KR20240079979A - Method and apparatus for detecting an arc in high power system using the pressure of insulating gas - Google Patents

Abstract

A method and device for detecting arc through the pressure of insulating gas and arc detection is provided. The arc detection device uses an optical sensor to detect the occurrence of an arc in a transmission pipe containing a circuit breaker, and detects the gas pressure in the transmission pipe containing a circuit breaker. A gas pressure sensor for measuring, detects that the gas pressure in the transmission pipe measured by the gas pressure sensor is below the first predetermined pressure value, and detects that the gas pressure in the transmission pipe measured by the gas pressure sensor is below the first predetermined pressure value. A transmission comprising a circuit breaker that detects a predetermined event after the pressure value falls below the arc and the gas pressure detected by an optical sensor based on the occurrence of the predetermined event after the gas pressure falls below the first predetermined pressure value. It includes a processor that determines that an arc has occurred in the pipeline.

Description

{Method and apparatus for detecting an arc in high power system using the pressure of insulating gas}

The present disclosure relates to a detection method and device for detecting an arc using the pressure of an insulating gas in a power system using high-power devices.

This disclosure is derived from a study conducted as part of the "Renewable Energy-Linked New Transmission 70kV Core Electrical Equipment Technology Development Project" conducted by the Korea Institute of Energy Technology Evaluation and Planning as a research management specialized organization and the Korea Electric Industry Technology Research Association as the lead organization. will be. [Project management number: 20193610100010, project name: Development and verification of intelligent-based 70㎸ substation digital network platform-linked condition monitoring and control device]

Arc discharge is often a problem when using high-power electrical devices. For example, ultra-high voltage GIS (Gas Insulated switched gear) is an important high-power electrical device used as a switch in the main circuit of power plants and substations. As such GIS operates at high power levels, high operational reliability is required and a robust preventive diagnostic device is required accordingly. A mechanism is needed.

If a problem occurs inside the ultra-high voltage GIS, partial discharge will initially occur, and insulation breakdown will progressively occur inside the ultra-high voltage GIS as a result of the partial discharge. When insulation breakdown accumulates inside an ultra-high voltage GIS, the accident critical point is exceeded and a major accident occurs.

At the same time, ultra-high pressure GIS is provided in the transmission pipe, and the transmission pipe is filled with insulating gas to prevent insulation breakdown of the ultra-high pressure GIS. If the pressure of this insulating gas decreases, the risk of arc occurrence also increases.

Arcs are initially generated in areas where electrical insulation is destroyed due to partial discharge, and it is very important for devices that control the power system to detect these arcs at an early stage in ensuring the reliability and safety of high-power heavy electric equipment.

However, although these arc detection sensor devices initially operate stably, there are cases where they fail to detect subtle malfunctions and deterioration in operating performance due to long-term use over time. If these subtle malfunctions or deterioration in operating performance continue, the reliability of the device sensor device itself will gradually decline, and eventually, it may recognize the occurrence of an arc even though it is not an arc, generate an error indicating that a system failure has occurred, and unnecessarily stop the system. Conversely, if an arc occurs but is not properly detected, it may result in fatal consequences that prevent a major accident from occurring.

Therefore, securing continuous operation performance even when the arc detection sensor device is used for a long period of time is very important to ensure the stability of high-voltage equipment or heavy electric equipment.

There is a need for a method and device that allows arc detection devices that detect arcs in high-power devices to precisely detect arc occurrence by using the pressure of the insulating gas in the transmission pipe and the arc detection optical sensor.

In order to solve the above problem, the present disclosure includes an optical sensor for detecting the occurrence of an arc in a transmission pipe containing a circuit breaker, a gas pressure sensor for measuring the gas pressure in the transmission pipe containing the circuit breaker, and the gas pressure sensor. After detecting that the gas pressure in the transmission pipe measured by is below the first predetermined pressure value, and after the gas pressure in the transmission pipe measured by the gas pressure sensor is below the first predetermined pressure value, A transmission pipe including the circuit breaker based on detecting a predetermined event and detecting the predetermined event again after the arc and the gas pressure detected by the optical sensor fall below the first predetermined pressure value. An arc detection device including a processor that determines that an arc has occurred is provided.

In one embodiment, the predetermined event is characterized as an event in which the gas pressure measured by the gas pressure sensor decreases below the first predetermined pressure value and then increases again.

In one embodiment, the processor controls the start of arc detection by the optical sensor from the time the predetermined event is detected.

In one embodiment, the predetermined event is characterized as an event in which the processor recovers the first predetermined pressure value.

In one embodiment, the predetermined event is characterized as an event in which the processor reaches a second predetermined pressure value that is greater than the first predetermined pressure value.

In order to solve the above problem, detecting that an arc occurs in a transmission pipe including a breaker through an optical sensor, and detecting that the gas pressure in the transmission pipe measured by the gas pressure sensor is less than or equal to a first predetermined pressure value. detecting a predetermined event, detecting a predetermined event after the gas pressure in the transmission pipe measured by the gas pressure sensor becomes less than the first predetermined pressure value, and an arc detected by the optical sensor An arc detection method is provided including the step of determining that an arc has occurred in a transmission pipe including the circuit breaker based on the predetermined event being detected after the gas pressure becomes less than or equal to the first predetermined pressure value.

Figure 1 is a diagram showing a transmission pipe containing insulating gas.
Figure 2 shows an example of an arc detection device that detects that an arc occurs in a power system according to an embodiment of the present disclosure.
Figure 3 is a diagram showing an arc detection system according to an embodiment of the present disclosure.
Figure 4 graphically illustrates an arc detection method according to an embodiment of the present disclosure.
Figure 5 shows an optical sensor 250 according to an embodiment of the present disclosure.
Figure 6 is a flowchart showing a method for an arc detection device to detect an arc based on gas pressure and arc detection according to an embodiment of the present disclosure.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the attached drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosure will be thorough and complete and so that the spirit of the invention can be sufficiently conveyed to those skilled in the art. Like reference numerals refer to like elements throughout the specification. Meanwhile, the terms used in this specification are for describing embodiments and are not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated in the phrase.

Usually, high-voltage devices or heavy electric devices belonging to the high-voltage power system require considerably high reliability because they have a high risk due to their operating power level. In other words, it is essential for safety to detect failures in devices in the power system within a short period of time or to predict failures in advance by detecting abnormal operations before failures occur at all.

A representative example of high-voltage equipment or heavy electric equipment is ultra-high voltage GIS (Gas Insulated Switched Gear). GIS is a large circuit breaker whose inside is filled with gas for insulation. Ultra-high voltage GIS is used as a switch on the main circuit in power plants and substations. Ultra-high voltage GIS is a device mainly used above 100kV and has a high power blocking ability. Ultra-high-voltage GIS is expensive because it is a switchgear for large-scale systems with high power levels, and therefore requires high reliability to prevent safety accidents in advance so that expensive devices are not damaged.

GIS has a pipe-type transmission line to connect the wiring from the blocked area, and these transmission lines are divided into gas compartments for each specific area. The gas used in GIS is typically SF6 gas, and this gas has very strong insulating properties, so it is used as an insulating gas in high-voltage applications.

Each gas compartment in which the transmission pipe is divided into gas compartments can usually monitor the health of the insulating gas pressure level of each gas compartment by installing a gas pressure sensor in each compartment to obtain status information. If insulating gas leaks, the insulation strength between line-line or line-ground between GIS internal conductors may drop, resulting in line-to-line short circuit or ground fault. Therefore, the gas pressure sensor installed in GIS is an important monitoring sensor that can check whether internal insulating gas is leaking. Therefore, the gas pressure sensor, once installed, is used to check whether the pressure inside the transmission pipe decreases.

Figure 1 is a diagram showing a transmission pipe containing insulating gas.

Referring to FIG. 1, it can be seen that the transmission pipe 30 is divided into sections and that an optical sensor 250 and a gas pressure sensor 220 are provided in each transmission pipe section. The light sensor 250 may be a sensor for detecting an arc, which is an optical signal. The optical sensor 10 is used to detect arcs occurring in the GIS within the transmission pipe through an optical sensor. In other words, the optical sensor 250 is a device that monitors the inside of the GIS and detects optical signals such as arcs. The optical sensor 250 is installed in each transmission pipe section and is used to detect arcs that may occur inside it (in a dark state). The arc detection device including the optical sensor 250 can detect an optical signal such as an arc that occurs during a short circuit or ground fault inside the GIS and inform the upper system of the accident.

Normally, if the arc is detected using only the optical sensor 250, it is possible to monitor whether the insulation of the GIS is broken, but in order to ensure GIS safety at a higher level, it is necessary to use the gas pressure sensor 220 in parallel.

Figure 2 shows an example of an arc detection device that detects the occurrence of an arc in a power system according to an embodiment of the present disclosure.

The arc detection device 100 that detects the occurrence of the arc 101 mainly uses an optical sensor 250 that detects the arc 101 with light. Referring to FIG. 2, when an arc 101 occurs in the power switch 110 of a switchboard or distribution board, the optical sensor 250 detects this arc optical signal and generates a fault signal 111 to protect the protection circuit 130. ) is sent to. The protection circuit 130 starts a power system protection function according to a fault signal. An example of the protection function is a method of protecting the power switch 110 by shorting the ground switch 140 connected to the power switch 110.

However, the occurrence of an arc can be seen as a sign that the insulation breakdown of the power line has already progressed to a significant extent in the switchboard or switchboard. Considering that the power level of the power system is quite high, the arc occurs in advance before the arc occurs in the switchboard or switchboard. There is a need to detect the risk of occurrence in advance. Additionally, a dual detection mechanism for arcing in addition to the optical sensor 250 may be required.

Figure 3 is a diagram showing an arc detection system according to an embodiment of the present disclosure.

For example, this power system receives three-phase high power of 22.9kV as input. The arc detection device 1000 may include a processor 291, a memory 293, an optical sensor 250, and a gas pressure sensor 220. In one embodiment, the arc detection device 1000 may further include a current sensor 260 and an antenna 280. The arc detection device 1000 detects an arc occurring in a switchboard or distribution board equipped with a three-phase power line 2001 through the optical sensor 250. Usually, an arc can appear as an optical signal in the form of a short pulse, so the arc is detected through the optical sensor 250. In one embodiment, the arc detection device 1000 also checks the door open signal 2005 of the switchboard or distribution board to prevent false detection of external light due to the door opening, rather than an arc, as an arc. If it is determined that an arc has occurred, the arc detection device 1000 may operate the protection relay 240 to block the three-phase power line 2001 through the arc eliminator 270. The arc detection device 1000 may internally generate control commands for arc detection and control peripheral devices through the processor 291.

The arc detection device 1000 can detect arc occurrence through the gas pressure sensor 220. As gas continues to leak over time from the transmission pipe 30 in which the arc detection device 1000 detects arc occurrence, the gas pressure continues to decrease, but the pressure decrease stops and the gas pressure increases again, which is detected by a gas pressure sensor ( When detected through 220), the processor 291 may determine that an arc is occurring by determining that the gas pressure in the transmission pipe 30 increases due to the arc occurring. The arc detection method using the gas pressure sensor 220 will be described in more detail with reference to FIG. 4.

The arc detection device 1000 may optionally be equipped with an antenna 280 that detects high-frequency signals. The antenna 280 detects a partial discharge signal showing a high frequency pattern of 5 MHz to 15 MHz. Usually, partial discharge signals occur frequently in the range of 8MHz to 10MHz.

Figure 4 graphically illustrates an arc detection method according to an embodiment of the present disclosure.

In Figure 4, the top shows the gas pressure and the bottom shows the arc accident occurrence warning level.

Until t ₁ , the gas in the transmission pipe 30 may continue to decrease due to leakage. Gas pressure can be continuously monitored by gas pressure sensor 220. If gas continues to leak, the gas pressure in the transmission pipe 30 may increase due to some cause from time _t2 . A typical case in which the gas pressure increases is when the internal gas pressure increases as the ambient temperature within the transmission pipe 30 increases due to the occurrence of an arc within the transmission pipe 30. In this case, even though the risk level due to arc generation increases, the gas pressure in the transmission pipe 30 does not fall to the accident level even though the gas pressure may drop to the accident level, and the gas pressure in the transmission pipe 30 starts from t ₂ before the accident level. As the gas pressure rises and exceeds the gas leak warning level again from point _t3 , the gas leak warning is canceled even though the actual insulation breakdown risk level of the circuit breaker has increased. This warning cancellation occurred at a time when arc occurrence was dangerous, so it is unreasonable in terms of stability management of the entire system.

In one embodiment of the present disclosure, the processor 291 of the arc detection device 1000 detects both gas pressure and arc and uses them as the basis for arc detection determination to increase arc detection accuracy. As shown in FIG. 4, when the gas in the transmission pipe 30 continues to decrease due to leakage, the gas pressure in the transmission pipe 30 decreases and reaches the gas leak warning level at time t ₁ . At this time, the processor 291 generates a gas pressure warning and outputs it through the output interface of the arc detection device 1000. In this situation, if gas is re-injected or other safety measures are not taken, and the gas pressure in the transmission pipe 30 rises again at time t ₂ and the gas leak warning level is recovered again, the processor 291 of the arc detection device 1000 ) determines that this recovery of the gas pressure level is not normal but that the gas pressure has increased due to arc generation, and the processor 291 may determine that an arc has occurred. At this time, the processor 291 detects an arc in the transmission pipe 30 through the optical sensor 250 and performs a protection operation when the arc is actually detected. The protective operation may be, but is not limited to, operating the protection relay 240, operating the arc eliminator 270, or blocking the power source 210.

The level for detecting the level at which the gas pressure in the transmission pipe 30 decreases and then increases again can be set in various ways. In one embodiment, the gas leak warning level in FIG. 4 is set to a first predetermined pressure value, which can be a starting point for determining whether the gas pressure rises again within a predetermined time. The processor 291 may determine that there is a high possibility that an arc has occurred within the transmission pipe 30 when a predetermined event occurs after the gas pressure drops beyond the first predetermined pressure value. In one embodiment, when an event occurs in which the gas pressure rises again and the gas leak warning level is restored, the processor 291 determines that it is highly likely that an arc has occurred within the transmission line 30 - or that an arc has occurred. You can judge. In another embodiment, the processor 291 detects an inflection event in which the gas pressure falls below a first predetermined pressure value and then rises again, even if the gas pressure has not yet recovered to the gas leak warning level. It can be determined that there is a high possibility that an arc has occurred - or that an arc has occurred. Or, in one embodiment, the processor 291 sets the second predetermined pressure value so that the gas pressure rises again and the gas pressure is greater than the predetermined value than the gas leak warning level, and the gas pressure is set to the second predetermined pressure value. When an event occurs, it can be determined that an arc has occurred.

In one embodiment, the optical sensor 250 may be operated at all times to detect arcs occurring within the transmission pipe 30 for arc detection, but in this case, there is a possibility of false detection due to door opening, so the processor 291 When the pressure of the insulating gas in the transmission pipe 30 decreases and reaches an accident level lower than the gas leak warning level, there is a high possibility of a short-circuit accident or ground fault accident due to a lack of insulating gas, so at this accident level or the gas leak warning level, the light By activating the sensor 250, arc occurrence can be accurately determined.

As shown in FIG. 4, the most GIS (circuit breaker) insulation breakdown accidents occur from the time t ₃ when the frequency of arc detection by the optical sensor 250 increases after the time t ₂ when the gas pressure decreases and then increases again due to arc generation. This can be considered a high-risk stage. Accordingly, the processor 291 of the arc detection device 1000 may determine the time between t ₃ and t ₄ as the highest level of accident warning.

As described above, the arc detection device 1000 can precisely respond to an insulation breakdown accident in the GIS based on two events: a change in the pressure of the insulating gas in the transmission pipe 30 and the frequency of arc occurrence.

Figure 5 shows an optical sensor 250 according to an embodiment of the present disclosure.

Referring to FIG. 5, the optical sensor 250 includes an optical signal receiver 251 that receives the arc as an optical signal when an arc occurs, and the detected arc is received by the optical signal receiver 251 and then transmitted to another device or processor as an arc signal. (291) may include an optical signal transmission unit 252 for transmitting as a signal.

The point at which arc generation due to partial discharge is often observed in the power system is when the voltage of the power source 210 of the power system is high. Therefore, when the arc detection device 1000 transmits a periodic self-diagnosis signal to the optical sensor 250 to determine whether the optical line is operating properly, it is desirable to avoid a point in time when an arc is likely to occur. This is because, if the feedback signal of the self-diagnosis signal that the arc detection device 1000 receives from the optical sensor 250 is mixed with the actual arc signal, it may not be possible to distinguish between the two signals.

Therefore, it is desirable for the arc detection device 1000 to transmit a self-diagnosis signal at a point where the voltage of the power system is low in order to increase self-diagnosis reliability. Accordingly, in one embodiment, the arc detection device 1000 may generate a self-diagnosis signal by synchronizing with the point where the voltage of the power source 210 of the power system crosses zero. Although it is desirable to sync the self-diagnosis signal to the same zero crossing point, when the voltage of the power system is relatively low compared to the peak voltage after a predetermined time has elapsed near the zero crossing point, the self-diagnosis signal is generated and the optical sensor You can also send it to (250).

Figure 6 is a flowchart showing a method for an arc detection device to detect an arc based on gas pressure and arc detection according to an embodiment of the present disclosure.

In step S610, the occurrence of an arc in the transmission pipe 30 including the circuit breaker is detected through the optical sensor 250. According to one embodiment, the optical sensor 250 may be turned on at all times to detect an arc. According to one embodiment, the optical sensor 250 may not be always on and the processor may be controlled to start operation according to the gas pressure level and the occurrence of an event. According to one embodiment, the optical sensor 250 may not be turned on at all times but may detect the arc periodically - for example, at 10-second intervals or at 30-second intervals for 10 seconds.

In step S620, the processor 291 of the arc detection device 1000 detects that the gas pressure in the transmission pipe 30 measured by the gas pressure sensor 220 is below a first predetermined pressure value. The first predetermined pressure value may be, for example, the gas leak warning level in FIG. 4.

In step S630, the processor 291 of the arc detection device 1000 performs a predetermined signal that occurs after the gas pressure in the transmission pipe 3 measured by the gas pressure sensor 250 falls below the first predetermined pressure value. events can be detected. In one embodiment, the predetermined event may be an event in which the gas pressure measured by the gas pressure sensor 220 decreases below a first predetermined pressure value and then increases again. In another embodiment, the predetermined event may be an event where the gas pressure (value) becomes the first predetermined pressure value again. In another embodiment, the predetermined event may be an event in which the gas pressure reaches a second predetermined pressure value that is greater than the first predetermined pressure value. In another embodiment, the predetermined event may be an event in which the gas pressure reaches a second predetermined pressure value that is greater than the first predetermined pressure value.

In step S640, the processor 291 connects the transmission line 30 including the breaker based on the occurrence of a predetermined event after the arc and gas pressure detected by the optical sensor 250 fall below the first predetermined pressure value. It is determined that an arc has occurred.

The processor 291 may take appropriate protective measures if it determines that an arc has occurred. For example, as shown in FIG. 2, when a failure signal 111 is generated and transmitted to the protection circuit 130, the protection circuit 130 can start a power system protection function according to the failure signal. An example of a protection function is a method of protecting the switch 110 by short-circuiting the ground switch 140 connected to the power switch 110 under the control of the processor 291.

As described above, embodiments of the present invention have been disclosed through detailed descriptions and drawings. The terms are used only for the purpose of describing the present invention, and are not used to limit the meaning or scope of the present invention described in the claims. Therefore, those skilled in the art will understand that various modifications and other equivalent embodiments are possible from the present specification. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims.

30; transmission line
100; arc detection device
101; ARC
110; power switch
130; protection circuit
140; ground switch
210; input power
220; gas pressure sensor
250; optical sensor
251; Optical signal receiver
252; Optical signal transmission unit
240; protection relay
270; arc eliminator
280; Antenna
291; processor
293; Memory
1000; arc detection device
2001; power line
2003; ground line

Claims (8)

An optical sensor that detects arcs occurring in transmission pipes containing circuit breakers;
A gas pressure sensor for measuring the gas pressure in the transmission pipe containing the circuit breaker;
Detecting that the gas pressure in the transmission pipe measured by the gas pressure sensor is below a first predetermined pressure value,
Detecting a predetermined event after the gas pressure in the transmission pipe measured by the gas pressure sensor falls below the first predetermined pressure value, and
A processor that determines that an arc has occurred in the transmission pipe including the circuit breaker based on detecting the predetermined event again after the arc detected by the optical sensor and the gas pressure fall below the first predetermined pressure value. An arc detection device comprising: According to claim 1,
The predetermined event is an arc detection device characterized in that the gas pressure measured by the gas pressure sensor decreases below the first predetermined pressure value and then increases again. According to claim 2,
The processor is an arc detection device characterized in that it controls the start of arc detection by the optical sensor from the point at which the predetermined event is detected. According to claim 1,
The predetermined event is an event in which the gas pressure recovers the first predetermined pressure value. According to claim 1,
The predetermined event is an event in which the gas pressure reaches a second predetermined pressure value that is greater than the first predetermined pressure value. Detecting that an arc occurs in a transmission pipe containing a circuit breaker through an optical sensor;
detecting that the gas pressure in the transmission pipe measured by a gas pressure sensor is below a first predetermined pressure value;
detecting a predetermined event after the gas pressure in the transmission pipe measured by the gas pressure sensor becomes lower than the first predetermined pressure value; and
A step of determining that an arc has occurred in the transmission pipe including the circuit breaker based on the predetermined event being detected after the arc and the gas pressure detected by the optical sensor fall below the first predetermined pressure value. Arc detection method including. According to claim 6,
The step of detecting the predetermined event after the gas pressure in the transmission pipe measured by the gas pressure sensor falls below the first predetermined pressure value,
An arc detection method comprising controlling to initiate arc detection through the optical sensor upon detecting an event in which the gas pressure decreases and then increases again. According to claim 6,
The arc detection method, characterized in that the predetermined event is an event in which the gas pressure recovers the first predetermined pressure value.

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