KR102343931B1 - Active underground power cable line tester and testing method - Google Patents

Abstract

The embodiment of the present invention relates to a device and method for exploring underground power cable live lines. Provided are a device and method for exploring underground power cable live lines, wherein the device includes: a reference point detection unit for detecting current magnitude, phase, and specific noise of a cable in a reference point switch; a pulse wave generator generating and injecting a pulse wave into the cable in the reference point switch; a reference point control unit which receives result signals of the reference point detection unit and the pulse wave generator and transmits results; a detection point measuring unit which measures the current magnitude, phase and specific noise of a detection point cable, and a pulse wave; and an exploration control unit for determining whether or not the cable is connected by comparing a measurement result of the detection point measuring unit with the result signals transmitted by the reference point control unit. According to the present invention, it is possible to quickly and accurately identify a connection cable line through the magnitude of the current, a phase angle, and the noise.

Description

Apparatus and method for detecting underground power cable live lines

The present invention relates to an apparatus and method for detecting a live line of an underground power cable, and to an apparatus and method for detecting a live line of an underground power cable that can safely find a power cable connected in a live state in terms of diagnosis or other maintenance of a power cable.

Diagnose the condition of cables in manholes, power spheres, trays, etc. where underground power cables are installed, such as KEPCO's distribution system or large-scale factories that receive special high voltage, or cut and branch cables for new power demand. In order to cope with this, the correct line name and phase division must be marked on the cable connection material, etc.

However, it is difficult in terms of maintenance due to the absence or non-attaching of the name of the track or the name of the track due to neglect during construction or for a long period of time.

In order to overcome this difficulty, there are foreign-made equipment that can perform exploration work only in the state of a dead line, but there is a disadvantage that it cannot be used in a load where power failure is difficult. In addition, although the method of exploring the track in a live state using an underground facility exploration device has been conducted, the accuracy is very low, and there is a problem that safety accidents occur frequently, such as cutting a live cable.

(Patent Document 1) Korean Patent Publication No. 10-1559533 (Patent Document 2) Korean Patent Publication No. 10-0319485

The present invention has been devised to solve the above problems, and in the power cable being transmitted, the change in electrical characteristics according to the load change for each line is constantly changed, and by using this change, the cable line connected in the live state can be searched out. It relates to an apparatus and method for detecting an underground power cable live line.

A reference point detector for detecting the current magnitude, phase, and specific noise of the cable in the reference point switch according to the present invention, a pulse wave generator for generating and injecting a pulse wave into the cable in the reference point switch, and the reference point detector and the pulse wave generator A reference point control unit that receives a result signal and transmits the result, a detection point measurement unit that measures the current magnitude, phase, specific noise, and pulse wave of the detection point cable, and the measurement result and the reference point control unit of the detection point measurement unit It provides an underground power cable live line exploration device including a search control unit for determining whether a cable is connected or not by comparing the obtained signal.

The reference point control unit includes a detection input unit receiving the detection result of the reference point detection unit, a pulse wave control unit controlling the pulse wave generator, a reference point converting unit converting the result of the detection input unit into a current magnitude, a phase, and a specific noise value; It characterized in that it further comprises a reference point communication unit for transmitting the result, and a reference point screen display unit for displaying the converted detection result.

The reference point communication unit transmits a result signal through wireless communication, but includes the current magnitude, phase, and specific noise information converted by the reference point conversion unit, and also includes pulse information generated by the pulse wave generator, the transmission/reception time difference characteristics that can be considered.

The exploration control unit includes a measurement input unit receiving the measurement result of the detection point measurement unit, a detection point conversion unit converting the measurement result, a detection point communication unit communicating with the reference point control unit, and a result signal by the converted measurement result and the reference point control unit It is characterized in that it comprises a result determining unit for determining whether or not the comparison, and a display unit for displaying the result signal of the reference point control unit and the measurement result of the detection point measuring unit on the screen.

The result determination unit analyzes the 3-phase result provided from the reference point control unit in the form of a waveform, and analyzes the detection result provided from the detection point measurement unit in the form of a 1-phase waveform, and determines that the same line is the same within the error range. and, if not, it is characterized in that it is determined as another line.

In addition, in the live line exploration method using the underground power cable live line exploration apparatus according to the present invention, the step of measuring the current for each phase of the reference point switchgear cable using the reference point detection unit, and one cable in the detection point area sequentially to each load In order to select a cable similar to the detection of the reference point area by measuring the current and to improve the accuracy of the measurement, measure the load current of the three-phase cable to determine whether the result value of the three-phase cable in the reference point area matches the result value, In this case, it provides an underground power cable live line exploration device method comprising the step of determining that the corresponding line is connected.

Waveforms are compared after temporarily stopping the waveforms that change on the screen for detection, and the comparison is characterized by current phase, current magnitude, specific noise, and square wave.

As described above, according to the present invention, in the power cable being transmitted, the change in electrical characteristics according to the load change is constantly changed for each line, and the cable connected in the live state can be searched out by using this change.

In addition, according to the present invention, it may be possible to quickly and accurately identify a connection cable line through the magnitude of the current, the phase angle, and the noise.

1 is a conceptual block diagram for explaining an underground power cable live line exploration apparatus according to an embodiment of the present invention.
Figure 2 is a conceptual diagram for explaining the entire system of the underground power cable live line exploration apparatus according to an embodiment.
3 is a block diagram of a reference point control unit according to an exemplary embodiment.
4 is a block diagram of an exploration control unit according to an exemplary embodiment.
5 is an output waveform of a reference point region according to an exemplary embodiment.
6 is an output waveform of a detection point area according to an exemplary embodiment.
7 to 9 are diagrams for explaining a method for detecting a live line of an underground power cable according to an embodiment of the present invention.
10 is a view for explaining oblique exploration according to an embodiment of the present invention.
11 is a conceptual diagram of a half moon CT according to an embodiment.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only these embodiments allow the disclosure of the present invention to be complete, and the scope of the invention to those of ordinary skill in the art completely It is provided to inform you. In the drawings, like reference numerals refer to like elements.

It is intended to clarify that the classification of the constituent parts in the present specification is merely a classification for each main function that each constituent unit is responsible for. That is, two or more components to be described below may be combined into one component, or one component may be divided into two or more for each more subdivided function. In addition, each of the constituent units to be described below may additionally perform some or all of the functions of other constituent units in addition to the main function it is responsible for. Of course, it can also be performed by being dedicated to it. Therefore, the existence or non-existence of each component described through the present specification should be interpreted functionally. For this reason, it is clearly stated that the configuration of the underground power cable live line exploration apparatus and method of the present invention may be different within the limit capable of achieving the object of the present invention.

In this specification, relational terms such as first and second, upper and lower, etc. are used to distinguish one entity or action from another without necessarily requiring or implying an actual relationship or order between those entities or actions. can only be used for The terms “comprises”, “comprising” or other variations thereof indicate that a process, method, product, or apparatus comprising a list of components does not contain only components, but such process, method, product, etc. It is intended to cover non-exclusive inclusions, which may include other components not expressly listed or implicit in the device. An element that proceeds to "comprises an one of" excludes, without further limitation, the presence of additional identical elements in a process, method, product, or apparatus that includes the element.

1 is a conceptual block diagram for explaining an underground power cable live line exploration apparatus according to an embodiment of the present invention.

2 is a conceptual diagram for explaining the entire system of the underground power cable live line exploration apparatus according to an embodiment. 3 is a block diagram of a reference point control unit according to an exemplary embodiment. 4 is a block diagram of an exploration control unit according to an exemplary embodiment. 5 is an output waveform of a reference point region according to an exemplary embodiment. 6 is an output waveform of a detection point area according to an exemplary embodiment.

1 to 6, the underground power cable live line exploration apparatus according to this embodiment includes a reference point detection unit 100 for detecting the current magnitude, phase, and specific noise of the cable in the reference point switchgear, and the cable in the reference point switchgear. A pulse wave generator 200 that generates and injects a pulse wave into the By comparing the measurement result of the detection point measurement unit 400 and the detection point measurement unit 400 and the result signal transmitted by the reference point control unit 300 for measuring the current magnitude, phase, specific noise, and pulse wave of the cable and an exploration control unit 500 that determines whether or not a connection is made.

Existing equipment uses the method to find the connection status of the line by disconnecting the elbow of the ground switchgear in the non-active state, connecting the equipment, disconnecting the elbow of the switchgear on the opposite side, and then short-circuiting 3 or 2 phases. There were many difficulties because the procedure was very complicated, took a lot of time, and a power outage was essential.

Recently, in order to find a line in a live state, a method of checking the connected cable by injecting a specific frequency into the conductor and shielding layer of the cable and detecting the line having the same frequency as the specific frequency in the detection point area to be found was used. However, in the case of a switchgear with multiple lines, since the cables are buried adjacently, a specific frequency applied to one cable is induced in other lines as well, resulting in a problem that the detection accuracy is remarkably reduced, and when the impedance of the surrounding lines is low In this case, the size of the signal was changed, causing a malfunction of recognizing the wrong cable as a connected cable.

However, in this embodiment, the current magnitude of the cable changes frequently according to the load change in the live wire state, the magnitude of the current is also different for each phase, and continuously changes with a constant phase angle, which can be equally applied to the connected line. . In addition, it is possible to search for a specific noise in the transmission line and to check the connected cable using this.

Accordingly, it is possible to detect the cable connected to the preceding reference cable in the detection point region far away by using the current magnitude, phase, and specific noise of the cable connected to the switchgear in the reference region. Of course, the underground power cable live line exploration apparatus of this embodiment has a diagonal mode, and it may be possible to search for a line even in a diagonal line.

It is effective that the reference point detection unit 100 includes at least one CT (Current Transformer) installed on a cable in the reference point switchgear. It is effective to install the CT on the switch elbow. CT sensor can be installed in all three phases.

Through this, the reference point detection unit 100 can detect the current magnitude, phase, and specific noise of the reference cable in the reference point area. As the reference point detection unit 100, it is effective to have a current capacity of up to 300A, and to have a class 1.0 waterproof type multiplier attached thereto. It is effective to have a minimum of 14mA and a minimum length of 10m for no-load use.

As the pulse wave generator 200 in this embodiment, it is effective to use a CT capable of generating a square pulse wave. Through this, the pulse wave generator 200 may generate a square pulse wave and apply the square wave pulse to the cable in the reference point switchgear. The pulse wave generator 200 is preferably configured as an output variable type. And, it is effective to set the variable output in consideration of the inflow of other circuits through the switchgear busbar. For example, it is preferable that it is A phase once, B phase 2 times, C phase 3 times.

The reference point control unit 300 includes a detection input unit 310 that receives the detection result of the reference point detection unit 100 , a pulse wave control unit 320 that controls the pulse wave generator 200 , and a result of the detection input unit 310 . It includes a reference point conversion unit 330 that converts the current magnitude, phase, and a specific noise value, and a reference point communication unit 340 that transmits the converted result. Of course, the reference point control unit 300 may further include a reference point screen display unit on which the converted detection result is displayed. Through this, the current magnitude, phase, and specific noise value of the reference point cable are displayed on the screen as waveform values and can be checked.

It is effective for the detection input unit 310 to receive the result of measuring the current for each phase. And, at this time, it is possible to adjust the CT magnification. It is effective that the detection input unit 310 is electrically connected to the reference point detection unit 100 by a separate signal line.

The pulse wave controller 320 may control the operation of the pulse wave generator 200 . Through this, it is possible for the pulse wave generator 200 installed on the upper portion of the shielding layer of the cable to inject the square wave pulse. It is effective that the range of the waveform current can be adjusted.

The reference point conversion unit 330 can digitize the analog input, and it is possible to implement it in the form of a waveform. The reference point conversion unit 330 may convert all three-phase signals and display them.

The reference point communication unit 340 transmits the result signal through wireless communication, but it is effective to include the current magnitude, phase, and specific noise information converted by the reference point conversion unit 330 . In addition, it is preferable to also include pulse information generated by the pulse wave generator 200 .

In this embodiment, it is possible to use various wireless communication methods as the reference point communication unit 340 . As an example, it may be possible to use a public wireless router data transmission/reception method such as 5G and LTE using CDMA. The reference point communication unit 340 may consider the transmission/reception time difference. To this end, a signal delay caused by a time delay can be eliminated by applying a trigger method on the receiving side using a technique that considers both sides of the tuning. In this case, it is preferable not to consider the time difference in the case of communication by the same base station. It is preferable to check whether there is a difference between the base stations with information in the received signal packet.

A signal is provided to a detection point far from the reference point through the reference point communication unit 340, and the connected line can be checked by finding a cable having the same signal pattern as this signal.

The detection point measurement unit 400 measures a current magnitude, a phase, and a specific noise of a cable located in the detection point area. It is preferable that the detection point measuring unit 400 measures the current magnitude, phase, and specific noise of one cable, that is, one phase. Of course, it is possible to measure all three phases. It is also possible to measure phase 1 first and then measure phase 3 later. This can increase the accuracy of searching all cables and improve the detection speed when there are many cables.

It is effective to use the same CT sensor as the reference point detection unit 100 in the present embodiment as the detection point measurement unit 400 . The detection point effectively refers to an underground area such as a manhole, and refers to an area far from the reference point area.

In addition, the detection point measuring unit 400 can also measure a pulse wave. In this case, it is effective to use a square wave as the pulse wave.

The exploration control unit 500 includes a measurement input unit 510 that receives the measurement result of the detection point measurement unit 400 , a detection point conversion unit 520 that converts the measurement result, and a detection point that communicates with the reference point control unit 300 . It includes a communication unit 530 and a result determination unit 540 that compares the converted measurement result with the result signal by the reference point control unit to determine whether or not there is a match. It is effective that the exploration control unit 500 further includes a display unit that displays the result signal of the reference point control unit 300 and the measurement result of the detection point measurement unit 400 on the screen.

The measurement input unit 510 receives the current magnitude, phase and specific noise, and the pulse wave provided from the detection point measurement unit 400 . At this time, it is possible to receive different values according to the number of cable lines connected to the detection point measuring unit 400, and when connected to one phase, it is possible to receive only this one value.

It is effective that the detection point conversion unit 520 converts the provided result into a digital form and converts the changed value into a waveform form.

The detection point communication unit 530 transmits a result signal through wireless communication, but preferably also includes the current magnitude, phase and specific noise information, and pulse information converted by the detection point conversion unit 520 .

In this embodiment, it is possible to use various wireless communication methods as the detection point communication unit 530 . As an example, it may be possible to use a public wireless router data transmission/reception method such as 5G and LTE using CDMA. The detection point communication unit 530 may consider the transmission/reception time difference. To this end, it is possible to solve the signal delay due to the time delay by applying a trigger method using a technique that considers the synchronization of both sides. In this case, it is preferable not to consider the time difference in the case of communication by the same base station. It is preferable to check whether there is a difference between the base stations with information in the received signal packet.

The result determination unit 540 analyzes the three-phase result provided from the reference point control unit 300 in the form of a waveform, and analyzes the detection result provided from the detection point measurement unit 400 in the form of a waveform. Through this, if the waveform is the same within the error range, it is determined as the same line, otherwise, it is determined as a different line.

Hereinafter, an underground power cable live line exploration method using the underground power cable live line exploration apparatus of the present invention will be described with reference to the drawings.

7 to 9 are diagrams for explaining a method for detecting a live line of an underground power cable according to an embodiment of the present invention.

As shown in FIG. 7 , the current for each phase of the reference point switchgear cable is measured using the reference point detection unit 100 . In this case, it is possible to adjust the CT magnification. To this end, it is effective to connect the reference point detector 100 and the pulse wave generator 200 to the elbow of the reference point switchgear. At this time, it is possible to adjust the waveform current range. Thereafter, the detected data and the provided waveform data are extracted and transmitted. Here, it is effective to adjust the square wave pulse output as needed, and it is effective to change it according to the sensitivity of the detection point area.

As shown in FIG. 8 , a cable similar to the detection of the reference point area is selected by sequentially measuring each load current of one cable in the detection point area. In this case, it is possible to adjust the CT magnification. It is effective to cross-compare the reference point current waveform and the target CT current waveform of the straight-line connector. For user's detailed detection, it is effective to compare the waveforms after temporarily stopping the changing waveforms on the screen. At this time, it is effective that the comparison is current phase, current magnitude, specific noise and square wave.

As shown in FIG. 9, to improve the accuracy of measurement, the load current of the three-phase cable is measured to determine whether the result value of the three-phase cable in the reference point area matches the result value, and if it matches, the corresponding line is connected judge to be

The present invention is also capable of oblique exploration using the above-described underground power cable live line exploration device.

10 is a view for explaining oblique exploration according to an embodiment of the present invention. 11 is a conceptual diagram of a half moon CT according to an embodiment.

As shown in FIGS. 10 and 11 , the DP of the switch elbow is disconnected for oblique inspection, and a square wave current signal is injected. This is because the DP of the elbow is separated because it is an oblique wire, not a live wire, and a signal can be injected into the inner conductor.

Then, disconnect the DP of the detection point area switch on the opposite side, and short-circuit the three phases.

When a square pulse is injected onto the conductors A and B of the switchgear in the reference point region, a signal that combines the pulse signals of phases A and B through the short circuit on the opposite side of phase C is transmitted. For this, it is possible to probe the phase line by detecting the square wave and period by using the receiving half-moon current open CT in the probe cable.

It is effective to use a half-moon type open CT to prevent the risk of having to lift another cable while live in order to install the CT on dozens of cables or connecting materials accommodated in the manhole.

It is effective that the half-moon-type off-CT includes a half-moon ring-shaped body and wires wound around the body.

Although the technical idea of the present invention described above has been specifically described in the preferred embodiment, it should be noted that the above-described embodiment is for the description and not the limitation. In addition, a person of ordinary skill in the art of the present invention will understand that various embodiments are possible within the scope of the technical spirit of the present invention.

100: reference point detection unit 200: pulse wave generator 300: reference point control unit
310: detection input unit 320: pulse wave control unit 330: reference point conversion unit
340: reference point communication unit 400: detection point measurement unit 500: exploration control unit
510: measurement input unit 520: detection point conversion unit 530: detection point communication unit
540: result judgment unit

Claims (7)

a reference point detection unit for detecting a current magnitude, a phase, and a specific noise of a cable in the reference point switch;
a pulse wave generator generating and injecting a pulse wave into the cable in the reference point switch;
a reference point control unit that receives the result signals of the reference point detection unit and the pulse wave generator and transmits the results;
a detection point measurement unit for measuring the current magnitude, phase, and specific noise of the detection point cable, and a pulse wave; and
Comprising a probe control unit for determining whether a cable is connected by comparing the measurement result of the detection point measurement unit and the result signal transmitted by the reference point control unit,
The reference point control unit includes a detection input unit receiving the detection result of the reference point detection unit, a pulse wave control unit controlling the pulse wave generator, a reference point converting unit converting the result of the detection input unit into a current magnitude, a phase, and a specific noise value; Further comprising a reference point communication unit for transmitting the result, and a reference point screen display unit for displaying the converted detection result,
The reference point communication unit transmits the result signal through wireless communication, but includes the current magnitude, phase, and specific noise information converted by the reference point conversion unit, and also includes pulse information generated by the pulse wave generator, the transmission/reception time difference An underground power cable live line exploration device, characterized in that it can be considered. delete delete The method of claim 1,
The exploration control unit includes a measurement input unit receiving the measurement result of the detection point measurement unit, a detection point conversion unit converting the measurement result, a detection point communication unit communicating with the reference point control unit, and the converted measurement result and the result signal by the reference point control unit. An underground power cable live line exploration device, comprising: a result determination unit to determine whether there is a match by comparison; and a display unit for displaying the result signal of the reference point control unit and the measurement result of the detection point measuring unit on a screen. 5. The method of claim 4,
The result determination unit analyzes the three-phase result provided from the reference point control unit in the form of a waveform, and analyzes the detection result provided from the detection point measuring unit in the form of a single-phase waveform, and if the waveform is the same within the error range, it is determined as the same line and, if not, underground power cable live line exploration device, characterized in that it is determined as another line. delete delete

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