KR20220069567A - Method for automatically discriminating earthquuake vibratory motion from erroneous signal record at seismic system of nuclear power plant - Google Patents

Abstract

Disclosed is a method for determining an erroneous signal of a seismic monitoring system of a nuclear power plant. The method for determining the erroneous signal of the seismic monitoring system of the nuclear power plant includes: (a) recording a signal exceeding an acceleration of gravity set in the seismic monitoring system installed in the nuclear power plant; (b) determining, after the signal of the step (a) is recorded, whether a seismic signal having a magnitude of 3.0 or more is generated within a set time range from a seismic database; (c) calculating an initial arrival time of the seismic signal transmitted from an earthquake and determined in the step (b) through a simulation, and determining whether the calculated arrival time of the seismic signal is identical to an actual arrival time of the seismic signal; (d) checking a P-wave seismic signal and an S-wave seismic signal, and determining whether the P-wave seismic signal and the S-wave seismic signal are generated with a time difference; (e) performing Fourier-transform on a waveform of the earthquake to determine whether the seismic signal is uniformly distributed within an observation frequency range; and (f) determining occurrence of the earthquake when the seismic signal having the magnitude of 3.0 or more is determined to be generated within the set time range from the seismic database in the step (b), and the steps (c) to (e) are determined. Accordingly, a power plant is safely operated.

Description

Method for detecting false signals in the earthquake monitoring system of nuclear power plants

The present invention relates to a method for determining a false signal in an earthquake monitoring system of a nuclear power plant capable of accurately detecting an earthquake signal.

In general, when a signal exceeding the gravitational acceleration set to detect an earthquake signal is detected in the earthquake monitoring system in a nuclear power plant, a seismic instrument operates to record the signal, and an alarm is generated according to the signal to warn of the risk of an earthquake. do.

However, the seismic monitoring system is different from the purpose of the seismic monitoring system to monitor earthquake motion caused by earthquakes. Signals exceeding the gravitational acceleration can be frequently detected.

Therefore, there is a problem in that the operation of a nuclear power plant may be confused by a malfunctioning earthquake warning due to a mechanical or electrical malfunction of an earthquake measuring device that is not caused by an earthquake, or noise caused by peripheral devices or human factors.

An embodiment of the present invention is to provide a method for determining a false signal in an earthquake monitoring system of a nuclear power plant that enables accurate detection of an earthquake signal and thus does not cause confusion in the operation of a nuclear power plant due to the false signal.

An embodiment of the present invention, (a) recording the signal exceeding the gravitational acceleration set in the earthquake monitoring system installed in the nuclear power plant, (b) after the signal of step (a) is recorded. Checking whether an earthquake signal with a magnitude of 3.0 or greater occurs in the time range set from the earthquake database, and (c) calculating the first arrival time of the earthquake signal transmitted from the earthquake confirmed in step (b) through simulation, , checking whether the arrival time of the calculated seismic signal matches the arrival time of the actual seismic signal, (d) checking the P-wave seismic signal and the S-wave seismic signal, (e) confirming whether the earthquake signal is uniformly distributed in the observed frequency range by Fourier transforming the waveform of the earthquake; (f) the earthquake data in step (b) It is checked whether an earthquake signal with a magnitude of 3.0 or greater is generated in the time range set from the base, and when steps (c) to (e) are confirmed, it includes the step of confirming that an earthquake occurs.

Step (a) may include alerting a signal greater than 0.01 g (1 g=9.81 m/s ² ).

The set time of step (b) may be a time between 30 minutes prior to the generation of a signal exceeding 0.01g (1g=9.81m/s ² ) of step (a).

In step (d), Hilbert Transform or STA/LTA (Short Term Average/Long Term Average) may be used.

The observation frequency of step (e) may be a broadband signal of 0.01 Hz to 50 Hz.

According to an embodiment of the present invention, when a signal of 0.01 g (1 g = 9.81 m/s ² ) is detected in the earthquake monitoring system of a nuclear power plant, mechanical or electrical malfunction of the seismic measurement equipment or the It is possible to clearly confirm whether a signal exceeding 0.01 g is generated by noise or whether a signal exceeding 0.01 g is generated by the occurrence of an actual earthquake. Accordingly, when a signal exceeding 0.01g is detected, if it is not an earthquake-induced earthquake signal, there is no need to cause unnecessary confusion to the operation of the nuclear power plant. can

1 is a flowchart schematically illustrating a method for determining a false signal in an earthquake monitoring system of a nuclear power plant according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and the same reference numerals are given to the same or similar components throughout the specification.

1 is a flowchart schematically illustrating a method for determining a false signal in an earthquake monitoring system of a nuclear power plant according to an embodiment of the present invention. Hereinafter, a method for discriminating false signals in the earthquake monitoring system of a nuclear power plant will be described in detail.

First, a signal exceeding the gravitational acceleration set in the earthquake monitoring system installed in the nuclear power plant is recorded (S10).

The gravitational acceleration set in step (S10) is 0.01g (1g=9.81m/s ² ), and step (S10) is to record a signal from the seismometer installed in the earthquake monitoring system installed in the nuclear power plant, 0.01g (1g= If a signal exceeding 9.81 m/s ² ) is generated, the signal can be recorded.

In step (S10), when a signal exceeding 0.01g (1g=9.81m/s ² ) is generated, it is also possible to record the signal and notify it through an alarm or the like.

Next, after the signal of step (S10) is recorded. It is checked whether an earthquake signal with a magnitude of 3.0 or greater is generated in the time range set from the earthquake database 10 (S20).

Step (S20) is to measure seismic signals outside the nuclear power plant, check the real-time earthquake records measured at places that can measure seismic signals such as the Meteorological Agency and the UGC outside the nuclear power plant, and check the occurrence of earthquake signals with a magnitude of 3.0 or greater. can be checked

Step (S20) is to check whether an earthquake of magnitude 3.0 or greater has occurred in the time range 30 minutes prior to the time when a signal exceeding 0.01g (1g=9.81m/s ² ) was recorded using the earthquake database 10 can

That is, real-time seismic records measured by the Korea Meteorological Agency, the Geological Survey Bureau, etc. outside the nuclear power plant are stored in the seismic database 10 , and it is possible to check whether an earthquake has occurred by checking the records in the seismic database 10 .

After the step (S20), it can be checked whether or not more than 5 minutes have elapsed after the generation time of the signal exceeding 0.01 g (S21). This takes into account the periodic update time of the database.

Therefore, step (S20, S21) exceeds 0.01 g without an earthquake with a magnitude of 3.0 or greater in the time range 30 minutes before the time when a signal exceeding 0.01 g (1 g = 9.81 m/s ² ) was recorded. If more than 5 minutes have passed since the occurrence of one signal, it can be confirmed that it is not an earthquake signal.

Next, the initial arrival time of the earthquake signal transmitted from the earthquake confirmed in step (S20) is calculated and estimated through simulation (S30), and it is checked whether the arrival time of the calculated earthquake signal matches the arrival time of the actual earthquake signal (S40).

In step (S30), the simulation of the initial arrival time of the earthquake signal transmitted from the earthquake can be calculated and estimated using a computer.

And, in step (S40), it can be checked whether the initial arrival time of the earthquake signal transmitted from the earthquake calculated by the computer in step (S30) matches the arrival time of the actual earthquake signal.

If the initial arrival time of the earthquake signal transmitted from the earthquake calculated by the computer in step (S40) does not match the arrival time of the actual earthquake signal, it may be confirmed that the earthquake signal is not.

Next, the P-wave earthquake signal and the S-wave earthquake signal are checked, and it is checked whether the P-wave earthquake signal and the S-wave earthquake signal occur with a time difference (S50).

In step S50, it may be confirmed whether the P-wave seismic signal and the S-wave seismic signal are generated with a time difference using Hilbert Transform or STA/LTA (Short Term Average/Long Term Average).

Here, the Hilbert transform is a time domain signal transformation method that rotates the phase by -90 degrees, and STA/LTA (Short Term Average/Long Term Average) is the average amplitude for a short time and the average amplitude for a long time. means using the ratio of the average amplitudes of

If the P-wave seismic signal and the S-wave seismic signal do not occur with a time difference in step (S50), it may be confirmed that the seismic signal is not.

Next, a Fourier transform is performed on the earthquake waveform (S60), and it is confirmed that the earthquake signal is uniformly distributed in the observed frequency range (S70).

In step (S70), the observation frequency is a broadband signal of 0.01 Hz to 50 Hz, and the earthquake waveform is Fourier transformed, and it can be checked whether the Fourier-transformed signal is evenly distributed in the wideband signal of 0.01 Hz to 50 Hz.

Here, when the Fourier-transformed signal is not confirmed in the range of a wideband signal of 0.01 Hz to 50 Hz, it can be confirmed that the signal is not an earthquake signal.

Next, in the state in which an earthquake signal with a magnitude of 3.0 or greater is generated in step (S20), if steps (S40), (S50), and (S70) are confirmed together, it is confirmed as an earthquake (S80).

That is, step (S80) includes steps (S40) and (S50) in the state where an earthquake with a magnitude of 3.0 or greater occurred in the time range 30 minutes before the time when a signal exceeding 0.01g (1g=9.81m/s ² ) was recorded. ) and (S70) are confirmed together, it can be confirmed as an earthquake.

As such, when a signal of 0.01g (1g=9.81m/s ² ) is detected in the earthquake monitoring system of a nuclear power plant, It is possible to clearly confirm whether an excessive signal is generated or whether a signal exceeding 0.01 g is generated due to the occurrence of an actual earthquake.

Therefore, when a signal exceeding 0.01g is detected, if it is not an earthquake-induced earthquake signal, there is no need to cause unnecessary confusion in the operation of the nuclear power plant. can

Although preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and it is possible to carry out various modifications within the scope of the claims, the detailed description of the invention, and the accompanying drawings, and this also It is natural to fall within the scope of

10...Earthquake database

Claims (5)

(a) recording a signal exceeding the gravitational acceleration set in the earthquake monitoring system installed in the nuclear power plant;
(b) after the signal of step (a) is recorded. checking whether an earthquake signal with a magnitude of 3.0 or greater is generated in a time range set from an earthquake database;
(c) calculating the initial arrival time of the earthquake signal transmitted from the earthquake confirmed in step (b) through simulation, and checking whether the calculated arrival time of the earthquake signal matches the arrival time of the actual earthquake signal;
(d) confirming the P-wave seismic signal and the S-wave seismic signal, and determining whether the P-wave seismic signal and the S-wave seismic signal occur with a time difference;
(e) confirming a uniform distribution state of the earthquake signal in an observation frequency range by Fourier transforming the earthquake waveform; and
(f) confirming whether an earthquake signal with a magnitude of 3.0 or greater is generated in the time range set from the earthquake database in step (b), and confirming that an earthquake occurs when steps (c) to (e) are confirmed ;
Including, a method for detecting false signals in the earthquake monitoring system of a nuclear power plant. According to claim 1,
The gravitational acceleration set in the step (a) is 0.01 g (1 g = 9.81 m/s ² ), and includes alarming a signal exceeding 0.01 g (1 g = 9.81 m/s ² ), nuclear power plant A method for detecting false signals in the earthquake monitoring system. 3. The method of claim 2,
The set time of the step (b) is a time between 30 minutes before the signal generation exceeding 0.01g (1g=9.81m/s ² ) of the step (a), the earthquake monitoring system false signal determination method of a nuclear power plant . 4. The method of claim 3,
In the step (d), a method for determining a false signal in an earthquake monitoring system of a nuclear power plant using Hilbert Transform or STA/LTA (Short Term Average/Long Term Average). 4. The method of claim 3,
The observation frequency of step (e) is a broadband signal of 0.01 Hz to 50 Hz, a method for determining an earthquake monitoring system erroneous signal of a nuclear power plant.

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