KR100869018B1 - Cause of break down analyzing apparatus for electric power system and method thereof - Google Patents

Abstract

The present invention is not only an arbitrary digital protection relay monitoring the power system in which the failure occurs when a failure occurs in the power system monitored by any of the digital protection relays installed in the distribution panel. The remaining digital protection relays that monitor other power systems that have not failed can also save the drive waveform at the time of failure, thereby facilitating analysis of the failure of the failed power system and the cause of the failure. An apparatus and method for analyzing the cause of failure of a system.

The failure cause analysis apparatus of the power system of the present invention includes first to n-th digital protection relays; One of the first to n-th digital protection relays connected to each of the first to n-th digital protection relays and commonly connected to one (-) differential signal line and one (+) differential signal line. Is outputted to the one (-) differential signal line and the one (+) differential signal line, and the output of the one or more differential signal lines and the one (+) differential signal line. First to n-th failure synchronization signal input / output units for inputting the failure synchronization signal generated by any digital protection relay to the remaining first to n-th digital protection relays; When the fault synchronization signal is input to the first to n-th digital protection relays, the driving waveform is stored in synchronization with the fault synchronization signal. And first to nth reservoirs.

Description

{Cause of break down analyzing apparatus for electric power system and method}

1 is a view schematically showing an apparatus for analyzing a cause of failure of a power system according to an exemplary embodiment of the present invention.

2 is a view illustrating in detail the failure detection signal input and output unit in FIG.

<Explanation of symbols for the main parts of the drawings>

10 ₁ to 10 _n : digital protective relays

20 ₁ to 20 _n : fault synchronization signal input / output units

21 ₁ to 21 _n : first to nth output drivers

22 ₁ to 22 _n : first to n th input receivers

23 ₁ to 23 _n : first to n th output control signal lines

24 ₁ to 24 _n : first to n th input control signal lines

25 ₁ to 25 _n : first to nth failure synchronization signal output transmission lines

26 ₁ to 26 _n : first to n th fault synchronization signal input transmission lines

27 ₁₁ to 27 _1n : first output lines of the first to n-th output drivers

27 ₂₁ to 27 _2n : second output lines of the first to nth output drivers

28 ₁₁ to 28 _1n : first output lines of the first to nth input receivers

28 ₂₁ to 28 _2n : second output lines of the first to nth input receivers

30 ₁ to 30 _n : storage parts

The present invention relates to an apparatus and method for analyzing the cause of failure of a power system, and in particular, when a failure occurs in a power system monitored by any digital protection relay among digital protection relays installed in a power distribution panel. In addition to any digital protection relay monitoring the corresponding power system, the remaining digital protection relays monitoring the other power system that have not failed can also save the drive waveform at the time of the failure. The present invention relates to a failure cause analysis device and a method of a power system that can facilitate analysis and analysis of a cause of a failure.

The conventional system of failure cause analysis of a power system is a digital protection system that monitors a power system in which a failure occurs when a power system that any digital protection relay of the digital protection relays installed in the power distribution panel is monitored. Only the relay stores the drive waveform at the time of failure. In addition, the conventional failure cause analysis system of the power system analyzes the failure of the corresponding power system and the failure of the corresponding power system using the driving waveform at the time of the failure stored by the digital protection relay monitoring the corresponding power system where the failure has occurred. Analyze the cause of the problem.

Therefore, the conventional system of failure cause analysis of a power system is a digital system that monitors a corresponding power system in which a failure occurs when a power system that any digital protection relay among the digital protection relays installed in the power distribution panel is monitored. Only protective relays store the drive waveform at the time of failure. Accordingly, the conventional system of failure analysis of a power system has a disadvantage in that it is not possible to know at all how the digital protection relays that monitor other power systems that have not failed are affected at the time of failure by the failed power system. have.

In particular, the conventional failure cause analysis system of a power system transmits a signal indicating that a failure has occurred in an arbitrary power system to digital protection relays that monitor a power system that does not have a failure. If a fault occurs, the digital protection relay installed in the power system of the upper end of the digital protection relay to cut off the fault section transmits a signal that a fault has occurred in an arbitrary power system and blocks the fault section. Only the digital protective relay installed in the power system above the digital protective relay that needs to block the section stores the drive waveform at the time of failure. In this case, the conventional failure cause analysis system of the power system is a digital protection relay installed in the power system of the upper stage of the faulty power system rather than the driving waveform at the time of the accident stored by the digital protection relay that monitors the faulty power system. It is difficult to know in which power system a fault has occurred by using the fault drive waveform stored in the system. In addition, the conventional power system failure cause analysis system uses a drive waveform at the time of failure stored by a digital protection relay installed in a power system above the failed power system even if it knows which power system has failed. As a result of analyzing the cause of the failure of the generated power system, there are many difficulties in analyzing the cause of the failure of the generated power system.

Accordingly, an object of the present invention is to provide an arbitrary digital monitoring system for a power system in which a failure occurs when a failure occurs in a power system monitored by any digital protection relay among digital protection relays installed in a distribution board. In addition to the protective relays, the remaining digital protective relays that monitor other power systems that have not failed can also store the drive waveform at the time of failure, making it easier to analyze the cause of the failed power system and the cause of the failure. The present invention provides an apparatus and method for analyzing a cause of failure of a power system.

In order to achieve the above object, the failure cause analysis device of the power system according to an embodiment of the present invention and the first to n-th digital protection relay; One of the first to n-th digital protection relays connected to each of the first to n-th digital protection relays and commonly connected to one (-) differential signal line and one (+) differential signal line. Is outputted to the one (-) differential signal line and the one (+) differential signal line, and the output of the one or more differential signal lines and the one (+) differential signal line. First to n-th failure synchronization signal input / output units for inputting the failure synchronization signal generated by any digital protection relay to the remaining first to n-th digital protection relays; When the fault synchronization signal is input to each of the first to nth digital protection relays, the fault synchronization signal is input in synchronization with the fault synchronization signal input. First to nth storage units configured to store driving waveforms of the first to nth digital protection relays based on a time point at which the first to nth digital protection relays are stored; first through n-th output drivers for receiving the fault synchronization signal generated by the arbitrary digital protection relay among the n digital protection relays and outputting the one differential signal line and the one differential signal line; ; First through n-th input receivers which receive the fault synchronization signal generated by the arbitrary digital protection relay from the positive differential signal line and the negative differential signal line and input the first to nth digital protection relays; do.

According to an embodiment of the present disclosure, a method of analyzing a cause of failure of a power system may include monitoring the arbitrary digital protection relay when a failure occurs in the power system monitored by any of the first to nth digital protection relays. Generating a failure synchronization signal indicating that a failure has occurred in the corresponding power system; (+) Commonly connected to the first to nth digital protection relays through the output driver of the failure detection signal input / output unit connected to the arbitrary digital protection relay, the fault synchronization signal generated by the arbitrary digital protection relay; Transmitting to a differential signal line and a negative differential signal line and an input receiver of a fault detection signal input / output unit connected to said arbitrary digital protective relay; Inputting the failure synchronization signal to the arbitrary digital protection relay through the input receiver of the failure detection signal input / output unit connected to the arbitrary digital protection relay; The digital protection relay storing the driving waveforms of the digital protection relays based on a time point at which the failure synchronization signal is input to a storage provided therein when the failure protection signal is input; The fault synchronization signal is transmitted from the positive differential signal line and the negative differential signal line to the first to nth input receivers of the first to nth fault detection signal input / output units connected to the first to nth digital protection relays. Becoming a step; Inputting the fault synchronization signal from the first to nth input receivers of the first to nth digital protection relays to the first to nth digital protection relays; The first to n-th digital protection relays to which the failure synchronization signal is input are based on a time point at which the failure synchronization signal is input to respective storage units provided in synchronization with the failure synchronization signal. n storing drive waveforms of the digital protective relays.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 1 and 2.

1 is a view showing a failure cause analysis device of a power system according to an embodiment of the present invention.

Referring to FIG. 1, an apparatus for analyzing a cause of failure of a power system according to an exemplary embodiment of the present invention may include first to nth digital protection relays 10 ₁ to 10 _n and first to nth digital protection relays 10. ₁ to 10 _n ) first to n-th failure synchronization signal input / output units 20 ₁ to _{1 which} are connected to each of them and are commonly connected to one (-) differential signal line and commonly connected to one (+) differential signal line. 20 _n ) and _first to _n- th storage units 30 ₁ to 30 _{n in} each of the first to n-th digital protection relays 10 ₁ to 10 _n .

When the first to n th digital protection relays 10 ₁ to 10 _n have a failure in the power system being monitored, the first to n-th digital protection relays 10 ₁ to 10 _n generate a fault synchronization signal indicating that a failure has occurred in the power system being monitored. Output to the fault synchronization signal input and output unit (20 ₁ to 20 _n ), and stores the drive waveform at the time of failure detection in the corresponding storage unit (30 ₁ to 30 _n ) provided therein. Then, the monitor and the power system has not occurred a fault the first to the n digital protective relay to which (10 ₁ to 10 _n) is monitored, and a fault in the power system has occurred any digital protective relay (10 ₁ to which Receives a failure synchronization signal generated by any one of 10 _n through each of the first to nth failure synchronization signal input / output units 20 ₁ to 20 _n , and is provided in synchronization with the input failure synchronization signal. The driving waveform at the time of the failure occurrence signal is stored in the first to nth storage units 30 ₁ to 30 _n .

The first to n-th failure synchronization signal input / output units 20 ₁ to 20 _n each of the first to n-th digital protection relays 10 ₁ to 10 _n from each of the first to n-th digital protection relays 10 ₁ to 10 _n . _{When a} signal indicating that a fault has occurred is input to the power system monitored by ₁ to 10 _n ), the fault synchronization signal is connected to one positively connected differential signal line and one negatively connected differential signal line in common. Outputs Then, the first to n-th fault synchronizing signal input and output portions (20 ₁ to 20 _n) is broken synchronization signal (any one of 10 ₁ to 10 _n), and any of the digital protective relay fault in the power system has occurred in monitoring occurred Are inputted from one (+) differential signal line connected in common and one (-) differential signal line connected in common, and the first to the first failures of the corresponding power system monitoring the input failure synchronization signal. n outputs to the digital protective relays 10 ₁ to 10 _n .

Described in detail the operation of the fault cause analysis apparatus of the power system of the present invention, for example, the first digital protective relay (10 ₁₎ when monitoring and fault in the power system occurs in the first digital protective relay (10 ₁ ) comprises a first storage unit (30 ₁₎ failure at the time the fault was caused by the driving waveform in the power system, which as well as monitors and stores the failure synchronizing signal of the first failure in synchronization with the signal output unit (20 ₁₎ provided in the To send. When the failure synchronization signal is input, the first failure synchronization signal input / output unit 20 ₁ outputs the failure synchronization signal to the connected (+) differential signal line and (-) differential signal line. Then, the second to nth failure synchronization signal input / output units 20 ₂ to 20 _n receive a failure synchronization signal generated by the first digital protection relay 10 ₁ through a positive differential signal line and a negative differential signal line. . When the failure synchronization signal is input, the second to nth failure synchronization signal input / output units 20 ₂ to 20 _n output the failure synchronization signal to the connected second to nth digital protection relays 10 ₂ to 10 _n . Then, the second to n-th digital protection relays 10 ₂ to 10 _n generate a failure signal to each of the second to n-th storage units 30 ₂ to 30 _n provided therein in synchronization with the input failure synchronization signal. Save the drive waveform at that time.

FIG. 2 is a diagram illustrating the failure detection signal input and output unit in detail in FIG. 1.

Referring to FIG. 2, the first to nth failure detection signal input / output units 20 ₁ to 20 _n of the present invention input a failure synchronization signal generated by the first to nth digital protection relays 10 ₁ to 10 _n . Receive fault synchronization signals from the first to nth output drivers 21 ₁ to 21 _{n that receive the} positive differential signal line and the negative differential signal line, and the positive differential signal line and the negative differential signal line. First to nth input receivers 22 ₁ to 22 _n and inputs to the first to nth digital protection relays 10 ₁ to 10 _n , and first to nth output drivers 21 ₁ to 21 _n. First to n th output control signal lines 23 ₁ to 23 _n for inputting a control signal to the first and second to n th input control signals 22 ₁ to 22 _n for inputting a control signal to the first to n th input receivers 22 ₁ to 22 _n . n input control signal lines 24 ₁ to 24 _n . In addition, the first to n th failure detection signal input / output units 20 ₁ to 20 _n of the present invention may be the first to n th digital protection relays 10 to the first to _n th output drivers 21 ₁ to 21 _n . ₁ to 10 _n ) faults input to the 1 st to n th fault sync signal output transmission lines 25 ₁ to 25 _n for transmitting fault synchronization signals generated, and to the n th input receivers 22 ₁ to 22 _n . First to nth failure synchronization signal input transmission lines 26 ₁ to 26 _n for transmitting a synchronization signal to the first to n th digital protection relays 10 ₁ to 10 _n . In addition, the first to nth failure detection signal input / output units 20 ₁ to 20 _n of the present invention may output the outputs of the first to nth output drivers 21 ₁ to 21 _n from the negative signal line and the first to _{n th} signals. First output lines 27 ₁₁ to 27 _{1n of} the first to nth output drivers for transmitting to the nth input receivers 22 ₁ to 22 _n , and first to nth output drivers 21 ₁ to 21 _n. And the second output lines 27 ₂₁ to 27 _{2n of} the first to n th output drivers for transmitting the output of the positive signal to the positive differential signal line and the first to n th input receivers 22 ₁ to 22 _n . _-First input lines 28 ₁₁ to 28 _{1n of} the first to nth input receivers receiving the differential signal line and the outputs of the first output lines 27 ₁₁ to 27 _{1n of} the first to nth output drivers, Second input lines 28 of the first to nth input receivers receiving the positive differential signal line and the outputs of the second output lines 27 ₂₁ to 27 _{2n of} the first to nth output drivers. ₂₁ to 28 _2n ).

The digital '0' signal is always supplied to the first to n th input control signal lines 24 ₁ to 24 _n . Accordingly, the nth input receivers 22 ₁ to 22 _n always fail input from the first and second input lines 28 ₁₁ to 28 _1n and 28 ₂₁ to 28 _{2n of} the first to nth input receivers. Receive the signal. On the other hand, if a fault is not detected in the monitored power system to the first to nth output control signal lines 23 ₁ to 23 _n , a digital '0' signal is supplied, and a fault is detected in the monitored power system. If the state is detected, the digital '1' signal is supplied. Therefore, when the digital '0' signal is supplied from the first to nth output control signal lines 23 ₁ to 23 _n , the first to n th output drivers 21 ₁ to 21 _n are monitored. If no fault is detected, no control occurs, and when the digital '1' signal is supplied from the first to nth output control signal lines 23 ₁ to 23 _n , that is, the power system to be monitored has failed. Is detected, the fault synchronization signal from the first to nth digital protection relays 10 ₁ to 10 _n is transmitted to the first and second output lines 27 ₁₁ to 27 _1n and 27 of the first to nth output drivers. ₂₁ to 27 _2n ).

The first to nth digital protection relays 10 ₁ to 10 _{n are} connected to the first to nth failure synchronization signal output transmission lines 25 ₁ to 25 _n when a failure is not detected in the monitored power system. Outputs a digital '1' signal. Then, the first output lines 27 ₁₁ to 27 _{1n of} the first to nth output drivers output the digital '0' signal, and the second output lines 27 ₂₁ to 27 _{2n of} the first to nth output drivers. Outputs a digital '1' signal. The digital '0' signal, which is an output of the first output lines 27 ₁₁ to 27 _{1n of} the first to nth output drivers, is a negative differential signal line and the first input lines 28 of the first to nth input receivers. ₁₁ to 28 _1n ), and the digital '1' signal, which is an output of the second output lines 27 ₂₁ to 27 _{2n of} the first to nth output drivers, is a positive differential signal line and the first to nth input receivers. Are input to the second input lines 28 ₂₁ to 28 _2n . Then, the first to n-th input receiver (22 ₁ to 21 _n) are the first to the first input lines (28 _{11 -} 28 _1n) of the n-type receiver-digital 0 is input from (or () differential signal lines) By a digital '1' signal input from the signal and the second input lines 28 ₂₁ to 28 _2n (or (+) differential signal line) of the first to nth input receivers (0-1 = -1 (digital ' 0 'signal)) Digital' 0 'signal is output. Then, the first to n-th digital protection relays 10 ₁ to 10 _n recognize that a failure is not detected in the power system by the input digital '0' signal.

Meanwhile, when the first to nth digital protection relays 10 ₁ to 10 _n detect a failure in the monitored power system, the first to nth failure synchronization signal output transmission lines 25 ₁ to 25 _n . Outputs a digital '0' signal. Then, the first output lines 27 ₁₁ to 27 _{1n of} the first to nth output drivers output the digital '1' signal, and the second output lines 27 ₂₁ to 27 _{2n of} the first to nth output drivers. Outputs a digital '0' signal. The digital '1' signal, which is an output of the first output lines 27 ₁₁ to 27 _{1n of} the first to nth output drivers, includes a _negative differential signal line and first input lines 28 of the first to nth input receivers. ₁₁ to 28 _1n ), and the digital '0' signal, which is an output of the second output lines 27 ₂₁ to 27 _{2n of} the first to nth output drivers, is a positive differential signal line and the first to nth input receivers. Are input to the second input lines 28 ₂₁ to 28 _2n . Then, the first to n-th input receiver (22 ₁ to 21 _n) are the first to the first input lines of the n input receiver (28, _{11 -} 28 _1n), - a digital input from the (or () differential signal lines), 1 By the digital '0' signal input from the signal and the second input lines 28 ₂₁ to 28 _2n (or (+) differential signal line) of the first to nth input receivers (1-0 = 1 (digital '1 'Signal)) Digital' 1 'signal is output. Then, the first to n-th digital protection relays 10 ₁ to 10 _n recognize that a failure is detected in the power system by the input digital '1' signal.

Referring to the operation of the first to n-th failure detection signal input / output units 20 ₁ to 20 _n of the present invention in detail, an error occurs in a corresponding power system monitored by the first digital protection relay 10 ₁ . The first digital protective relay 10 ₁ outputs a digital '0' signal, which is a failure synchronization signal indicating that a failure has occurred in the power system being monitored, through the first failure synchronization signal output transmission line 25 ₁ . Output to the driver 21 ₁ . When the digital '0' signal, which is a failure synchronization signal, is input to the first output driver 21 ₁ , the first output line 27 ₁₁ of the first output driver is connected to the negative differential signal line and the first input of the first input receiver. A digital '1' signal is output to the line 28 ₁₁ , and the second output line 27 ₂₁ of the first output driver is digitally connected to the positive differential signal line and the second input line 28 ₂₁ of the first input receiver. Output a '0' signal. Then, the first input receiver 22 ₁ transmits the digital '1' signal to the first failure synchronization signal input transmission line 26 ₁ . Accordingly, the first digital protection relay 10 ₁ recognizes that a failure is detected in the power system by the digital '1' signal input, and at the time of a failure occurrence signal in the first storage unit 30 ₁ provided therein. Save the drive waveform. Then, the second to n-th input receiver (22 ₂ to 21 _n) has to digital zero as the second to n-th a first input line (28, ₁₂ to 28, _1n) of the input receiver connected to the differential signal lines () A second to nth fault is received by receiving a 'signal' and receiving a digital '0' signal from the second input line 28 ₂₂ to 28 _2n of the second to nth input receivers connected to the positive differential signal line. The digital '1' signal is transmitted to the synchronization signal input transmission lines 26 ₁ to 26 _n . Then, the second to n-th digital protection relays 10 ₂ to 10 _n generate a failure signal to each of the second to n-th storage units 30 ₂ to 30 _n provided therein in synchronization with the input failure synchronization signal. Save the drive waveform at that time.

As such, the apparatus for analyzing a failure cause of a power system according to an exemplary embodiment of the present invention may be applied when a failure occurs in a power system monitored by an arbitrary digital protection relay among digital protection relays installed in a distribution panel. Any digital protection relays that are monitoring the failing power system, as well as the other digital protection relays that are monitoring other power systems that have not failed, store the drive waveform at the time of failure. Therefore, the failure cause analysis system of the power system of the present invention can easily know how the digital protection relays that monitor other power systems that do not have a failure were affected by the failure of the power system at the time of failure. Accordingly, the failure cause analysis system of the power system of the present invention can facilitate the analysis of the failure of the power system in which the failure occurs and the analysis of the cause of the failure.

The failure cause analysis device of the power system according to an embodiment of the present invention transmits a signal that a failure has occurred in an arbitrary power system to digital protection relays that monitor a power system in which a failure does not occur. In the event of a failure of a digital protective relay that must shut down, not only any digital protective relay that monitors the failed power system, but also the remaining digital protective relays that monitor other power systems that do not fail. Save the drive waveform. Therefore, the apparatus for analyzing the cause of failure of the power system of the present invention can easily identify which power system has a failure, and facilitate the analysis of the failure of the power system where the failure occurs and the analysis of the cause of the failure. Can be.

As described above, an apparatus for analyzing a cause of failure of a power system according to an exemplary embodiment of the present invention may be used when a failure occurs in a power system monitored by an arbitrary digital protection relay among digital protection relays installed in a distribution panel. In addition, any digital protection relay monitoring the power system in which the failure occurred, as well as the remaining digital protection relays monitoring the other power system in which the failure has not occurred, stores the drive waveform at the time of failure, Interpretation of the failure and the cause of the failure can be facilitated.

Claims (6)

First to nth digital protection relays; One of the first to n-th digital protection relays connected to each of the first to n-th digital protection relays and commonly connected to one (-) differential signal line and one (+) differential signal line. Is outputted to the one (-) differential signal line and the one (+) differential signal line, and the output of the one or more differential signal lines and the one (+) differential signal line. First to n-th failure synchronization signal input / output units for inputting the failure synchronization signal generated by any digital protection relay to the remaining first to n-th digital protection relays; When the fault synchronization signal is input to each of the first to nth digital protection relays, the fault synchronization signal is input in synchronization with the fault synchronization signal input. First to n-th storage unit for storing the driving waveform of the first to n-th digital protection relay on the basis of the time point, The first to n-th failure detection signal input and output unit, First through fifth outputting the fault synchronization signal generated by the arbitrary digital protection relay among the first to n-th digital protection relays to the one (+) differential signal line and the one (-) differential signal line. n output drivers; First through n-th input receivers which receive the fault synchronization signal generated by the arbitrary digital protection relay from the positive differential signal line and the negative differential signal line and input the first to nth digital protection relays; Device for failure cause analysis of the power system, characterized in that. The method according to claim 1, The first to nth digital protection relays, If a failure occurs in the monitored power system, a failure synchronization signal indicating that a failure has occurred in the monitored power system is generated and output to the connected failure synchronization signal input / output unit, and the corresponding storage provided therein. Store the driving waveforms of the first to nth digital protection relays based on a time point at which the fault synchronization signal is input to a unit; Analysis of the cause of failure of a power system, characterized in that the fault synchronization signal generated by any of the first to n th digital protection relays is generated through each of the first to n th fault synchronization signal input / output units. Device. The method according to claim 1, First output lines of the first through nth output drivers to transmit the outputs of the first through nth output drivers to the one (−) differential signal line and the first through nth input receivers; Second output lines of the first through nth output drivers for transmitting the outputs of the first through nth output drivers to the one (+) differential signal line and the first through nth input receivers; First input lines of first to n-th input receivers to receive the output of the one (−) differential signal line and the first output lines of the first to nth output drivers; And a second input line of the first to nth input receivers to receive the output of the one (+) differential signal line and the second output lines of the first to nth output drivers. Failure Cause Analysis Device. The method according to claim 1, First to n-th failure synchronization signal output transmission lines for transmitting the fault synchronization signal generated by the arbitrary digital protection relay among the first to n-th digital protection relays to the first to n-th output drivers; And first to n-th fault synchronization signal input transmission lines for transmitting the fault synchronization signal generated by the arbitrary digital protection relay input to the n-th input receivers to the first to n-th digital protection relays. Device for failure cause analysis of power system. The method according to claim 1, First to nth output control signal lines for inputting signals to the first to nth output drivers; And first to n-th input control signal lines for inputting signals to the first to n-th input receivers. If a failure occurs in the power system monitored by any of the first to nth digital protection relays, the arbitrary digital protection relay generates a failure synchronization signal indicating that a failure has occurred in the power system being monitored. Making a step; (+) Commonly connected to the first to nth digital protection relays through the output driver of the failure detection signal input / output unit connected to the arbitrary digital protection relay, the fault synchronization signal generated by the arbitrary digital protection relay; Transmitting to a differential signal line and a negative differential signal line and an input receiver of a fault detection signal input / output unit connected to said arbitrary digital protective relay; Inputting the failure synchronization signal to the arbitrary digital protection relay through the input receiver of the failure detection signal input / output unit connected to the arbitrary digital protection relay; The digital protection relay storing the driving waveform of the digital protection relay based on a time point at which the failure synchronization signal is input to a storage provided therein when the failure protection signal is input; The fault synchronization signal is transmitted from the positive differential signal line and the negative differential signal line to the first to nth input receivers of the first to nth fault detection signal input / output units connected to the first to nth digital protection relays. Becoming a step; Inputting the fault synchronization signal from the first to nth input receivers of the first to nth digital protection relays to the first to nth digital protection relays; The first to n-th digital protection relays to which the failure synchronization signal is input are based on a time point at which the failure synchronization signal is input to respective storage units provided in synchronization with the failure synchronization signal. and n storing driving waveforms of the digital protective relays.

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