead-in line at the branch lead-in point and determining that the lead-in line for identifying the lead-in line in which the detected leakage current is present is to be identified, The current generating unit includes: a coding unit that converts a leakage current into a coded signal by a short or a time difference according to a component; A size setting unit for setting a magnitude of a leakage current; And a controller for controlling the leakage current generating unit to operate or stop.

In addition, the leakage current generating unit is characterized by generating a leakage current component by dividing the leakage current into one of a capacitive leakage current (lgc) and a resistance (lgr) leakage current.

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The leakage current circuit portion is characterized by being formed in the form of a capacitive circuit in which a capacitive leakage current lgc flows according to a component of a leakage current or a resistive circuit in which a resistive leakage current lgr flows.

The leakage current detector may further include: an analyzer for analyzing the coded signal of the detected leakage current;

An identification unit for identifying the configuration and components of the lead-in line to be identified through the coded signal of the analyzed leakage current; And a display unit for displaying on the display screen a code number corresponding to the detected leakage current coded signal and a configuration and components of the lead line identified.

According to another aspect of the present invention, there is provided a method of identifying a lead line using a leakage current, the method comprising: generating a leakage current by dividing a component by a leakage current generator provided in a lead line to be identified; Flowing the leakage current by a leakage current circuit unit provided in parallel to the ground of the lead-in wire; Detecting the leakage current from the branch lead-in point to the ground of the lead line by the leakage current detecting section; And a step of determining, by the leakage current detector, that the lead-in line having the detected leakage current exists and is the lead-in line to be identified, wherein the step of generating a leakage current includes: The size setting unit sets the magnitude of the leakage current, and the control unit controls the operation or stop of the leakage current generating unit.

In addition, in the step of generating a leakage current, the leakage current generating section generates a leakage current component by dividing the leakage current into one of a capacitive leakage current (lgc) and a resistance (lgr) leakage current.

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Further, in the step of flowing a leakage current, the leakage current circuit portion is configured in the form of a capacitive circuit in which a capacitive leakage current lgc flows in accordance with a component of a leakage current, or a resistive circuit in which a resistive leakage current lgr flows .

Also, the step of identifying the lead-in line in which the leakage current exists and determining that the lead-in line is to be identified includes: analyzing a coded signal of the leakage current detected by the analysis unit; Identifying a configuration and a component of the lead line to be identified through the coded signal of the leakage current analyzed by the identification unit; And displaying the code number of the coded signal of the leakage current detected by the display unit and the configuration and components of the lead line identified on the display screen.

According to the present invention, there is provided an apparatus and method for identifying a lead-in line using leakage current, comprising: a circuit for flowing a leak current artificially generated in a lead-in line for a customer; There is an effect that the constitution and components of the lead-in wire in which the leakage current is detected can be accurately identified.

In addition, the present invention has the effect of remarkably reducing manpower and work time since it is possible to quickly identify a lead line to be searched out among the lead-in lines in which a large number of wires are installed, even when the cover is not removed or short-circuited.

In addition, the present invention converts the leakage current into a coded signal by a short or long time difference in identifying the components and configuration of the customer's incoming lead through the detected leakage current component, and allows the operator in the field to easily identify the coded signal based on the coded signal The convenience and workability can be remarkably improved.

In addition, the present invention integrates the functions of the conventional load current detection device so as to simultaneously test for leakage and lead-in line identification, thereby reducing the waste of components and manufacturing costs that can occur when the detection devices are separately manufactured There is an effect that can be.

Further, the present invention enables remote control of a worker, so that not only the effect of manpower allocation due to manpower saving can be expected, but also efficiency and speed of work can be maximized.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of a lead-in line identifying apparatus using a leakage current according to an embodiment of the present invention; FIG.
2 is a view showing a detailed configuration of a leakage current generating unit employed in a lead-in line identifying apparatus using a leakage current according to an embodiment of the present invention.
3 is a detailed circuit diagram of a leakage current detector employed in the lead-in line identification apparatus using leakage current according to an embodiment of the present invention.
4 is a view for explaining the principle of identification of a lead-in line identifying apparatus using a leakage current according to an embodiment of the present invention.
5 is a flowchart illustrating a method of identifying a lead-in line using a leakage current according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention. . First, in adding reference numerals to the constituents of the drawings, it is to be noted that the same constituents are denoted by the same reference symbols as possible even if they are displayed on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus and method for detecting a lead line using a leakage current according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The present invention is for identifying a multi-branched low-voltage incoming line in a three-phase four-wire type low-voltage power supply circuit, and can identify a lead-in line using normal supply power and without applying external current or high frequency signal.

Generally, the identification signal for identifying the line is advantageous in that it can be tested without applying a signal affecting the external power line by using the electrical component of ㎐ which is supplied from the electric supplier and the commercial power There is an advantage of being able to test as much as the supplied distance.

In addition, since the current passing through the normal wire and the neutral wire is uniformly generated in the normal low-voltage line, the differential current due to the load current is not detected in the leakage current detection using the ZCT (Zero Current Transformer).

Also, single-phase power supply uses two wires to supply power and loops through it, so the current of the supplied power flows in opposite directions from the wire. Therefore, when two currents are detected side by side and the current is detected by the video current transformer, the magnitude of the current is canceled out to be "0" A.

Therefore, according to the present invention, a resistance element or a condenser is provided in a corresponding line to artificially generate a leakage current in a ground line and a ground line. In the power line of the line, a differential current The leakage current is detected only in the corresponding lead-in line which is generated and desired to be identified, so that it is possible to distinguish the correct lead-in line to be identified. At this time, there is no leakage current in the line other than the line through which the artificial leakage current flows, and even if a normal leakage current flows, it is easy to identify because it is a current different from the leakage current generated in the present invention.

That is, the present invention generates an identifiable leakage current, not a normally occurring leakage current, and uses it as an identification signal to identify a lead-in line to be identified.

FIG. 1 is a view showing a configuration of a lead-in line identifying apparatus using a leakage current according to the present invention, FIG. 2 is a view showing a detailed configuration of a leakage current generating unit employed in a lead-in line identifying apparatus using a leakage current according to the present invention, 3 is a detailed configuration of a leakage current detecting unit employed in the lead-in line identifying apparatus using the leakage current according to the present invention.

1, the lead line identifying apparatus 100 using leakage current according to the present invention mainly includes a leakage current generating unit 110, a leakage current circuit unit 120, and a leakage current detecting unit 130.

The leakage current generating unit 110 is provided on a lead line to be identified to generate a leakage current. In the leakage current generating part 110, a resistor (or a condenser) and an intermittent circuit are connected to generate a leakage current, and the operation thereof can be controlled by a control part to be described later. Here, the leakage current does not flow through a normal load circuit (closed circuit) but refers to a current flowing through an arbitrary single phase and a ground.

The leakage current generating unit 110 separately generates a leakage current component. That is, the leakage current generating unit 110 divides the leakage current into a capacitive (Igc) leakage current or a resistance (Igr) leakage current. For the leakage current component classification, the power factor is always generated by the phase difference of the voltage and the current for the power source having the phase change and the frequency, and the leakage current component can be distinguished by applying this power factor to the leakage current in the same manner.

The leakage current generating unit 110 includes a coder 111, a size setting unit 113, and a controller 115 as shown in FIG.

The encoding unit 111 can divide the leakage current into coded signals based on the components of the leakage currents at short or long time intervals. At this time, the encoding unit 111 may convert the leakage current by using various methods other than the encoding method of converting the leakage current into a coded signal by a short or a time difference. In addition, the encoding unit 111 assigns a unique code number to the coded signal so that the process of the display unit 135 can be automatically identified and displayed on the screen.

The size setting unit 113 sets the magnitude of the leakage current to a magnitude (approximately 50 to 200 mA or so) that can be compared with the magnitude of the normally existing leakage current. That is, the size setting unit 113 sets the magnitude of the leakage current to a size that the leakage current detection unit 130 can sufficiently identify.

The leakage current generated in the leakage current generating unit 110 is difficult to distinguish due to a large load current in a conventional identification scheme that supplies current from the outside regardless of the magnitude of the load current that normally flows, It is not necessary to separately amplify the signal due to the loss of the signal according to the distance between the signal and the signal.

The control unit 115 controls the operation or stop of the leakage current generation unit 110 to control the leakage current generation. That is, the control unit 115 can operate the leakage current generating unit 110 to ground the resistor, stop the resistor, and isolate the resistor from the ground to operate or stop the generation of the leakage current. At this time, the control unit 115 may be operated by a remote control device such as a remote controller or manually to control the generation of a leakage current. Accordingly, when the worker 1 performs the lead line identification service, the control unit 115 allows the worker 2 to perform manual work so that the worker can perform work using the remote control device, thereby controlling the generation of the leakage current .

The leakage current circuit part 120 is a circuit for flowing a leakage current generated in the leakage current generating part 110 and is provided in parallel to the ground of the lead-in line to be identified.

The leakage current circuit section 120 may be configured in the form of a resistive circuit in which a resistive (Igr) leakage current flows, consisting of a capacitive circuit or resistive element through which a capacitive (Igc) leakage current flows from the lead line to the ground depending on the component of the leakage current .

The leakage current detector 130 detects a leakage current generated from the leakage current generator 110 and returns to the ground. The leakage current detector 130 detects a leakage current coded at the branch entry point, identifies the entry line to be identified therewith, and determines that the entry line is for identifying the entry line. At this time, the leakage current detector 130 is provided in the form of a portable detection device so that the leakage current can be detected in a non-contact manner.

The leakage current detector 130 includes an analyzer 131, an identification unit 133, and a display unit 135 as shown in FIG.

The analyzer 131 analyzes the coded signal of the detected leakage current. That is, the coded signal is analyzed to determine whether the component of the detected leakage current is a capacitive (Igc) leak current or a resistive (Igr) leakage current.

The identification unit 133 identifies the configuration and components of the lead-in line to be identified through the components of the analyzed leakage current.

The display unit 135 displays a code number (for example, 1, 2, 3 or A, B, C) given to the coded signal of the leakage current so that the workers in the field can easily distinguish the detected leakage current, And displays the configuration and components of the lead line identified by the section 133 on the display screen. At this time, the leakage current detection unit 130 automatically identifies the code number given to the coded signal of the leakage current by a separate processor, for example, # 1, # 2, # 3. #A, #B, #C ... and so on.

4 is a view for explaining the principle of identification of a lead-in line identifying apparatus using a leakage current according to the present invention.

As shown in FIG. 4, a leakage current generating unit 110 is provided in a corresponding A phase (# 1) to be identified and is operated to control the generation of a leakage current.

More specifically, the current I1 (A phase) + Igr (resistive leakage current) flows in the A phase (A∮: LOAD # 1) of the branch entry point and the current flows through the N phase A normal current flows. At this time, a leakage current generating portion 110 and a leakage current circuit portion 120 are formed between the A phase and the ground to generate a leakage current, and the generated leakage current (resistive or capacitive leakage current) Here, the normal I1 current is only the current flowing through the N phase (neutral line), and the leakage current flows from the lead line to the ground and is detected by the leakage current detector 130. The flow of leakage current is indicated by an arrow in the figure.

In the detection of leakage current, a CT (Current Transformer) that detects the current is used to detect the current in different directions by simultaneously passing the lead line to be identified and the N phase (neutral line) through the CT. At this time, the difference current of the two lines is detected, and the current thus detected is the leakage current.

In other words, when the ZCT (Zero Current Transformer) clamp detects the lead-in line and the N-line to be detected at the lead-in point, only leakage current (resistive or capacitive leakage current) is detected.

Therefore, at the branch entry point, the current to be identified is I1 (A phase) + resistive leakage current Igr + capacitive leakage current Igc-I1 (N phase) = resistive leakage current + capacitive leakage current Igr + Igc ).

As described above, since the leakage current Igr + Igc is detected only at the # 1 lead line at the branch entry point, it is possible to identify the lead line in which the leakage current is detected and accurately identify the lead line to be identified. At this time, if only the condenser is actually connected in the field, only the capacitive leakage current will remain, and if the circuit of the earth is constituted by the resistor alone, only the resistive leakage current will remain.

5 is a flowchart illustrating a method of identifying a lead line using a leakage current according to the present invention.

Referring to FIG. 5, a method of identifying a lead-in line based on the lead-in line identifying apparatus 100 using the leakage current described above will be described below.

First, a leakage current generating unit 110 is provided in a lead line to be identified. (S100) At this time, the leakage current generating unit 110 divides the leakage current component into a capacitive leakage current lgc and a resistance (lgr) leakage current. The leakage current generating unit 110 converts the leakage current into a coded signal based on the leakage current according to the leakage current component by the coder 111 and sets the size of the leakage current by the size setting unit 113 And its operation can be controlled by the control unit 135. [

Next, the leakage current circuit portion 120 is provided in parallel to the ground of the lead-in line to flow a leakage current. At this time, the leakage current circuit unit 120 is configured in the form of a resistive circuit in which a resistive (Igr) leakage current flows, consisting of a capacitive circuit or resistive element through which a capacitive (Igc) leakage current flows from the lead line to the ground depending on the component of the leakage current .

Then, the leakage current detection unit 130 detects the leakage current to the ground of the lead-in line at the branch lead-in point, identifies the lead-in line in which the detected leakage current exists, and determines that the lead- S200, and S300) In this step, the component of the leakage current detected by the analysis unit 131 is analyzed, and the configuration and the component of the lead line to be identified through the component of the leakage current analyzed by the identification unit 133 are identified, A code number assigned to the coded signal of the leakage current detected by the detection unit 135 and a configuration and a component of the identified lead line on the display screen.

As described above, according to the present invention, there is provided an apparatus and method for identifying a lead-in line using leakage current, which further comprises a circuit through which a leak current generated by a human being is artificially generated, thereby detecting a leakage current to the earth, It is possible to accurately identify the configuration and components of the lead line.

In addition, the present invention converts the leakage current into a coded signal by a short or long time difference in identifying the components and configuration of the incoming lead through the components and configuration of the detected leakage current, And convenience and operability can be remarkably improved.

In addition, the present invention integrates the functions of the conventional load current detection device so as to simultaneously test for leakage and lead-in line identification, thereby reducing the waste of components and manufacturing costs that can occur when the detection devices are separately manufactured .

In addition, the present invention enables remote control of an operator, not only can the effect of manpower allocation due to manpower saving be expected, but also efficiency and speed of work can be maximized.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art without departing from the scope of the appended claims. As will be understood by those skilled in the art.

100: Lead wire identification device 110: Leakage current generator
120: Leakage current circuit part 130: Leakage current detection part

Claims (10)

A leakage current generating unit provided in a lead line to be identified to generate a leakage current by dividing a component;
A leakage current circuit part provided in parallel to the ground of the lead-in line to flow the leakage current; And
And a leakage current detector for detecting the leakage current from the branch lead-in point to the ground of the lead-in line and determining that the lead-in line exists for identifying the lead-in line in which the detected leakage current exists,
The leakage current generating unit includes:
A coder which converts a leakage current into a coded signal by a short or a time difference according to a component;
A size setting unit for setting a magnitude of a leakage current; And
A control unit for controlling the leakage current generating unit to operate or stop;
Wherein the lead-in line identification device includes: The method according to claim 1,
Wherein the leakage current generating unit generates a leakage current component by dividing the leakage current into one of a capacitive leakage current (lgc) and a resistance (lgr) leakage current. delete The method according to claim 1,
Wherein the leakage current circuit portion is configured in the form of a capacitive circuit through which a capacitive leakage current (lgc) flows or a resistive circuit through which a resistive leakage current (lgr) flows. The method according to claim 1,
The leakage current detector may include:
An analysis unit for analyzing a coded signal of the detected leakage current;
An identification unit for identifying the configuration and components of the lead-in line to be identified through the coded signal of the analyzed leakage current; And
A display unit for displaying on the display screen a code number corresponding to a coded signal of the detected leak current and a configuration and components of the lead line identified;
Wherein the lead-in line identification device includes: Generating a leakage current by dividing a component by a leakage current generating unit included in a lead line to be identified;
Flowing the leakage current by a leakage current circuit unit provided in parallel to the ground of the lead-in wire;
Detecting the leakage current from the branch lead-in point to the ground of the lead line by the leakage current detecting section; And
And a step of identifying the lead-in line in which the detected leakage current exists by the leakage current detecting unit and determining that the lead-in line is to be identified,
The step of generating a leakage current includes:
The coded part converts the leakage current into a coded signal by a short or a time difference according to the component, sets the magnitude of the leakage current by the magnitude setting part, and controls the operation or the stop of the leakage current generation part by the control part A method for identifying a lead line using a leakage current. The method according to claim 6,
In the step of generating leakage current,
Wherein the leakage current generating unit generates a leakage current component by dividing the leakage current into one of a capacitive leakage current (lgc) and a resistance (lgr) leakage current. delete The method according to claim 6,
In the step of flowing leakage current,
Wherein the leakage current circuit portion is configured in the form of a capacitive circuit through which a capacitive leakage current (lgc) flows or a resistive circuit through which a resistive leakage current (lgr) flows. The method according to claim 6,
Wherein the step of identifying a lead line in which a leakage current exists and determining that the lead line is a lead line for identifying the lead line,
Analyzing a coded signal of the leakage current detected by the analysis unit;
Identifying a configuration and a component of the lead line to be identified through the coded signal of the leakage current analyzed by the identification unit; And
Displaying the code number of the coded signal of the leakage current detected by the display unit and the configuration and components of the lead line identified on the display screen;
Wherein the leakage current is detected by the leakage current detection means.

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