KR20220053443A - Method for preventing accidents due to disconnection of power distribution line - Google Patents

Abstract

Disclosed is a power system control method comprising the steps of: obtaining a breakdown detection time point when zero crossing has to occur on alternating current flowing in a power line connected between an upstream-side power distribution system and a downstream-side power distribution device but zero crossing does not occur; obtaining a fault waveform detection time point when the upstream-side power distribution system detects a fault waveform occurring on the power line; and determining whether the upstream-side power distribution system (100) is to re-supply power to the power line (70) based on the breakdown detection time point and the fault waveform detection time point. Therefore, provided is an analysis device for detecting high-resistance ground faults in an RTU.

Description

Method for preventing accidents due to disconnection of power distribution line

The present invention relates to a power system monitoring and processing method, and more particularly, to a technology for quickly determining whether an accident occurs in a distribution line distributed from a substation.

The current technology for blocking accidents on distribution lines in distribution automation systems uses a method of protecting lines with CB (Circuit Breaker) and R/C (Recloser). Typically, it is configured to detect fault currents in R/C and block accidents in distribution lines through reclosing up to 3 times and protect the system. However, voltage and current information obtained from the switch body in order to determine the presence or absence of a failure generates erroneous information due to inaccuracy of the sensor, so that the disconnection/phase loss information is not trusted in the distribution center. For this reason, when the insulated wire is disconnected, the line is not immediately cut off, so there is a risk of safety accidents and disasters such as forest fires. A detailed technical configuration related thereto will be described below with reference to FIG. 1 .

1 shows a substation 20 for converting ultra-high voltage power into high voltage power, a plurality of feeders branched from the substation (Feeder#1 to Feeder#3), and reclosers 30 and RC1 to RC3 respectively connected to the feeders. ), high voltage power lines (PL) connected to the reclosers, switchgear 40 respectively connected to the high voltage power lines, RTUs 51 to 56 respectively installed in the switchgear, connected to the feeder / power lines It is a diagram briefly showing the connection relationship of commercial power transformers (TR).

Power lines PL may be connected to the switch 40 (eg, 41 ), and an accident in which the power lines PL are disconnected may occur. For example, an upstream power line PL1 and a downstream power line PL11 may be connected to the switch 41 . Among them, whether the upstream power line PL1 is disconnected may be detected by the recloser 30 (eg, 31 ) connected to the upstream power line PL1 . However, the recloser 31 does not determine that the power line PL1 is actually disconnected only when the power line PL1 is disconnected, but is a very temporary problem with the power line PL1 (for example, when a broken branch collides with the power line PL1 for a short time). Even when a problem that is solved naturally) occurs, it may be determined that it is a disconnection.

In the case of the actual disconnection, voltage zero crossing due to the power supplied through the power line PL1 will not occur, but when the very temporary problem occurs, the power supplied through the power line PL1 may Voltage zero crossings can occur continuously.

When it is determined that the recloser 31 is disconnected, the connection between the power line PL1 connected to the recloser 31 and another power line (eg, PL11) is disconnected. However, as described above, since a very temporary problem may occur in the power line, power supply to the power line may be resumed again after 3 cycles, for example, 50 ms, of the AC commercial power provided by the power line. When it is determined that there is no abnormality in the state of the power line after restarting the power supply, the power supply to the power line may be continuously maintained.

However, when it is determined that the power line PL1 is disconnected even after the power supply is resumed, the recloser 31 may again cut the connection between the power line PL1 and the other power line PL11 again. That is, in this case, it is determined that a real and semi-permanent problem has occurred, rather than a very temporary problem that is naturally solved in the power line PL1. However, in this determination process, a major accident may occur while power is supplied to the power line PL1 having a problem even for a short time. For example, if lightning strikes a pole on a pole and breaks the power supply, the power supply must be immediately and continuously stopped. , which is actually a serious threat.

Therefore, when a practical problem occurs in the power system, a technology to quickly confirm the fact is required.

An object of the present invention is to provide a technique for quickly determining the fact when a problem occurs in the distribution power system to which commercial power is distributed.

Since the current voltage sensing method (housing or CPD) of switchgear for distribution automation cannot accurately detect high-resistance ground faults caused by disconnection of insulated wires, the present invention provides an analysis device that can detect high-resistance ground faults in RTU want to

The control method of the wiring system provided according to one aspect of the present invention is, when a disconnection occurs in the power line of the first section between the first recloser and the first switchgear in the first feeder connected to the substation, the power line of the first section It relates to a method including the process of accurately detecting the presence or absence of a disconnection.

Specifically, the method includes, by the first RTU connected to the first switch, detecting a zero crossing time of the signal detected from the circuit by using a circuit for detecting a voltage from a power line connected to the first switch. Here, the power line connected to the first switchgear may be, for example, a power line of the first section or a power line of another segment connected to the first switchgear and a power line having the same phase as the power line of the first section. If the power flowing through the wiring system is AC power and has a frequency of, for example, 60 Hz, the interval between the zero crossing points will be 1/60 = 16.7 ms. Therefore, given one zero-crossing time, it is possible to predict the next zero-crossing time.

A time point at which zero crossing is not generated even though zero crossing should occur may be referred to as a break down detection time point.

The method includes the step of recording, by the first RTU or the first switchgear, the break-down detection time. The time may be determined using the GPS connected to the first RTU or the first switch.

Then, the method includes the step of transmitting, by the first RTU or the first switchgear, the break-down detection point to a remote server. In this case, when the server receives the break-down detection time point, the server may determine that the zero crossing has not occurred even though the zero crossing should occur at the corresponding time point. To this end, when the first RTU or the first switchgear transmits the breakdown detection time to the server, additional information indicating that zero crossing has not occurred even though it should occur may be transmitted together.

And the method may include the step of detecting, by the first recloser, an accident occurring in the power line of the first section. This step may be made by the prior art, and the scope of the present invention is not completely limited by the specific method.

In addition, in the method, the first recloser and the server communicate with each other, and the first information on whether or not an accident occurring in the power line of the first section is detected, and zero crossing in the first switch and determining the next operating state of the first recloser by using the second information on whether or not it has not occurred despite the fact.

The device for determining the operating state of the first recloser may be the first recloser or the server.

When the device for determining the operating state of the first recloser is the first recloser, immediately after the server receives the break-down detection time or the server determines that zero crossing has not occurred even though it should occur Immediately thereafter, the step of generating a zero crossing alarm may be executed. In addition, the step of the server transmitting the zero crossing alarm to the first recloser may be executed. At this time, the first recloser is the interval between the time when the first recloser detects an accident occurring in the power line of the first section and the time when the first recloser receives the zero crossing alarm from the server When the absolute value is less than a predetermined value, it is possible to determine the fact that an accident has occurred in the power line of the first section, and execute a subsequent operation accordingly. For example, the subsequent operation is that the first recloser continuously cuts the connection between the first feeder and the power line of the first section.

On the other hand, when the device for determining the operation state of the first recloser is the server, the first recloser may transmit the fact of detecting the accident and the detection time of the accident to the server. At this time, the server, when the absolute value of the interval between the time when the first recloser detects the accident occurring on the power line in the first section and the break-down detection time is less than a predetermined value, the first section It is possible to determine the fact that an accident has occurred on the power line and execute subsequent actions accordingly. For example, the subsequent operation may be that the server notifies the first recloser that the fact that an accident has occurred in the power line of the first section is confirmed, or transmits a specific command to the first recloser . The specific command is, for example, that the first recloser continuously cuts the connection between the first feeder and the power line of the first section.

When the first recloser receives the fact that the fact that an accident has occurred in the power line of the first section is confirmed from the server, the first recloser may execute a subsequent operation accordingly. For example, the subsequent operation is that the first recloser continuously cuts the connection between the first feeder and the power line of the first section.

When the first recloser determines the operating state of the first recloser, the determination of the operating state may be made more quickly than when the server determines the operating state of the first recloser.

The determination of the operating state of the first recloser may be made within a predetermined time limit from a point in time when the first recloser detects an accident occurring in the power line of the first section. In a preferred embodiment, the time limit may be three periods of the AC frequency of commercial power supplied to the power line of the first section. For example, when the AC frequency is 60 Hz, one cycle may be 1/60 s, and in this case, the three cycles may be 3/60 s=50 ms.

The circuit for detecting a voltage from a power line connected to the first switch may include a voltage sensor and a current sensor of the first switch. The determination that the zero crossing has not occurred despite the need to occur may be made when the zero crossing is not detected in both the voltage detection sensor and the current detection sensor.

The method for determining the reclosing function provided according to another aspect of the present invention is a method of accurately finding the presence or absence of disconnection in a section when phase B disconnection occurs between the first recloser and the first switchgear in the first feeder. In the first RTU, it includes the process of detecting a zero-crossing signal of a frequency from a circuit that detects a voltage from the first switchgear, receiving the time at which zero-crossing is not detected from the GPS, recording it, and transmitting it to the server. At this time, the first recloser also detects an accident and blocks or blocks the line. In the process of delivering the accident details to the server and determining whether it is an accident caused by a simple leakage current or a disconnection, the frequency detection of the first switchgear is compared It involves the process of judging lung function.

According to another aspect of the present invention, the method for determining the presence or absence of disconnection is a detection of 3 cycles or less at a time when the zero crossing of the 60Hz component of commercial power input from the voltage and current sensing sensors of the switch is not detected by the two sensors. It detects an accident and generates an event to the server through do.

According to one aspect of the present invention, a server connected to the switchgear is connected to a breakdown detection point, which is a point in time when zero crossing does not occur despite zero crossing of AC power flowing in a power line connected between the recloser and the switchgear according to one aspect of the present invention. receiving from; And so that the operation state of the recloser is determined by using together the first information regarding the time of occurrence of the accident occurring in the power line detected by the recloser and the second information regarding the time of detection of the break down, the server A method of controlling the operation of the recloser, including; communicating with the recloser, may be provided.

In this case, the communicating may include, by the server, receiving the occurrence point from the recloser; determining, by the server, that an accident has occurred in the power line when the interval between the occurrence time and the break-down detection time is smaller than a predetermined value; and transmitting, by the server, the fact that the fact that an accident has occurred in the power line has been confirmed or a specific command to the recloser.

At this time, in the communicating step, immediately after the server receives the breakdown detection time point or immediately after determining that the zero crossing has not occurred despite the fact that the zero crossing should occur, a zero crossing alarm including the breakdown detection time point and transmitting the zero-crossing alarm to the recloser, wherein the recloser detects that an accident has occurred in the power line when the interval between the occurrence time and the break-down detection time is less than a predetermined value. may be set to be confirmed.

At this time, the time point at which the fact that the accident occurred in the power line is confirmed is within a predetermined time from the detection time point when the recloser detects the occurrence point of the accident occurring in the power line, and the predetermined time is the frequency of the AC power It can be a multiple of three of

According to another aspect of the present invention, a recloser operation control server including a communication unit and a processing unit may be provided. At this time, the processing unit, through the communication unit, the device connected to the switchgear at a breakdown detection point, which is a time point at which zero crossing does not occur despite zero crossing of AC power flowing in the power line connected between the recloser and the switchgear should occur. and receiving from the recloser, using the first information on the time of occurrence of the accident occurring in the power line detected by the recloser and the second information on the time of detection of the break down together with the recloser. The step of communicating with the recloser through the communication unit is performed so that the operating state is determined.

In this case, the processing unit, in the communicating step, the step of receiving the occurrence point from the recloser; determining that an accident has occurred in the power line when the interval between the occurrence time and the breakdown detection time is smaller than a predetermined value; and transmitting the fact that the fact that an accident has occurred in the power line has been confirmed or a specific command to the recloser;

According to another aspect of the present invention, a recloser; switch; and a server; may be provided with a distribution management system including. At this time, in the switch or the device locally connected to the switch, the break-down detection time, which is a time point at which zero crossing does not occur, even though zero crossing of AC power flowing in a power line connected between the recloser and the switch has to occur. to be transmitted to the server. And, the recloser is configured to detect the occurrence time of the accident occurring in the power line and transmit the occurrence time to the server. And the server is configured to determine that an accident has occurred in the power line when it is smaller than a predetermined value of the interval between the occurrence time and the break-down detection time, and when it is determined that an accident has occurred in the power line, to the determination related information is transmitted to the recloser. And the recloser is configured not to resume power supply to the power line upon receiving the information on the confirmation.

According to another aspect of the present invention, a recloser; switch; and a server; may be provided with a distribution management system including. At this time, in the switch or the device locally connected to the switch, the break-down detection time, which is a time point at which zero crossing does not occur, even though zero crossing of AC power flowing in a power line connected between the recloser and the switch has to occur. to be transmitted to the server. And, the server generates a zero crossing alarm including the breakdown detection time point immediately after receiving the breakdown detection time point or immediately after determining that the zero crossing has not occurred despite the need to occur, thereby generating the zero crossing alarm. to be transmitted to the recloser. And the recloser is configured to determine that an accident has occurred in the power line when the interval between the occurrence time and the break-down detection time is smaller than a predetermined value, and when it is determined that an accident has occurred in the power line, the power line The power supply is not to be resumed.

According to one aspect of the present invention, the power system control device must issue zero crossing of AC power flowing in the power line 70 connected between the upstream power system distribution system 100 and the downstream power system distribution device 150 acquiring a break-down detection time point, which is a time point at which zero crossing does not occur in spite of this; acquiring, by the power system control device, the fault waveform detection time point, which is the time point at which the upstream power system distribution system detects the fault waveform generated in the power line (70); and determining, by the power system control device, whether or not to re-supply power to the power line 70 by the upstream power system distribution system 100 based on the break-down detection time and the accident waveform detection time; Including, a power system control method may be provided.

At this time, when the break-down detection time is earlier than the fault waveform detection time, it is determined that the power line control device does not re-supply power to the power line by determining that an accident related to the break-down detection time point has occurred in the power line. may be made to do.

At this time, when the break-down detection time is later than the accident waveform detection time, the cause of the breakdown is not due to an accident related to the power line, but the upstream power distribution system cut off the power provided to the power line By judging that this is the case, the power system control device may be configured to determine to re-supply power to the power line.

At this time, the upstream power distribution system 100 provides or cuts off the AC power output from the substation to the power line 70 , and the downstream power distribution device 150 provides the power line 70 . to provide or cut off the AC power provided from the power line to another power line connected to the downstream power distribution device 150, and the upstream power distribution system 100 is configured to generate an accident waveform generated in the power line 70 is detected, the power supplied to the power line may be cut off, and then power may be re-supplied to the power line according to a predetermined condition.

At this time, when it is decided not to re-supply power to the power line 70, the upstream power distribution system 100 ignores the predetermined condition and may not re-supply power to the power line.

At this time, the upstream power distribution system 100 is configured to provide or block the AC power output from the substation to the power line 70, and output from the substation among the upstream power distribution system 100 The upstream power system distribution device 130, which is a device for providing, blocking, or resupplying the AC power to the power line 70 is a circuit breaker (CB, Circuit Breaker) or a recloser (RC, Recloser), and the upstream The side power system distribution device 130 determines the fault waveform detection time point, which is the point at which the upstream side power system distribution device 130 detects the fault waveform generated in the power line 70, and provides it to the power system control device may be made to do.

At this time, the downstream power system distribution device 150 includes a switch connected to the power line 70; a sensor for detecting current or voltage from the power line (70); and a communication unit that determines a break-down detection time point, which is a point in time when zero crossing does not occur despite the need to generate zero crossing in the signal output from the sensor, and transmits the break-down detection time to the power system control device; can

At this time, the upstream power distribution system 100 provides or cuts off the AC power output from the substation to the power line 70, and the power system control device includes the upstream power distribution system ( 100) may be an upstream power system distribution device 130 which is a device for providing or blocking the AC power output from the substation to the power line 70 .

At this time, the upstream power distribution system 100 provides or cuts off the AC power output from the substation to the power line 70, and the power system control device includes the upstream power distribution system ( 100) of the upstream power system distribution device 130 and the downstream power system distribution device 150, which are devices that provide or cut off the AC power output from the substation to the power line 70. A server ( 10) can be.

At this time, in the power system control method, when it is determined that the upstream power system distribution system 100 re-supply the current provided to the power line 70 , the upstream power system distribution system 100 controls the power line providing, by the power system control device, a signal to resupply the current provided to the power line 70 to the upstream power system distribution system 100 to resupply the current provided to the power line 70; may further include.

At this time, the downstream power system distribution device 150 includes a downstream GPS device used to determine the break down detection time, and the upstream power distribution system 100 detects the accident waveform detection point. It may include an upstream GPS device used to determine.

In this case, one end of the power line 70 may be connected to the downstream power system distribution device 150 . And the other end of the power line 70 is a device included in the upstream power distribution system 100, and is a device for providing, blocking, or resupplying the AC power output from the substation to the power line 70, upstream power. It may be connected to the system distribution device 130 .

In this case, the power system control device may acquire the fault waveform detection point from the upstream power system distribution system 100 . At this time, in particular, the power system control device provides or blocks the AC power output from the substation to the power line 70 as a device included in the upstream power distribution system 100 at the time of detecting the accident waveform. It can be obtained from the upstream power system distribution device 130, which is a re-supply device.

The upstream power system distribution device 130 may be a circuit breaker (CB) or a recloser (RC, Recloser).

According to another aspect of the present invention, a power system control device including a communication unit and a processing unit may be provided. The processing unit, the time point when the zero crossing does not occur despite the zero crossing of the AC power flowing in the power line 70 connected between the upstream power distribution system 100 and the downstream power distribution device 150 should be issued to perform the step of acquiring the in-breakdown detection point through the communication unit; the upstream power distribution system performs the step of acquiring the fault waveform detection time point, which is the time point at which the fault waveform generated in the power line 70 is detected; And the upstream power distribution system 100 determines whether to re-supply power to the power line 70 based on the breakdown detection time and the accident waveform detection time.

At this time, the processing unit, when the break-down detection time is later than the fault waveform detection time, the power system control device is configured to determine to re-supply power to the power line, and the break-down detection time is the accident If it is ahead of the waveform detection time, the power system control device is configured to determine not to re-supply power to the power line.

The power system control device according to another aspect of the present invention; and a downstream power system distribution device; a power system control system including a power system control system may be provided. In this case, in the downstream power system distribution device, a switch connected to the power line 70, a sensor detecting a current or voltage from the power line 70, and a signal output from the sensor should generate zero crossing despite the fact that and a communication unit for determining a break-down detection time point, which is a time point at which zero crossing does not occur, and transmitting the break-down detection time point to the power system control device.

According to the present invention, when a problem occurs in the distribution power system to which commercial power is divided, it is possible to provide a technology for quickly determining the fact.

According to the present invention, it is possible to prevent safety accidents and prepare for disasters due to fire, etc. by blocking the line within the reclosing standby time (several cycles) when the insulated wire of the distribution line is disconnected.

According to the present invention, when a disconnection accident is detected in the RTU, safety can be secured by quickly transmitting the data to the main device and locking out the CB and R/C.

According to the present invention, since the effect of the invention can be obtained by adding a detection device based on the existing system while maintaining the existing system, the investment cost can be reduced.

1 is a substation that converts ultra-high voltage power into high voltage power, a plurality of feeders branched from the substation, reclosers respectively connected to the feeders, high voltage power lines connected to the reclosers, and high voltage power lines respectively connected to the It is a diagram briefly showing the connection relationship of switchgear, RTUs respectively installed in the switchgear, and commercial power transformers connected to the feeder/power lines.
2 shows the configuration of the disconnection detection circuit 1 and the insulator 60 according to an embodiment of the present invention.
3 is a diagram showing disconnection detection circuits and commercial power frequency and zero-crossing square wave through a first insulator, a second insulator, and a third insulator according to an embodiment of the present invention.
4 is a diagram for explaining a method of determining whether to reclose an RTU, a recloser, and a server according to an embodiment of the present invention.
5 is a view for explaining an operation control method of the recloser according to an embodiment of the present invention.
6 is a view for explaining in detail step S160 of FIG. 5 according to an embodiment of the present invention.
7 is a view for explaining in detail step S160 of FIG. 5 according to another embodiment of the present invention.
8 is a diagram illustrating the configuration of a power system control system provided according to an embodiment of the present invention.
9 is a diagram showing the configuration of a power system control system provided according to another embodiment of the present invention.
10 is a detailed method for determining whether the upstream power distribution system re-supply power to the power line based on the break down detection time and the accident waveform detection time according to an embodiment of the present invention. It's a timing diagram.
11 is a flowchart illustrating a power system control method provided according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be implemented in various other forms. The terminology used herein is for the purpose of helping the understanding of the embodiments, and is not intended to limit the scope of the present invention. Also, singular forms used hereinafter include plural forms unless the phrases clearly indicate the opposite.

2 shows the configuration of the disconnection detection circuit 1 and the insulator 60 according to an embodiment of the present invention.

The insulator 60 is a mechanism used to insulate electricity from a power transmission line or the like, and may be configured to be fastened to the switch 40 of FIG. 1 . For example, three insulators 60 may be fastened to one switch 40 .

The insulator 60 may include a voltage detection sensor 61 and a current detection sensor 62 .

The circuit of the voltage detection sensor 61 may have the same configuration as that of reference numeral A1, and accordingly, a graph for commercial power frequency and a zero-crossing square wave of the voltage detection sensor may be the same as reference numerals A11 and A12.

The circuit of the current sensing sensor 62 may have the same configuration as that of reference numeral A2, and the graph of the commercial power frequency and the zero-crossing square wave of the current sensing sensor may be the same as those of reference numerals A21 and A22.

The voltage detection sensor 61 and the current detection sensor 62 may be configured as circuits including, for example, a photocoupler/optocoupler.

In another embodiment, reference numerals A1 or A2 of FIG. 1 may include an ADC instead of an optocoupler. The ADC may convert the analog voltage detected by the voltage detection sensor 61 or the current detection sensor 62 into a digital value and output it. In the digital value, when the analog voltage has a positive value, the sine bit of the digital value has a value of +1, and conversely, when the analog voltage has a negative value, the sine bit of the digital value has a value of -1. can have a value. Accordingly, a moment when the sine bit of the digital value observed over time changes from +1 to -1 or a moment from -1 to +1 may be determined as the zero crossing occurrence time.

3 shows disconnection detection circuits and commercial power frequency and zero-crossing square wave through a first insulator, a second insulator, and a third insulator according to an embodiment of the present invention.

The configuration of the first insulator 60_1 , the second insulator 60_2 , and the third insulator 60_3 may be the same as that of the insulator 60 of FIG. 2 .

The first insulator 60_1, the second insulator 60_2, and the third insulator 60_3 are for phase A, phase B, and phase C, respectively.

Circuit diagrams B1 and B2 of the second voltage detection sensor 63 of the second insulator 60_2, the second current detection sensor 64, and the third voltage detection sensor 65 of the third insulator 60_3, the second 3 Circuit diagrams C1 and C2 of the current detection sensor 66 may be the same as circuit diagrams A1 and A2 of the first voltage detection sensor 61 and the first current detection sensor 62 of the first insulator 60_1. .

The commercial power frequency and the zero-crossing square wave through the first voltage detection sensor 61 may be the same as graphs A11 and A12.

The commercial power frequency and the zero-crossing square wave through the first current sensing sensor 62 may be the same as graphs A21 and A22.

The commercial power frequency and the zero-crossing square wave through the second voltage detection sensor 63 may be the same as graphs B11 and B12.

The commercial power frequency and the zero-crossing square wave through the second current detection sensor 64 may be the same as graphs B21 and B22.

The commercial power frequency and the zero-crossing square wave through the third voltage sensor 65 may be the same as graphs C11 and C12.

Commercial power frequency and zero-crossing square wave through the third current sensing sensor 66 may be the same as graphs C21 and C22.

4 is a diagram for explaining a method of determining whether to reclose an RTU, a recloser, and a server according to an embodiment of the present invention.

It will be described with reference to FIGS. 1, 3, and 4 together.

For example, when a break occurs in the power line in the first section between the first recloser 31 and the first switch 41, the first switch installed in the first switch 41 is installed to accurately find out whether the power line in the first section is broken. 1RTU 51 can be used.

The first RTU 51 uses the circuit A1, A2, B1, B2, C1, C2 for detecting a voltage from the power line PL1 connected to the first switch 41. The zero crossing time of the signal detected from the circuit can be detected.

The graph 71 is a graph of the signal detected by the first RTU 51 and shows a normal three-phase frequency waveform.

The graph 72 is a graph of the signal detected by the first RTU 51 and shows a frequency waveform when a phase B disconnection occurs. At this time, it can be seen that, unlike the graph 71 , no zero crossing is detected in the graph 72 for the B phase.

The graph 73 is a graph of the signal detected by the first reclosers RC1 and 31, and shows the fault waveform when the B phase disconnection occurs.

The distribution automation server 10 (hereinafter, the server) may receive an accident report indicating that an accident has occurred and a reclosing request from the first reclosers RC1 and 31 .

The server 10 may receive accident data (no zero crossing) from the first RTU 51 .

The server 10 combines the accident report received from the first recloser 31 and the accident data received from the first RTU 51 to determine whether to reclose, and transmits a command therefor to the first recloser 31 . can Alternatively, the server 10 may transmit, to the first recloser 31 , information on the presence or absence of zero crossing received from the first RTU 51 .

5 is a view for explaining an operation control method of the recloser according to an embodiment of the present invention.

In step S110 , the RTU 51 connected to the switch 41 may detect a zero crossing time of a signal detected from a circuit for detecting a voltage from a power line (eg, PL1 ) connected to the switch 41 .

In step S120 , the RTU 51 or the switch 41 may detect a break-down detection time, which is a time point at which zero crossing is not generated even though the zero crossing should occur.

If the power flowing through the wiring system is AC power and has, for example, a frequency of 60 Hz, the interval between the zero crossing points will be 1/60 = 16.7 ms. Therefore, given one zero-crossing time, it is possible to predict the next zero-crossing time. In this case, the zero-crossing time to occur next may be a break-down detection time.

The determination that the zero crossing has not occurred even though it should have occurred may be made when the zero crossing is not detected in both the voltage sensor and the current sensor of FIG. 3 .

In step S130 , the RTU 51 or the switch 41 may transmit a break-down detection time to the remote server 10 .

At this time, between the steps S120 and S130, the RTU 51 or the switch 41, the step of recording the break-down detection time may be added. The time may be determined using the GPS connected to the RTU 51 or the switch 41.

In step S140 , when the server 10 receives the break-down detection time point, the server 10 may determine that the zero crossing has not occurred even though it should occur at the corresponding time point. To this end, in step S130, when the RTU 51 or the switch 41 transmits the break-down detection time to the server 10, additional information indicating that the zero crossing has not occurred even though it should occur is included together. can send

In step S150 , the recloser 31 may detect an accident occurring in the power line PL1 of the first section.

In step S160, the recloser 31 and the server 10 communicate with each other, and the first information regarding whether an accident occurring in the power line PL1 of the first section has been detected, and the zero crossing in the switchgear 41 It is possible to determine the next operation state of the recloser 31 by using the second information on whether or not it has not occurred even though it should have occurred.

6 is a view for explaining in detail step S160 of FIG. 5 according to an embodiment of the present invention.

Step S160 may include the following steps.

In step S210, immediately after the server 10 receives the break-down detection point or immediately after the server 10 determines that the zero crossing has not occurred despite that it should have occurred, the server 10 issues a zero crossing alarm. can create

In step S220 , the server 10 may transmit a zero crossing alarm to the recloser 31 .

In step S230 , the recloser 31 detects an accident occurring on the power line in the first section, and the recloser 31 receives a zero crossing alarm from the server 10 . When the absolute value of the interval between the time points is less than a predetermined value, it is possible to determine the fact that an accident has occurred in the power line of the first section and execute a subsequent operation accordingly. For example, the subsequent operation may be that the recloser 31 continuously cuts the connection between the first feeder #1 and the power line of the first section.

In this case, the time at which the fact that the accident occurred in the power line is determined may be within a predetermined time from the detection time when the recloser 31 detects the time of occurrence of the accident occurring in the power line. The predetermined time may be three times the frequency of the AC power.

7 is a view for explaining in detail step S160 of FIG. 5 according to another embodiment of the present invention.

In the embodiment of FIG. 6 , the recloser determines the operating state of the recloser, whereas in the embodiment of FIG. 7 , the server may determine the operating state of the recloser.

Step S160 may include the following steps.

In step S310 , the recloser 31 may transmit the fact of detection of an accident occurring in the power line of the first section and the detection time point to the server 10 .

In step S320, the server 10, when the absolute value of the interval between the time when the recloser 31 detects the accident occurring on the power line in the first section and the break-down detection time is less than a predetermined value, the second The fact that an accident occurred on the power line in section 1 can be confirmed.

In this case, the time at which the fact that the accident occurred in the power line is determined may be within a predetermined time from the detection time when the recloser 31 detects the time of occurrence of the accident occurring in the power line. The predetermined time may be three times the frequency of the AC power. For example, when the frequency of the AC power is 60 Hz, one cycle may be 1/60 s, and in this case, the three cycles may be 3/60 s=50 ms.

In step S330 , the server 10 may notify the recloser 31 that the fact that an accident has occurred in the power line of the first section has been confirmed, or may transmit a specific command to the recloser 31 . . The specific command may be, for example, the recloser 31 continuously disconnecting the connection between the first feeder #1 and the power line of the first section.

When the first recloser receives from the server that the fact that an accident has occurred in the power line of the first section is confirmed, the first recloser may execute a subsequent operation accordingly. For example, the subsequent operation may be that the recloser 31 continuously cuts the connection between the first feeder #1 and the power line of the first section.

8 is a diagram showing the configuration of a power system control system provided according to an embodiment of the present invention.

The power system control system provided according to an embodiment of the present invention is an upstream power system distribution system 100 , a power system control device, and a downstream power system distribution device 150 provided according to an embodiment of the present invention ) may be included.

The power system control device may be included in the upstream power system distribution system 100, or provided separately from the upstream power system distribution system 100 and the downstream power system distribution device 150 It may be a server (distribution automation server) 10 .

The upstream power distribution system 100 and the downstream power distribution device 150 may be connected to the network 80 through a first communication channel 81 and a second communication channel 82, respectively. Also, when the server 10 participates in the power system control system, the server 10 may also access the network 80 .

The upstream power distribution system 100 may perform a function of distributing and supplying power output from the substation 20 to power lines, a function of blocking the supplied power, and a function of resupplying the cut off power.

The upstream power distribution system 100 is configured to cut off the power provided to the power line when detecting an accident waveform generated in the power line 70, and then re-supply power to the power line according to a predetermined condition. may have been In addition, when the power system control device determines not to re-supply power to the power line 70, the upstream power system distribution system 100 ignores the predetermined condition and does not re-supply power to the power line. there may be

The downstream power system distribution device 150 includes a switch 40 connected to a power line 70 connected between the upstream power distribution system 100 and the downstream power distribution device 150, the power line ( 70), the sensors 61 and 62 for detecting current or voltage, and the breakdown detection time, which is a time point at which zero crossing does not occur even though zero crossing should occur in the signal output from the sensors 61 and 62 It may include a communication unit for determining the break-down detection time to transmit to the power system control device. The communication unit may be provided integrally with the RTU 51 shown in FIG. 1 or may be a device locally connected to the RTU 51 . The sensors 61 and 62 may be for detecting a state of power supply provided through the upstream power line among the upstream power line and the downstream power line connected to the switch 40 .

And the downstream power system distribution device 150 may be configured to provide or block the AC power provided from the power line 70 to another power line connected to the downstream power system distribution device 150 .

The power system control device may include a communication unit and a processing unit.

At this time, the processing unit detects a break-down detection point, which is a point in time when zero crossing does not occur even though zero crossing of AC power flowing through the power line 70 should be issued, through the communication unit, through the communication unit, the downstream power system distribution device 150 ) may be adapted to perform the step of obtaining from. The break-down detection time may be acquired from the communication unit of the downstream power system distribution device 150 .

In addition, the processing unit, the upstream power distribution system 100 may be configured to perform the step of acquiring the fault waveform detection time point at which the fault waveform generated in the power line 70 is detected.

If the power system control device is included in the upstream power distribution system 100, the fault waveform detection time can be obtained according to the information exchange protocol in the upstream power distribution system 100.

Or, if the power system control device is a server (distribution automation server) provided separately from the upstream power system distribution system 100 and the downstream power system distribution device 150, the power system control device is The fault waveform detection time may be acquired from the upstream power distribution system 100 through the network 80 . At this time, when it is determined that the upstream power distribution system 100 re-supply the current provided to the power line 70 , the upstream power distribution system 100 provides the current provided to the power line 70 . In order to re-supply , the power system control device may provide a signal to re-supply the current provided to the power line 70 to the upstream power system distribution system 100 .

In addition, the processing unit, based on the break-down detection time and the accident waveform detection time, the upstream power distribution system 100 determines whether to re-supply power to the power line 70 to be performed. there may be

9 is a diagram showing the configuration of a power system control system provided according to another embodiment of the present invention.

The power system control system shown in FIG. 9 embodies the configuration of the upstream power system distribution system 100 among the power system control systems shown in FIG. 8 .

The upstream power distribution system 100 includes upstream power distribution devices 130 that provide, block, or resupply the AC power output from the substation 20 to the power line 70 . can do. The upstream power system distribution device 130 may be a circuit breaker (CB) or a recloser (RC, Recloser).

At this time, the upstream power system distribution device 130 determines the fault waveform detection time point, which is the time point at which the upstream power system distribution device 130 detects the fault waveform generated in the power line 70 , and the power system It may be adapted to provide a control device.

The upstream power distribution system 100 shown in FIG. 8 may mean the circuit breaker (CB, Circuit Breaker) or the recloser (RC, Recloser).

If the power system control device is included in the upstream power distribution system 100, the power system control device may be the circuit breaker (CB, Circuit Breaker) or recloser (RC, Recloser).

10 is a detailed method for determining whether the upstream power distribution system re-supply power to the power line based on the break down detection time and the accident waveform detection time according to an embodiment of the present invention. It's a timing diagram.

10 (a) shows a case in which an actual disconnection accident occurs in the power line 70, and FIG. 10 (b) shows that the power line 70 is not disconnected, for example, a broken branch touched the power line 70 briefly case is indicated.

In (a) of FIG. 10 , the upper graph 2000 shows the time point t1 at which the disconnection event of the power line 70 occurs. When the power line 70 is disconnected, the power supply to the power line 70 must be cut off, and power must not be re-supplied to the power line 70 until the physical recovery is completed.

The solid arrows shown in the middle graph 1501 in FIG. 10 (a) indicate the zero-crossing occurrence time detected in the downstream power system distribution device 150 by the power provided through the power line 70 . A dotted arrow shown in the graph 1501 in FIG. 10A indicates an initial time point t2 where zero crossing by the power provided through the power line 70 should not occur even though it should occur. Since the power line 70 is disconnected, the zero crossing does not appear immediately after the disconnection.

The solid arrow presented in the lower graph 1001 in (a) of FIG. 10 is the time point at which the power supply to the power line 70 is cut off by detecting an accident waveform from the power line 70 in the upstream power distribution system 100 (t3) is shown.

Although the power line 70 is not disconnected, the upper graph 2000 in FIG. 10B shows, for example, a time point t1 at which an event in which another object instantaneously contacts the power line 70 occurs. Since the power line 70 is not disconnected, the upstream power distribution system 100 can re-supply power to the power line 70 even if the power supply to the power line 70 is temporarily cut off.

The solid arrow presented in the middle graph 1001 in FIG. 10 (b) is the time point when the power supply to the power line 70 is cut off by detecting an accident waveform from the power line 70 in the upstream power system distribution system 100 (t3) is shown. Even if the power supply to the power line 70 is cut off by detecting the fault waveform, the power supply to the power line 70 may be re-supplied after a predetermined time has elapsed since it is not an actual disconnection. The re-supply time is not indicated in (b) of FIG. 10 .

The solid arrows shown in the lower graph 1502 in FIG. 10B indicate the zero crossing occurrence time detected in the downstream power system distribution device 150 by the power provided through the power line 70 . A dotted arrow shown in the graph 1502 in FIG. 10(b) indicates the first time point t4 in which zero crossing due to power provided through the power line 70 should not occur, even though it should occur. Although the power line 70 is not disconnected, the breakdown can be detected because the power supply to the power line 70 is stopped in the upstream power system distribution system 100 .

As shown in (a) of FIG. 10 , for example, when a disconnection event occurs near the downstream power system distribution device, the breakdown detection time t2 obtained by the downstream power distribution device 150 is the upstream power distribution system. It is ahead of the accident waveform detection time point t3 obtained in (100). In this case, the power system control device may be configured to determine not to re-supply power to the power line.

As shown in (b) of FIG. 10 , for example, if a specific event occurs, although not a disconnection, near the downstream power system distribution device, the breakdown detection time t4 obtained by the downstream power system distribution device 150 is on the upstream side. It is later than the fault waveform detection time (t3) obtained in the power distribution system 100. In this case, the power system control device may be configured to determine to re-supply power to the power line.

In order to determine the time point shown in FIG. 10, the downstream power system distribution device 150 includes a downstream GPS device used to determine the breakdown detection time point, and the upstream power system distribution system 100 includes It may include an upstream GPS device used to determine the time of detection of the accident waveform. When there is a time difference between the downstream GPS device and the upstream GPS device, a synchronization unit for synchronizing the time difference may be provided in the upstream power distribution system 100 .

11 is a flowchart illustrating a power system control method provided according to an embodiment of the present invention.

In step S410, the power system control device, the power line 70 connected between the upstream power distribution system 100 and the downstream power distribution device 150, the zero crossing of the AC power flowing through the must be issued and a break-down detection time point at which zero crossing does not occur may be acquired.

In step S420 , the power system control device may acquire the fault waveform detection time point, which is the time point at which the upstream power system distribution system detects the fault waveform generated in the power line 70 .

In step S430, the power system control device determines whether the upstream power system distribution system 100 re-supply power to the power line 70 based on the break down detection time and the accident waveform detection time. can decide

By using the above-described embodiments of the present invention, those skilled in the art will be able to easily implement various changes and modifications within the scope without departing from the essential characteristics of the present invention. The content of each claim in the claims may be combined with other claims without reference within the scope that can be understood through this specification.

Claims (14)

Although the power system control device should issue zero crossing of AC power flowing in the power line 70 connected between the upstream power system distribution system 100 and the downstream power system distribution device 150, zero crossing does not occur. acquiring a break-down detection time point that is not a time point;
acquiring, by the power system control device, the fault waveform detection time point, which is the time point at which the upstream power system distribution system detects the fault waveform generated in the power line (70); and
determining, by the power system control device, whether to re-supply power to the power line 70 by the upstream power system distribution system 100 based on the break down detection time and the accident waveform detection time;
containing,
Power system control method. The power system control method according to claim 1, wherein when the break-down detection time is earlier than the accident waveform detection time, the power system control device determines not to re-supply power to the power line. . The power system control method according to claim 1, wherein when the break-down detection time is later than the fault waveform detection time, the power system control device determines to re-supply power to the power line. According to claim 1,
The upstream power distribution system 100 is configured to provide or block the AC power output from the substation to the power line 70,
The downstream power system distribution device 150 is configured to provide or block the AC power provided from the power line 70 to another power line connected to the downstream power system distribution device 150, and
The upstream power distribution system 100 is configured to cut off the power provided to the power line when detecting an accident waveform generated in the power line 70, and then re-supply power to the power line according to a predetermined condition supposed to do,
Power system control method. 5. The method of claim 4, wherein when the power system control device determines not to re-supply power to the power line (70), the upstream power distribution system (100) ignores the predetermined condition and supplies power to the power line. Power system control method, characterized in that it is not re-supplied. According to claim 1,
The upstream power distribution system 100 is configured to provide or block the AC power output from the substation to the power line 70,
The upstream power system distribution device 130, which is a device for providing, blocking, or resupplying the AC power output from the substation among the upstream power system distribution system 100 to the power line 70, is a circuit breaker (CB, Circuit). Breaker) or recloser (RC, Recloser), and
The upstream power system distribution device 130 determines the fault waveform detection time point, which is the point at which the upstream power system distribution device 130 detects the fault waveform generated in the power line 70 , and the power system control device characterized in that it is intended to be provided to
Power system control method. According to claim 1,
The downstream power system distribution device 150,
a switch connected to the power line (70);
a sensor for detecting a current or voltage from the power line (70); and
a communication unit configured to determine a break-down detection time point, which is a time point at which zero crossing does not occur despite zero crossing to be generated in the signal output from the sensor, and transmit the break-down detection time point to the power system control device;
characterized in that it comprises,
Power system control method. According to claim 1,
The upstream power distribution system 100 is configured to provide or block the AC power output from the substation to the power line 70, and
The power system control device is an upstream power system distribution device 130, which is a device that provides or blocks the AC power output from the substation among the upstream power system distribution system 100 to the power line 70. characterized,
Power system control method. According to claim 1,
The upstream power distribution system 100 is configured to provide or block the AC power output from the substation to the power line 70, and
The power system control device is an upstream power system distribution device 130, which is a device for providing or blocking the AC power output from the substation among the upstream power system distribution system 100 to the power line 70, and the characterized in that it is a server 10 that exists separately from the downstream power system distribution device 150,
Power system control method. The power line (70) of claim 9, wherein when it is determined that the upstream power distribution system (100) re-supply the current provided to the power line (70), the upstream power distribution system (100) is connected to the power line (70) In order to re-supply the current provided to A power system control method. According to claim 1,
The downstream power system distribution device 150 includes a downstream GPS device used to determine the break-down detection time,
The upstream power distribution system 100 includes an upstream GPS device used to determine the time of detection of the accident waveform,
Power system control method. As a power system control device,
It includes a communication unit and a processing unit,
The processing unit,
Breakdown detection, which is a point in time when zero crossings do not occur despite zero crossing of AC power flowing in the power line 70 connected between the upstream power distribution system 100 and the downstream power distribution device 150 should be issued acquiring a viewpoint through the communication unit;
the upstream power distribution system performs the step of acquiring the fault waveform detection time point, which is the time point at which the fault waveform generated in the power line 70 is detected; And
The upstream power distribution system 100 determines whether to re-supply power to the power line 70 based on the breakdown detection time and the accident waveform detection time,
power system control device. 13. The method of claim 12,
The processing unit,
When the break-down detection time is later than the accident waveform detection time, the power system control device determines to re-supply power to the power line, and
When the break-down detection time is earlier than the accident waveform detection time, the power system control device is configured to determine not to re-supply power to the power line,
Power system control method. The power system control device according to claim 12 or 13; and
downstream power system distribution device;
includes,
The downstream power system distribution device,
a switch connected to the power line 70;
a sensor for detecting a current or voltage from the power line 70, and
A communication unit that determines a break-down detection time point, which is a point in time when zero crossing does not occur despite the need to generate zero crossing in the signal output from the sensor, and transmits the break-down detection time to the power system control device;
containing,
power system control system.

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