KR102561858B1 - Switchboard self-diagnostic system capable of smart monitoring for partial discharge and normal operation of partial discharge sensor - Google Patents

Abstract

The present invention is a partial discharge sensor for detecting the internal partial discharge of the switchgear; a temperature sensor that senses the internal temperature of the switchgear in a plurality of zones; Sensor units composed of: thermal pigments configured in a plurality of zones to be discolored according to changes in the internal temperature of the switchgear, and each configured adjacent to the temperature sensors installed in the plurality of zones; photographing means for photographing the color of the thermal pigment; A control device that receives all of the partial discharge signal from the partial discharge sensor, the temperature signal from the temperature sensor, and the video signal from the photographing means to determine the partial discharge and temperature of the switchgear, and controls the operation of the switchgear according to the judgment result. ; and a remote control server that shares the partial discharge signal from the partial discharge sensor, the temperature signal from the temperature sensor, and the video signal from the photographing means with the control device, and remotely controls the operation of the switchgear according to the determination result. In the partial discharge, as the partial discharge occurs, the detected sound is converted into vibration and the vibration signal is transmitted to the control device, so that the partial discharge and the normal operation of the partial discharge sensor are determined. Disclosed is a switchgear self-diagnosis system capable of smart monitoring.

Description

Switchboard self-diagnosis system capable of smart monitoring for normal operation of partial discharge and partial discharge sensor

The present invention relates to a switchgear self-diagnosis system capable of smart monitoring for partial discharge and normal operation of a partial discharge sensor.

More specifically, the present invention is a sensor module that detects various problems that may occur inside the switchgear, such as partial discharge, a control device that processes detection signals by the sensor module, and a remote control server (manager's smartphone, etc.) are networked It is possible to constantly manage the internal state of switchgear by a control device or smart phone on site or in a remote place.

In addition, an acoustic vibration conversion sensor that detects the partial discharge of the switchgear and converts it into vibration, a temperature sensor that detects the temperature that can cause partial discharge and the deterioration of the insulator, which is the cause of the partial discharge, The arc and corona discharge of the switchgear are predicted in various ways by combining the detection signals by the thermal pigment, and the operation of the switchgear can be controlled through a smartphone, etc. accordingly.

In addition, by determining whether the partial discharge sensor is normally operating, control of the switchgear due to the partial discharge can be efficiently performed.

Group power consumers such as schools, buildings, apartment complexes, factories, etc. require a switchboard to receive extra-high voltage supplied from a substation and convert it to an appropriate low-voltage commercial voltage in order to obtain the power each needs.

This switchboard includes a high-voltage transformer that converts extra-high voltage to low voltage, an instrument current transformer, an automatic switch for faulty sections that switches high-voltage incoming lines, and a current-limiting high-voltage fuse within a single enclosure, which reduces the amount of power consumption on the consumer side. Accordingly, heat is generated in the high-voltage transformer, etc., and the temperature inside the enclosure rises.

Excessive rise of the internal temperature of the enclosure in the switchboard reduces the operation efficiency and accuracy of various parts and devices and can cause a fire. When it is determined that the temperature has been reached, the cooling fan is immediately operated to forcibly lower the internal temperature of the enclosure.

The temperature cooling operation inside the switchboard enclosure through forced ventilation has high heat dissipation efficiency, so it can solve the problem of power loss due to the high temperature coefficient of resistance of connection terminals or busbars of various devices and facilities in the device.

However, the heat dissipation operation of the switchboard through the forced ventilation causes the inflow of fine dust from the outside and also disperses the fine dust inside to relocate and fix it. As a result, the temperature coefficient of resistance of terminals or busbars of various facilities or devices in the switchboard is reduced. will increase

In addition, in power facilities, insulation deterioration occurs under the influence of mechanical stress, temperature, etc., resulting in local partial discharge in an internal insulation portion.

Partial discharge generally occurs when the breakdown voltage is reached due to insulation deterioration. The physical phenomena that appear are light, sound (sound signal), RF signal (electromagnetic signal), discharge leakage current (electrical red signal) is emitted.

This partial discharge signal is generated in the form of an impulse with a short pulse width, and the size of the signal is proportional to the amount of discharge and occurs when the discharge initiation voltage is exceeded in repeated AC cycles. It has a characteristic that appears repeatedly in the phase.

Even if there is no problem in the performance and operation of the system in the beginning, the partial discharge phenomenon has a problem in that the degree of insulation deterioration increases due to the electric tree and oxides generated during the partial discharge when it occurs for a continuous period of time.

In order to solve this problem, a technology for detecting partial discharge by analyzing the frequency of electromagnetic waves generated from partial discharge installed in an insulation device, a technology for detecting partial discharge with a pulse pattern of partial discharge using a current signal, and a number of A technology for detecting the position of partial discharge by using the arrival time difference of an acoustic emission signal and a partial discharge detection system of a switchboard equipped with an acoustic emission signal sensor have been proposed.

Korean Patent Registration No. 10-1489300 relates to an integrated switchgear for arc, partial discharge and temperature monitoring and a switchgear control method using the same, which includes a detection unit for detecting temperature, arc, and partial discharge inside the switchgear; and a leakage current detecting unit for detecting leakage current leaking from the switchgear circuit, a current converter for converting current when overcurrent flows in the switchgear, and an overcurrent for preventing the current induced from the current converter from damaging the circuit. An integrated interface unit including a protection unit; A controller that controls the switchgear when risk is determined based on whether the temperature detected by the detection unit and whether an arc has occurred and the leakage current detected by the integrated interface unit are mutually linked on the same interface to determine whether or not a reference value inside the switchgear has been exceeded. , Arc, Partial Discharge is integrated to protect the switchgear protection relay, check the precursor of an accident at the beginning of the accident, measure it with the integrated instrument and inform the manager of the change at the beginning of the accident to prevent an accident in the first place. making it possible

Republic of Korea Patent Registration No. 10-1823007 relates to an eco-friendly switchboard equipped with partial discharge, temperature diagnosis function, and IoT technology, and is installed in a box consisting of a front door and a rear door in a hexahedral shape and installed inside the box to provide internal devices. and a diagnosis device for detecting and diagnosing partial discharge and temperature of the cells, wherein the diagnosis device includes: a UHF sensor for detecting partial discharge and resonant frequency; a temperature sensor attached to the measurement part and outputting a resonant frequency according to a change in temperature; a repeater for receiving and transmitting the signal output from the UHF sensor; and a diagnostic device for diagnosing partial discharge and temperature based on the signal received from the repeater and transmitting the diagnosis result to an external device, using a molded UHF sensor to generate a part generated inside an enclosed space. Discharge can be detected, and the temperature can be detected in a wireless manner by being contact-type installed at the point where temperature monitoring is required.

Republic of Korea Patent Registration No. 10-1529818 relates to a diagnostic system for monitoring the state of a switchboard, which includes a plurality of sensors installed in a switchboard that detect two or more of different partial discharge signals, temperature signals, and arc signals generated in the switchboard. A sensor unit comprising; Collecting a plurality of measurement data for monitoring and diagnosing control of the state of the switchboard through signal processing by receiving two or more different ones of the partial discharge signal, the temperature signal, and the arc signal from a sensor unit including the plurality of sensors data collection device; and a remote monitoring device for receiving the plurality of measurement data from the data collection unit and monitoring and diagnosing the state of the switchboard, including internal and external elements of the switchboard (electrical, thermal, chemical stress and vibration, environmental factors ), insulation is destroyed due to deterioration or mechanical coherence is weakened, and accident signs that can eventually lead to accidents are detected early to prevent the spread of accidents in advance.

1. Republic of Korea Patent Registration No. 10-1489300 (2015. 01. 28. Registration, name: arc, partial discharge and temperature monitoring integrated switchboard and switchboard control method using it) 2. Republic of Korea Patent Registration No. 10-1823007 (2018. 01. 23. Registration, name: Eco-friendly switchboard equipped with partial discharge, temperature diagnosis function and IoT technology) 3. Republic of Korea Patent Registration No. 10-1529818 (2015. 06. 11. Registration, name: Diagnosis system for monitoring switchboard status)

An object of the present invention is to network various sensors for detecting problems inside switchgear, a control device for processing detection signals by the sensors, and a remote control server (manager's smartphone, etc.), so that the control device or smartphone can be used on-site or remotely. It is to provide a switchgear self-diagnosis system capable of smart monitoring for partial discharge, enabling constant management of the internal state of switchgear.

Another object of the present invention is to detect the partial discharge of the switchgear through an acoustic vibration conversion sensor, determine whether the switchgear is normal by using a temperature sensor that detects a temperature that can cause partial discharge, and a thermal pigment that is discolored according to the temperature. By making it easier to understand, it is based on determining whether the switchgear is normal by combining all the above three signals, but two or more signals are selectively used according to the state of sensor failure, etc. to determine whether the switchgear is normal or not. It is an object of the present invention to provide a switchgear self-diagnosis system capable of smart monitoring for partial discharge using a sensor module that can be used as a signal to identify.

Another object of the present invention is to provide a switchgear self-diagnosis system capable of smart monitoring of normal operation of a partial discharge sensor, which determines whether the partial discharge sensor is operating normally, so that control of the switchgear due to partial discharge can be efficiently performed. is in providing

Another object of the present invention is to implement the partial discharge sensor in various forms to prevent errors in judgment due to abnormality of the partial discharge sensor. to provide the system.

In addition, other objects of the present invention may be inferred according to the description below.

In order to achieve the above object, the switchgear self-diagnosis system capable of smart monitoring for normal operation of partial discharge and partial discharge sensors according to an embodiment of the present invention,

a partial discharge sensor that detects partial discharge inside the switchgear;

a temperature sensor that senses the internal temperature of the switchgear in a plurality of zones;

Sensor units composed of: thermal pigments configured in a plurality of zones to be discolored according to changes in the internal temperature of the switchgear, and each configured adjacent to the temperature sensors installed in the plurality of zones;

photographing means for photographing the color of the thermal pigment;

A control device that receives all of the partial discharge signal from the partial discharge sensor, the temperature signal from the temperature sensor, and the video signal from the photographing means to determine the partial discharge and temperature of the switchgear, and controls the operation of the switchgear according to the judgment result. ; and

A remote control server that shares the partial discharge signal from the partial discharge sensor, the temperature signal from the temperature sensor, and the image signal from the photographing means with the control device, and remotely controls the operation of the switchgear according to the judgment result. ,

The partial discharge is characterized in that sound sensed as the partial discharge occurs is converted into vibration, and the vibration signal is transmitted to a control device to determine whether the partial discharge occurs.

In the present invention, the sensor unit, the control device and the remote control server are wired and wirelessly networked, and the remote control server is a manager terminal.

In the present invention, the partial discharge sensor

a film for generating a mode attached to a portion other than the insulating portion and having a plurality of grooves formed at regular intervals to generate a desired ultrasonic mode;

a laser generator electrically connected to the acoustic vibration converter and irradiating the mode generation film with a laser beam to generate induction ultrasonic waves in the insulating part;

an acoustic emission sensor installed on the opposite side of the film for mode generation based on the insulating part to receive induction ultrasonic waves generated in the insulating part;

an acoustic emission measuring device electrically connected to the acoustic emission sensor and the acoustic vibration converter to measure the sound received by the acoustic emission sensor and to transmit the sound to the vibration sensor through the acoustic vibration converter; and

and an acoustic vibration converter for converting sound transmitted from the acoustic emission meter into vibration.

In the present invention, the vibration sensor for detecting the vibration signal

A cable composed of first, second and third conductors;

When the first conductor and the second conductor are connected to the differential amplifier, if the electromotive force generated by the movement of the two conductors is the same, the output of the differential amplifier becomes zero (0) because the waveform is the same or the signal strength is the same, so there is no deviation. , If the output of the differential amplifier is not zero (0) due to a predetermined deviation between the electromotive force generated in the two conductors, it is recognized as a partial discharge signal and processed.

The third conductor is connected to an operational amplifier so that electromotive force is generated in proportion to the moving strength;

It is characterized in that it consists of; a permanent magnet installed inside or outside the cable to generate electromotive force according to the movement of the cable.

In the present invention, the control device and the remote control server

Based on the video signal of the thermosensitive pigment, it is determined whether the thermosensitive pigment is damaged, and if it is normal, the partial discharge signal, the temperature signal, and the video signal of the thermosensitive pigment are all combined and reflected in the operation of determining whether the switchgear is normal or not,

If it is determined that there is damage to the thermal pigment by the video signal, the video signal is not reflected in determining whether the switchboard is normal or not, and only the partial discharge signal and the temperature signal from the partial discharge sensor and the temperature sensor are combined to determine whether the switchboard is normal or not. It is characterized in that it is reflected in the action.

In the present invention, the installation positions of the temperature sensor and the thermal pigment correspond to each other inside and outside the switchgear, and considering that the temperature sensor and the thermosensitive pigment are installed inside and outside the switchgear, respectively, the temperature sensor directly affected by the internal temperature of the switchgear It is characterized in that a judgment error that may occur due to a difference in configuration positions of the temperature sensor and the thermal pigment is prevented by matching the temperature sensed by the sensor and the color changed by the thermal pigment with a predetermined tolerance.

In the present invention, the thermosensitive pigment is formed of an irreversible material, so that even if the internal temperature of the switchgear is out of the normal temperature and recovered within a short time, the color is maintained so that the manager can inspect it.

In the present invention, the device for determining whether the partial discharge sensor is operating normally is

a control signal generator for generating a control signal generated from a signal generated by a sensor;

a control signal conversion unit that converts the control signal into a high level or a low level according to the control signal input from the control signal generation unit; and

It is characterized by consisting of; an LED light emitting unit that emits light in a predetermined color according to the signal input from the control signal conversion unit.

According to the switchgear self-diagnosis system capable of smart monitoring whether partial discharge and partial discharge sensors are normally operating, various sensors for detecting problems inside the switchgear, a control device for processing detection signals by the sensors, and a remote The control server (manager's smartphone, etc.) is networked, so it is possible to manage the internal state of switchgear at all times by a control device or smart phone on-site or remotely.

In addition, it is basic to determine whether the switchboard is normal or not by combining all three signals: a temperature sensor that detects partial discharge of the switchgear and detects the temperature that can cause partial discharge, and a temperature sensitive pigment that changes color depending on the temperature. However, if a sensor failure occurs, it is possible to determine the correct state of the switchgear by selectively using the remaining sensor signals to determine whether the switchgear is normal or not.

In addition, by determining whether the partial discharge sensor is normally operating, control of the switchgear due to the partial discharge can be efficiently performed.

In addition, by implementing the partial discharge sensor in various forms, it is possible to prevent errors in judgment due to abnormality of the partial discharge sensor.

Other effects will become apparent to those skilled in the art from the description below.

1 is a network configuration diagram of a switchgear self-diagnosis system capable of smart monitoring for normal operation of a partial discharge sensor according to an embodiment of the present invention.
2 is a configuration diagram for detecting partial discharge and temperature change according to an embodiment of the present invention.
3 is a network configuration diagram for detecting and determining a temperature by a temperature sensor and a thermosensitive pigment according to an embodiment of the present invention.
4 and 5 are heat dissipation control configuration diagrams according to an embodiment of the present invention.
6 is a control configuration diagram for determining whether a temperature sensor and/or a partial discharge sensor is out of order.
7 is a control configuration diagram for determining whether a partial discharge sensor is out of order according to another embodiment.
8 is a control configuration diagram of a self-diagnosis system according to another embodiment.
9 to 12 are sensor configurations for detecting that the sound sensed by the partial discharge sensor is converted into vibration.

The embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art, and the following examples may be modified in many different forms, and the scope of the present invention is as follows It is not limited to the examples. These embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the spirit of the invention to those skilled in the art.

Terms used in this specification are used to describe specific embodiments and are not intended to limit the present invention. As used herein, the singular form may include the plural form unless the context clearly indicates otherwise. Also, when used herein, the term “comprising” specifies the presence of the recited shapes, numbers, steps, operations, members, elements, and/or groups thereof, and one or more other shapes, numbers, operations, It does not exclude the presence or addition of members, elements and/or groups.

Most of the switchboards below 22.9kV installed in Korea use vacuum circuit breakers and are operated by contracting with a bus made of the same material.

Vacuum circuit breaker is an assembly composed of mechanical mechanisms, and after installation, deterioration occurs continuously. When deterioration of springs and wear of mechanisms occur, the pressure force of V.I (VACCUM INTERRUPTER) is weakened, resulting in heat generation and impossibility of complete insertion (half-insertion state). An ARC conduction state may occur due to

The vacuum circuit breaker in the switchboard and the busbar made of the same material are connected with fastening bolts and clips, and when the vacuum circuit breaker operates, an impact of about 450kgf X 3 (upper) occurs, which causes problems such as loosening of the bolts of the clip connection part and deformation of the contact part. occurs

In addition, a number of failures occur due to heat generation and malfunction due to loose fastening of the connection part and poor contact of the contact part clip.

In the interior of the switchgear (MCSG), the temperature measurement is inevitably partially made structurally, and it is practically difficult to monitor the temperature by measuring the temperature of a number of circuit breakers every day.

Therefore, in order to detect the risk of accidents early and maximize the efficiency of safe operation management, it would be desirable to configure a constant temperature monitoring system in the switchboard and connect it to a remote control server (DB SEVER) so that it can be monitored in the field and control room. .

In other words, the vacuum circuit breaker is a device that blocks normal current and fault current flowing in the system using a mechanical mechanism. Various insulators are used to secure insulation between the conductor panel enclosure and internal diaphragm, but many ground fault and short circuit accidents occur due to insulation damage caused by deterioration of insulation due to deterioration, corrosion, and intrusion of foreign substances into the enclosure. Insulation and partial discharge monitoring system in switchgear is essential.

However, circuit breakers and insulators installed inside switchboards cannot check the progress of insulation breakdown during operation, and it is impossible to measure insulation by taking out devices in a power outage state every day for many switchboards.

Therefore, in order to prevent ground faults and short circuit accidents due to insulation breakdown, it would be very desirable to configure a system that constantly checks the insulation state in the switchboard and connect it to a remote control server so that it can be monitored at the site and control center.

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

1 is a network configuration diagram of a switchgear self-diagnosis system capable of smart monitoring whether a partial discharge sensor is normally operating according to an embodiment of the present invention. 2 is a configuration diagram for detecting partial discharge and temperature change according to an embodiment of the present invention. 3 is a network configuration diagram for sensing and determining a temperature by a temperature sensor and a thermosensitive pigment according to an embodiment of the present invention. 4 and 5 are heat dissipation control configuration diagrams according to an embodiment of the present invention. 6 is a control configuration diagram for determining whether a temperature sensor and/or a partial discharge sensor is out of order.

As shown in FIGS. 1 and 2, the switchgear self-diagnosis system capable of smart monitoring whether the partial discharge and the partial discharge sensor are normally operating according to the present invention measures the partial discharge and the internal temperature of the switchgear 10 as a sensor unit ( 100) is detected by the partial discharge sensor 110, the temperature sensor 120, and the thermal pigment 130, and when the detection signal is processed by the control device 200, the switchgear 10 is processed according to the processed result. ) is normal, and as a subsequent operation, an operation to release heat from the switchgear 10 is performed.

The partial discharge signal and the temperature signal of the switchboard are shared by the control device 200 configured in the switchboard 10 and the remote control server 300 configured in a remote location.

The sensors, the control device 200, and the remote control server 300 are wired and wirelessly networked, and constant management of switchgear is possible anytime and anywhere by sharing data obtained by processing detection signals by the sensors.

The remote control server 300 may be replaced with an administrator terminal separately networked to the remote control server, for example, a smart phone.

The internal temperature of the switchboard detected by the temperature sensor 120 is obtained by dividing into a plurality of zones as described below, and the average temperature of these plurality of zones is provided as a temperature for performing a heat dissipation operation, and the inside of the switchboard The temperature sensed for each zone divided into a plurality of zones is provided as a temperature to determine whether each component or electrical connection part is normal or abnormal.

The divided zone may be composed of four zones as shown in FIG. 3, and it is determined whether or not the normal temperature is out of each of the divided zones. In addition, in addition to the temperature of each divided zone, the temperature of an adjacent zone may be linked to determine the final temperature of the zone.

Referring to FIG. 1 , considering that partial discharge may occur in busbars, CTs, PTs, cables, and VCBs, temperature sensors 120 may be installed individually or collectively in these areas.

In addition, the heat dissipation operation may be performed based on the average temperature of the four divided zones, but based on the average temperature finally obtained by reflecting predicted values that may rise due to the influence of the temperature of other zones for a certain period of time.

At this time, the heat generated in the switchgear is usually directed upwards. Considering this, the temperature detected in the divided zone located relatively above can be detected higher than the normal temperature, and the temperature in each zone is finally determined. and calculate the average temperature.

For example, if the uppermost part of the switchgear is set as zone 1, and the lower part is set as zone 2, 3, and 4 sequentially, the heat generated in zones 3 and 4 is particularly Since it often affects zone 2, even if the temperature detected in zone 1 and zone 2 is higher than the normal temperature, the allowable temperature value is set in advance and the temperature in the zone does not exceed the allowable temperature value. can be considered normal. That is, as the heat goes upward, the temperature in the area located above may instantaneously rise. For example, if it is determined that the temperature can be restored to the original temperature within a certain time, the temperature of the area is determined to be normal.

The thermal pigment 130 is a packaged thermal pigment capable of displaying various colors and can be accommodated in, for example, a thermal pigment storage unit formed in the central portion of the front panel of the switchgear, and the color changes according to the change in the internal temperature of the switchgear. By changing and appearing, the manager can recognize the internal temperature of the switchgear even if only checking the temperature sensitive pigment.

As another embodiment, when the color of the thermal pigment 130 changes, a camera 700 for photographing the color may be installed as a photographing means, and an image signal obtained by the camera 700 is transmitted to the controller 200. ) and the control server 300, the internal temperature of the switchgear can be determined by using the thermosensitive pigment alone or in conjunction with a temperature sensor.

As shown in FIG. 3 , the thermosensitive pigment 130 may be configured to have a different color according to the grades of low temperature, appropriate temperature, ambient temperature, and warning temperature. At this time, the low temperature, proper temperature, ambient temperature, and warning temperature may be set to correspond to the temperature detected by the temperature sensor 120 when the control device 200 analyzes the temperature.

Preferably, the temperature sensor 120 is installed inside the switchboard and is directly affected by the internal temperature, and the temperature sensitive pigment 130 is installed on the outer surface of the switchboard and is less affected by the internal temperature than the temperature sensor 120. In consideration of this, a temperature obtained by adding a predetermined temperature to a temperature corresponding to a color represented by the thermal pigment 130 and a temperature detected by the temperature sensor 120 may correspond to each other. The temperature to which the predetermined temperature is added may be set in various forms depending on the external environment.

As another embodiment, the thermal-sensitive pigment may be formed as at least one label covering a predetermined portion of the switchgear to determine the heat radiation condition, and in this case, the label is formed by including at least two kinds of thermal-sensitive pigments that change color at different temperatures It can be. In addition, a predetermined mark may be marked with ink or paint containing the thermal pigment, and the mark may include at least one of letters, figures, and numbers.

As another embodiment, it may be formed of at least one sticker containing an irreversible thermal-sensitive pigment whose color irreversibly changes with a temperature change, and may be adhered to a predetermined position on the outer surface of the switchgear in a predetermined size. Because a thermosensitive pigment that is irreversibly discolored is used, once the temperature rises and discolors, it does not return to its original color.

This is because when a reversible temperature sensitive pigment is used, when abnormal heat in the switchgear temporarily occurs, it is discolored and then returned to its original state, making it impossible to check whether or not there is an abnormality in the switchgear. That is, once the internal temperature of the switchgear is out of the normal temperature and does not recover in a short time, it is safe for the manager to take inspection measures due to the nature of the switchgear. If it appears, it is judged normal only with the visually recognizable thermal pigment, and it may be impossible to inspect the switchgear.

The thermal pigments 130 composed of the labels or stickers may be respectively formed in a plurality of areas on the outer surface of the switchgear. Preferably, each may be configured in an area close to the area where the temperature sensor 120 is installed.

In addition, the thermosensitive pigment may be configured to include at least two types of thermosensitive pigments to continuously change color at predetermined temperature intervals according to the temperature change of the switchgear. For example, if a temperature sensitive pigment that changes color from green to blue when the temperature of the switchgear rises to 30 to 40 ° C and a temperature sensitive pigment that changes color from blue to red when the temperature reaches 50 to 60 ° C are used together, the temperature of the switchgear increases to 30 ° C. When changing from 50 to 60 ° C. to 40 ° C., the color changes to blue and red. However, it is not limited only to these temperature values.

In addition, the thermosensitive pigment may be used alone or at least two types of thermosensitive pigments having different discoloration temperatures may be mixed. For example, if a thermosensitive pigment that changes from blue to colorless at 50 °C and a thermosensitive pigment that changes from red to colorless at 70 °C is combined, the mixed color of blue and red turns red at 50 °C and completely colorless at 70 °C. However, it is not limited only to these temperature values.

In addition, it may be formed by mixing a general pigment that is not affected by a change in temperature and a thermosensitive pigment. When a general pigment is mixed with a thermosensitive pigment that changes from blue to colorless at 50℃ or higher, it appears as a mixed color when the temperature does not rise above 50℃. However, it is not limited only to these temperature values.

The color of the irreversible thermosensitive pigment changes from one color to another color in a specific temperature range, for example, from colorless to a specific color, from a specific color to another specific color, or from a specific color to colorless. Such an irreversible thermosensitive pigment shows discoloration as the pigment is decomposed by heat, and inorganic or organic pigments may be used. As the inorganic zion pigment, inorganic metal oxides or hydrates of metal oxides, inorganic metal oxides or Mixtures of hydrates of metal oxides and the like can be used.

However, the type of irreversible thermal-sensitive pigment is not specified here, and various thermal-sensitive pigments irreversibly discolored at a predetermined temperature may be used.

The partial discharge sensor 110 is a light oil sensor that estimates a quantity to be measured using the intensity of light passing through an optical fiber, the refractive index and length of the optical fiber, the mode, and the change in polarization state, etc. The measured quantities include voltage and current. , temperature, pressure, strain, rotation rate, sound, gas concentration, etc.

In the present invention, a method using a sensor that converts sound detected as a partial discharge occurs into vibration is applied.

Referring to FIG. 1 , considering that partial discharge may occur in busbars, CTs, PTs, cables, and VCBs, partial discharge sensors 110 may be installed individually or collectively in these areas. At this time, the partial discharge sensor 110 may be installed on the outer surface of the switchboard in consideration of the acoustic wave sensing performance.

The control device 200 determines and displays the partial discharge and temperature (temperature based on the temperature sensor and the temperature sensitive pigment) of the switchgear and controls the Internet-based heat dissipation based on the internal temperature of the switchgear, and at the same time, By enabling remote control by the control server 300, the overall flow of returning the internal temperature of the switchgear to normal temperature is controlled.

The release of heat from the switchgear of the present invention is controlled by the control device 200 included in the switchgear 10 or remotely controlled by the control server 300.

The control device 200 controls the switchboard upper cover 600 to be opened for heat dissipation when the internal temperature (average temperature) of the switchboard is out of the normal temperature, and the control operation is performed by the solenoid driven by the solenoid driver 400 ( 500).

When the solenoid 500 is driven, the upper cover 600 of the switchgear is pushed up and the upper part of the switchgear is opened so that heat dissipation is possible. When the heat dissipation ends, that is, when the temperature returns to the normal temperature, the driving of the solenoid 500 also ends, and the upper cover 600 of the switchboard is returned to its original position.

In order to open or close the upper cover of the switchgear by the solenoid 500, a hinge may be formed on one side of the upper cover 600 and a configuration limiting the opening range may be provided on the other side. The configuration limiting the opening range may be configured by connecting a predetermined point of the upper cover 600 and the side plate of the switchboard. That is, when the solenoid 500 is driven, the upper cover 600 is opened while the hinge acts as a central axis of rotation of the upper cover 600, and is communicated with the outside to release heat.

When it is determined that the internal average temperature of the switchgear 10 configured as described above is out of the normal temperature, a heat dissipation operation is automatically performed.

The control server 300 processes the partial discharge and temperature values of the switchgear transmitted from the switchgear 10 and transmits a remote control signal to the control device 200 when it is determined that heat dissipation is necessary.

In the present invention configured as described above, when a partial discharge occurs as the internal temperature rises, the temperature sensor 120 detects the temperature and the color of the thermosensitive pigment changes. Therefore, the manager can directly recognize the color change of the thermal pigment to determine whether the internal temperature of the switchgear is normal or not, and take appropriate measures.

In addition, when the color change of the thermal pigment is photographed by the camera 700, the photographed image signal is processed by the control device 200 to determine whether the temperature of the switchboard is normal or not, and according to the determination result, the solenoid driving unit 400 ) to drive the solenoid 500 so that the heat inside the switchgear is released to the outside and returned to normal temperature.

At the same time, the control device 200 transmits the temperature value of the switchgear obtained by processing the temperature signal to the control server 300 so that the remote manager can also share it.

The present invention determines whether a switchgear is normal by combining a partial discharge signal, a temperature signal, and a changing color signal of a thermal pigment, or selectively combining them according to a sensor state, and can be implemented in various forms as follows. there is.

First, the partial discharge signal from the partial discharge sensor 110, the temperature signal from the temperature sensor 120, and the image signal obtained by photographing the thermosensitive pigment 130 are combined to determine whether the operation is normal as follows. It can be done.

The partial discharge signal detected by the partial discharge sensor 110, the temperature signal detected by the temperature sensor 120, and the image signal of the color changed by the thermal pigment 130 captured by the camera are all controlled by the device ( 200) is entered.

The control device 200 processes all of the partial discharge signal, temperature signal, and video signal to determine whether all three are within the normal range, all three are within the abnormal range, or whether one or both are within the normal or abnormal range, respectively. do. Here, the temperature signal is an average temperature detected in four divided areas.

As a result of the determination, when all three are within the normal range, the current operating state of the switchgear is maintained, and when all three are within the abnormal range, a control operation is performed to stop the current operating state of the switchgear.

On the other hand, if any one is within the abnormal range, the current operating state of the switchgear is controlled differently depending on whether the temperature value or the partial discharge value is within the abnormal range.

For example, it is determined which one has a larger change trend between the temperature value and the partial discharge signal value. In other words, it is to compare the internal temperature change trend and the partial discharge change trend of the switchgear. All of these change trends are based on the same time.

As a result, if the internal temperature of the switchgear is abnormal, but the change trend is slower than the partial discharge change trend or the range of change is not high, a predetermined time is waited. Thereafter, when the partial discharge value is included within the abnormal range during the waiting time, the current operating state of the switchgear is stopped.

However, if the partial discharge value does not change during the waiting time or the range of change is smaller than the set value, but the internal temperature maintains the abnormal range, the internal heat of the switchgear is released or the operation is stopped.

In addition, the present invention determines whether the thermosensitive pigment 130 is damaged based on an image signal of the camera 700 that captures the thermosensitive pigment 130, and determines whether the thermosensitive pigment 130 is damaged or not, and the result of the determination is used to determine the partial discharge signal, the temperature signal, and the thermal pigment. Video signals can be combined and reflected in the operation of determining whether the switchgear is abnormal. The damage includes all causes that interfere with determining the temperature using the thermal pigment, such as separation from the switchgear and scratches.

In this case, the video signal of the camera 700 is provided to the control device 200 as a signal capable of determining the color and damage of the pigment, respectively. Therefore, the control device 200 determines whether the temperature value according to the color and the temperature value by the temperature sensor 120 match, and if they match, it can be determined that there is no damage.

On the other hand, if the temperature value according to the color and the temperature value by the temperature sensor 120 do not match, it is determined whether or not the thermal pigment 130 is damaged. When it is determined that the thermosensitive pigment 130 is damaged, it is excluded from the combination signal.

The temperature values are the average temperature value of the temperature values sensed by the four thermal pigments 130 and the four temperature sensors 120 in consideration of the fact that a plurality of thermal pigments 130 are configured to correspond to the temperature sensors 120. ) determines the average temperature value of the temperature values sensed by corresponding to each other.

If one or more thermal pigments 130 are damaged, the average temperature value of the temperature values detected by the thermal pigments 130 and the average temperature value of the temperature values detected by the four temperature sensors 120 do not match each other. won't Therefore, the average temperature value by the thermosensitive pigment 130 is excluded from the combination signal.

Determination of whether the temperature sensitive pigment 130 is normal is similarly applied to the temperature sensor 120, so that it is possible to determine whether the switchgear is normal or not similar to the above embodiment.

As shown in FIG. 6, the component for determining whether the partial discharge sensor and/or the temperature sensor is out of order includes a control signal generator 70 that generates a control signal generated from a signal generated by each sensor, and the control signal A control signal converting unit 80 that converts a high level or a low level according to a control signal input from the generating unit 40, and an LED emitting light of a predetermined color according to a signal input from the control signal converting unit 80 It may consist of a part (90). 8 shows a configuration for determining whether or not there is a failure based on signals input from three sensors.

When the input of the control signal 1 input from the control signal generator 70 that receives the signal input from any one sensor is on (when there is a signal from the sensor), the control signal passed through the first control signal conversion unit 81 becomes a low signal, and in the LED set 91, the LED connected to the control signal conversion unit 81 is turned off, and the LED not connected to the control signal conversion unit 81 does not go through the first control signal conversion unit 81 Since it receives a direct signal from the control signal generator 70, it emits light in a predetermined color.

On the other hand, when the input of the control signal 1 is OFF (when there is no signal from the sensor), the control signal passing through the first control signal conversion unit 81 becomes a high signal, and the LED connected to the first control signal conversion unit 81 The LED of the set 91 is turned on, and the LED not connected to the first control signal conversion unit 81 directly inputs an off signal from the control signal generation unit 70 without going through the first control signal conversion unit 80. It is turned off because it is received.

In addition, when the input of the control signal 2 input from the control signal generating unit 70 receiving the signal input from the other sensor is ON (when there is a signal from the temperature sensor), the second control signal conversion unit 82 passes through The control signal becomes a low signal, and the LED connected to the second control signal conversion unit 82 in the LED set 92 is turned off, and the LED not connected to the second control signal conversion unit 82 is the second control signal conversion unit Since it receives a signal directly from the control signal generator 70 without going through 82, it emits light.

On the other hand, when the input of the control signal 2 is OFF (when there is no signal from the sensor), the control signal passing through the second control signal conversion unit 82 becomes a high signal, and the second control signal conversion unit in the LED set 92 The LED connected to 82 is turned on, and the LED not connected to the second control signal conversion unit 82 directly inputs an off signal from the control signal generation unit 70 without going through the second control signal conversion unit 82. It is turned off because it is received.

In addition, when the input of the control signal 3 input from the control signal generating unit 70 receiving the signal input from another sensor is on (when there is a signal from the temperature sensor), the third control signal conversion unit 83 passes through The control signal becomes a low signal, and the LED connected to the third control signal conversion unit 83 in the LED set 93 is turned off, and the LED not connected to the third control signal conversion unit 83 is the third control signal conversion unit Since it receives a signal directly from the control signal generator 70 without going through 83, it emits light.

On the other hand, when the input of the control signal 3 is OFF (when there is no signal from the sensor), the control signal passing through the third control signal conversion unit 83 becomes a high signal, and the third control signal conversion unit in the LED set 93 The LED connected to (83) is turned on, and the LED not connected to the third control signal conversion unit 83 directly inputs an off signal from the control signal generation unit 70 without going through the third control signal conversion unit 83. It is turned off because it is received.

In this way, the present invention constitutes a green LED and a red LED, respectively, and the control signal conversion unit 80 receives the signal generated from the control signal generation unit 70, but the green LED does not go through the control signal conversion unit 80. The red LED receives the signal converted through the control signal conversion unit 80 so that one LED always emits light, so that the state of a plurality of sensors can be accurately recognized at the same time.

That is, when a low signal is input, a red LED is turned on to recognize that the sensor is abnormal, and when a high signal is input, a green LED is turned on to recognize that the sensor is normal.

That is, when an off signal, that is, an abnormal signal of the sensor is generated in the control signal generating unit 70, the off signal is converted into an on signal through the control signal conversion unit 80 and inputted to the LED set 91 so that the red LED emits light. do. Therefore, the control device 200 judges the abnormality of the temperature sensor by the red LED emission and inspects the sensor.

On the other hand, when the signal from the control signal generator 70, that is, the normal signal of the sensor is generated, the OFF signal converted through the control signal conversion unit 80 is supplied to the red LED so that it does not emit light, and the LED set 91 The on signal supplied directly to the green LED of , causes the green LED to emit light. Therefore, the control device 200 determines whether the sensor is normal by green LED light emission.

7 is a control configuration diagram for determining whether a partial discharge sensor is out of order according to another embodiment.

Referring to FIG. 7, the device for determining the normal operation of the partial discharge sensor includes a sensor unit 111, a communication unit 112, a filter unit 113, a digital signal processing unit 114, a pulse generator 115, and an attenuation unit 116. ), a detection unit 117 and a determination unit 118.

The sensor unit 111 functions to measure loss of a cable connecting the partial discharge sensor 110 shown in FIGS. 1 to 3 above.

When a signal is transmitted through the communication unit 112 and a signal fed back from the partial discharge sensor 110 is received, the loss value of the cable measured through the sensor unit 111 is also received to know the loss value of the cable. can

The communication unit 112 receives a type of partial discharge signal selected for transmission among a plurality of generated partial discharge signals. The type of this signal is at least one of a corona discharge signal and an insulation abnormal discharge signal, which is a signal that can be newly generated or a previously generated source can be reused.

The communication unit 112 also transmits the partial discharge pulse signal adjusted through the attenuation unit 116 to the partial discharge sensor 110 .

The digital signal processing unit 114 sets the attenuation level according to the type of system AC signal and partial discharge signal that may be generated in the power facility. Here, the attenuation level represents the degree of attenuation with respect to the strength of the signal.

This attenuation level may vary depending on the type of attenuation unit 116 . Assuming that the attenuation unit 116 can set a level of 256 or more levels, the attenuation level may be set to a level corresponding to a set value among 256 or more levels. In addition, the digital signal processing unit 114 may include a real time clock (RTC) chip (not shown), and receives time information from other equipment or the partial discharge sensor 110 through the communication unit 112 to synchronize the time. and can be used in history and data analysis.

The pulse generator 115 generates a partial discharge pulse signal, and a signal generator or pulse generator is generally used.

The attenuation unit 116 adjusts the level of the signal according to the attenuation level set by the digital signal processing unit 114. For example, the attenuation unit 1160 considers the signal level (dBm) measured in various detection equipment in the frequency range of 300 MHz to 2 GHz used in the partial discharge sensor 110 to simulate the size of 256 steps or more It is a signal control device. More specifically, if the attenuator 160 can control 256 levels in units of 0.1dBm for a basic 0dBm signal, it can attenuate up to 25.6dBm (256 * 0.1dBm), increasing the size from 0dBm to -25.6dBm. can be converted into a signal. Therefore, a partial discharge signal considering the system AC signal generated in the power system can be generated through this adjustment procedure.

The determination unit 118 transmits the partial discharge pulse signal, the size of which has been adjusted by the attenuation unit 116, to the partial discharge sensor 110 through the communication unit 112, and then receives feedback from the partial discharge sensor 110. The operation of the partial discharge sensor 110 is determined through the signal.

The signal fed back from the partial discharge sensor 110 has a phase resolved pulse sequence (PRPS) format in units of 1 second. That is, it is possible to determine whether the partial discharge sensor 110 is operating through comparison and analysis of the signal fed back from the partial discharge sensor 110 and the partial discharge pulse signal whose size is adjusted and transmitted through the communication unit 112. there is. The PRPS is a method of sequentially displaying partial discharge pulse data flowing in real time on a screen in three dimensions, that is, a method of synchronizing a measured signal with a power phase and analyzing it on a time axis.

In addition, when receiving the feedback signal, the determination unit 118 determines that there is a problem with the cable connecting the partial discharge analyzer and the partial discharge sensor 110 through the cable loss value measured from the sensor unit 111. can determine if there is In addition, the determination unit 118 transmits signals to the power equipment and the partial discharge sensor 110 through the communication unit 112, compares and analyzes signals fed back from the power equipment and the partial discharge sensor 110, and The reflection coefficient of (1110) can be inferred.

The filter unit 113 functions to remove noise from various types of system AC signals that may occur in power facilities.

The detection unit 117 detects an interruption state or malfunction of the partial discharge analyzer, and detects whether such an interruption or malfunction occurs. That is, the sensing unit 117 performs a monitoring function for monitoring the operating power supply and the interruption state of the device. While performing these functions, when a problem occurs in the partial discharge analyzer, the circuit may be protected by stopping the digital signal processor 114 that controls the pulse generator 115 and the attenuator 116.

8 is a control configuration diagram of a self-diagnosis system according to another embodiment, and FIGS. 9 to 12 are configuration diagrams of a vibration sensor that detects that sound sensed by a partial discharge sensor is converted into vibration.

As shown in FIG. 8 , the diagnostic system according to another embodiment includes a control device 200, a film for mode generation 7, a laser generator 110, an acoustic emission sensor 30, an acoustic emission measuring instrument 36, It may be configured to include an acoustic vibration converter 37 and a vibration sensor 38 .

The film 7 for mode generation is attached to a part other than the insulating part 5 of the power facility 1, for example, and a plurality of grooves 8 are formed at regular intervals. The mode generating film 7 functions to generate a desired ultrasonic mode.

The laser generator 110 is electrically connected to the acoustic vibration converter 37, and irradiates a laser beam on the mode generation film 7 to generate induction ultrasonic waves inside the power equipment.

The acoustic emission sensor 30 may be configured using a known acoustic emission sensor (AE sensor). The acoustic emission sensor 30 is installed on the opposite side of the mode generation film 7 with respect to the insulation part 5 of the power facility 1 to receive the induced ultrasonic waves generated in the power facility 1.

Meanwhile, since the ultrasonic signal received by the acoustic emission sensor 30 is very weak, an amplifier 35 may be configured between the acoustic emission sensor 30 and the acoustic emission meter 36.

The acoustic emission measuring device 36 is electrically connected to the acoustic emission sensor 30 and the acoustic vibration conversion device 37 to measure the sound received from the acoustic emission sensor 30, and the acoustic vibration conversion device 37 to measure the sound. through the vibration sensor 38.

The control device 200 is connected to the vibration sensor 38 and analyzes a signal transmitted through the acoustic vibration converter 37 to determine whether a partial discharge occurs.

More specifically, it is as follows.

The laser beam emitted from the laser generator 110 is irradiated to the film 7 for mode generation, and through the film 7 for mode generation, guided ultrasonic waves of a desired mode are generated in the busbar 1.

The generated induction ultrasonic wave is received by the acoustic emission sensor 30 through the insulation part 5 of the power facility 1. At this time, as shown in FIG. 8, if there is a defect 6 such as a groove in the insulating part 5, the speed, frequency, energy, etc. of the ultrasonic wave change due to this defect 6.

The ultrasonic waves received by the acoustic emission sensor 30 are amplified through the amplifier 35 and then input to the acoustic emission meter 36 .

The acoustic emission meter 36 measures the input signal, analyzes the speed and/or frequency, energy, etc. of the ultrasonic wave, and transmits it to the acoustic vibration converter 37.

Therefore, the vibration sensor 38 receives the signal output from the acoustic vibration conversion device 37 and generates a predetermined vibration according to the material and insulation of the power equipment 1 stored in the database in the control device 200. Defects are determined by comparing data such as propagation speed of laser-guided ultrasound and/or frequency component change, mode change, and energy change according to the material and insulation of the power facility 1.

The vibration sensor 38 is tightly connected to the acoustic vibration conversion device 37 with a cable, and its various forms are shown in FIGS. 9 to 12 .

As shown in FIGS. 9 to 12, the cable 20 is configured so that the conductor (wire) 24 has three strands 24a, 24b, and 24c, and the conductors 24a and 24b are differential. If the electromotive force generated by the movement of the two conductors in the state connected to the amplifier is the same, there is no deviation because the waveform is the same or the signal strength is the same, so the output of the differential amplifier becomes zero (0), and the electromotive force generated by the two conductors is If the output of the differential amplifier is not zero (0) due to a deviation, it is recognized as a partial discharge signal and processed.

In addition, the conductor 24c is connected to the operational amplifier so that electromotive force is generated in proportion to the strength of the conductor's movement.

In the drawing, reference numerals 22a, 22b, 22c, 101 and 102 denote coatings.

When the conductors and the amplifiers are connected in this way, the signals induced by the conductors 24a, 24b, and 24c are compared, and a zero signal is generated if they have the same magnitude, and as a result of comparing the two signals, if there is a difference, the difference A signal is input to the control device 200 to determine whether or not there is a partial discharge.

In addition, the operational amplifier generates electromotive force in proportion to the intensity of vibration and inputs the electromotive force to the control device 200 so that partial discharge is determined.

The control device 200 compares and analyzes the amplified signals of the differential amplifier and the operational amplifier to determine whether there is a partial discharge.

When a minute vibration occurs, the signal deviation of the differential amplifier connected to the two conductors occurs greatly, but the operational amplifier does not generate a partial discharge signal based on the signal when a weak vibration signal is input.

When strong vibration occurs, there is no signal deviation of the differential amplifier, but when the vibration signal introduced into the operational amplifier is large, a partial discharge signal is generated.

An operation of determining partial discharge through vibration will be described below.

When the cable sensor 20 is shaken, the permanent magnet 15 moves, so the magnetic field B changes and noise is induced in the cable wire, generating electromotive force and noise. The electromotive force value generated in this way is sensed by the sensor. In the structure shown in FIG. 9, three permanent magnets 15 (15a, 15b, 15c) are configured inside the cable 20, and in the structure shown in FIGS. 10 and 11, two permanent magnets 15 are outside the cable 20. Dogs 15a and 15b may be configured.

The electromotive force and noise are transmitted to the control device 200, analyzed, and compared with a previously stored database to determine whether the cable 20 has been shaken. That is, it is determined whether the vibration corresponds to the partial discharge signal.

As described above, the detailed description of the present invention has been described with respect to the preferred embodiments of the present invention, but this is the best embodiment of the present invention exemplarily described, but does not limit the present invention. In addition, it is of course possible for anyone having ordinary knowledge in the technical field to which the present invention belongs to various modifications and imitations without departing from the scope of the technical idea of the present invention.

Therefore, the scope of the present invention is not limited to the above-described embodiments, but may be implemented in various forms of embodiments within the scope of the appended claims. And without departing from the subject matter of the present invention claimed in the claims, anyone with ordinary knowledge in the art to which the invention pertains is considered to be within the scope of the claims of the present invention to various extents that can be modified.

An embodiment for implementing a switchboard self-diagnosis system capable of smart monitoring for partial discharge and normal operation of partial discharge sensors has been described. The embodiments described above are illustrative of some of the many specific embodiments that demonstrate the principles described herein. Therefore, by using the embodiments of the present invention, those skilled in the art will be able to easily implement many other arrangements within the scope defined by the claims of the present invention.

70: control signal generating unit 80: control signal conversion unit
90: LED set 100: sensor unit
110: partial discharge sensor 120: temperature sensor
130: thermosensitive pigment 200: control device
300: remote control server 400: solenoid driving unit
500: solenoid 600: upper cover of switchgear

Claims (8)

a partial discharge sensor that detects partial discharge inside the switchgear;
a temperature sensor that senses the internal temperature of the switchgear in a plurality of zones;
Sensor units composed of: thermal pigments configured in a plurality of zones to be discolored according to changes in the internal temperature of the switchgear, and each configured adjacent to the temperature sensors installed in the plurality of zones;
The partial discharge sensor
a sensor unit measuring loss of a cable connecting the partial discharge sensor;
a digital signal processing unit that sets an attenuation level according to the types of system alternating current signals and partial discharge signals that may occur in the switchgear;
a pulse generating unit generating a partial discharge pulse signal;
an attenuation unit that adjusts the level of the signal according to the attenuation level set by the digital signal processing unit;
After transmitting the partial discharge pulse signal whose size is adjusted in the attenuation unit to the partial discharge sensor through the communication unit, the determination unit determines whether the partial discharge sensor is operating or not through the signal fed back from the partial discharge sensor; Normal operation is determined by the discharge sensor normal operation determination device,
The thermal-sensitive pigment is an irreversible thermal-sensitive pigment whose color changes irreversibly with temperature change, considering that it is necessary for a manager to take inspection measures due to the nature of the switchgear when the internal temperature of the switchgear is out of normal temperature and is not recovered in a short time. It is formed of at least one sticker including a and configured on the outer surface of the switchboard adjacent to the area where the temperature sensor is installed;
photographing means for photographing the color of the thermal pigment;
A control device that receives all of the partial discharge signal from the partial discharge sensor, the temperature signal from the temperature sensor, and the video signal from the photographing means to determine the partial discharge and temperature of the switchgear, and controls the operation of the switchgear according to the judgment result. ; and
A remote control server that shares the partial discharge signal from the partial discharge sensor, the temperature signal from the temperature sensor, and the image signal from the photographing means with the control device, and remotely controls the operation of the switchgear according to the judgment result. ,
The control device and remote control server
Considering that the temperature sensor is installed inside the switchgear and is directly affected by the internal temperature, and the thermosensitive pigment is installed on the outer surface of the switchgear and is less affected by the internal temperature than the temperature sensor, the temperature value according to the color of the thermosensitive pigment The temperature value obtained by adding the predetermined temperature value to the temperature value sensed by the temperature sensor is matched with each other to prevent errors in judgment that may occur due to differences in configuration positions of the temperature sensor and the thermosensitive pigment,
Based on the image signal of the camera that captures the thermal pigment, it is determined whether the thermally sensitive pigment is damaged, and the result of the determination is used to determine whether the switchgear is abnormal by combining the partial discharge signal, the temperature signal, and the color signal of the thermally sensitive pigment. reflect,
It is determined whether the temperature value according to the color of the thermal pigment and the temperature value by the temperature sensor match. In consideration of this, the average temperature value of the temperature values detected by the four temperature-sensitive pigments and the average temperature value of the temperature values detected by the four temperature sensors are determined in correspondence with each other,
If the temperature value according to the color of the thermal pigment and the temperature value by the temperature sensor do not match, it is determined that the thermal pigment is damaged and the temperature value according to the color of the thermal pigment is combined with the temperature value by the partial discharge signal and the temperature sensor. A switchgear self-diagnosis system capable of smart monitoring for normal operation of partial discharge and partial discharge sensor, characterized in that it does not. The method of claim 1,
The sensor unit, the control device and the remote control server are wired and wirelessly networked, the remote control server is a manager terminal, and the control device and the remote control server share the data obtained by processing the detection signal by the sensor unit with each other to control the switchgear. A switchgear self-diagnosis system capable of smart monitoring for normal operation of partial discharge and partial discharge sensors, characterized in that constant management is possible. delete delete delete delete delete delete

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