JPH1026669A - Seismograph and administration method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a seismograph itself from becoming nonfunctioning state and improve its operation rate by constituting a sensor with a plurality of sensor parts, periodically performing self test and separating and degenerating failed sensor parts. SOLUTION: A plurality of sensor parts 21 to 2n are provided as a sensor 2. The sensor parts 21 to 2n are connected in parallel to a measurement processing part. The measurement processing part calculates seismic intensity based on acceleration signal outputs from the each of the operating sensor parts 21 to 2n , outputs alarm signal and displays and records the seismic intensity. Voltage self test and current self test are performed periodically in the operating state of the seismograph to detect failures. The measurement processing part judges the existence of failure and separates the sensor parts 21 to 2n in which failures are detected from operation state and make new normal sensor parts 21 to 2n in operation state. Therefore, the maintenance and exchange of the sensor parts 21 to 2n can be done even with the operation of the seismograph and the operation rate is improved.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an earthquake measuring apparatus and a method for managing the apparatus, and more particularly to detecting an acceleration signal which is a wave at the time of an earthquake, calculating a seismic intensity, outputting a warning signal, and outputting a warning signal. And a method for managing this device.

[0002]

2. Description of the Related Art A conventional example of a seismic measuring device having only one sensor unit for detecting an earthquake wave cannot operate as a seismic measuring device when a sensor fails. When the sensor unit breaks down and the seismic measurement device goes out of operation, the failed sensor unit is replaced with a normal sensor.

[0003]

By the way, it does not mean that the sensor unit has failed. However, if the accelerometer that constitutes the sensor unit has deteriorated, it is difficult to detect this during operation of a normal seismometer. Have difficulty. Therefore, the deterioration of the sensor unit is often found by periodic inspection and calibration. However, since the seismic measuring device is in a non-operational state during the periodical inspection, the operation rate of the seismic measuring device decreases.

[0004] The present invention is to provide an earthquake measuring apparatus which solves the above-mentioned problem and a method for managing the apparatus.

[0005]

It plurality of sensor portions 2 ₁ a sensor 2 for detecting the vibration of seismic Means for Solving the Problems] comprises a 2 _n, each to 2 ₁ a plurality of sensor unit 2 _n connected in parallel The sensor unit includes a measurement processing unit 1 that calculates a seismic intensity based on an acceleration signal output from the sensor unit, outputs a warning signal, and displays and records the seismic intensity. A servo amplifying unit 5 that has an angular displacement detecting unit 4 that converts the angular displacement of the pendulum 3 into an electric signal, and that amplifies the detected electric signal into a voltage signal proportional to the input acceleration α. Force F = mα proportional to input acceleration α
And a read resistor 7 that outputs a current I that generates an electromagnetic force that returns the pendulum 3 to its original position in a balanced manner, and that converts the output current I of the torquer 6 into a DC voltage and reads it.
Test current source 8 that supplies self-test current to ToruCa 6
And a test voltage source 9 for supplying a self-test voltage to the servo amplifier 5.

The measurement processing unit 1 constitutes an earthquake measuring apparatus having a configuration in which the sensor unit in the operating state is separated from the operating state or returned to the operating state by an instruction signal. In addition, the self-test current constituted an earthquake measurement device using this as an alternating current. Here, with respect to the above-mentioned seismic measuring device, a method for applying a test current from the test current source 8 to the ToruCa 6 to perform a current self-test has been configured.

Further, in the above-described method for managing a seismic measuring device, a method for managing a seismic measuring device in which a test voltage is applied from a test voltage source 9 to a servo amplifier 5 to perform a voltage self-test is configured. In addition, the self-test is configured so that the sensor unit in the operating state is separated from the operating state by the instruction signal transmitted from the measurement processing unit 1 or the self-test is performed in the operating state.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION An earthquake measuring apparatus according to the present invention has a plurality of sensors for detecting seismic waves, calculates a seismic intensity based on an acceleration signal output from the sensor, and issues an alarm. It has a measurement processing unit that outputs signals and displays and records seismic intensity. By performing a self-test for applying simulated data to the sensor and detecting and separating the sensor unit in which an abnormality has occurred, an accurate seismic intensity calculation can be performed. Since the sensor unit in which the abnormality has occurred is separated and degenerated, maintenance and replacement of the sensor unit can be performed even while the seismic measurement device is operating, so that the operation rate of the seismic measurement device itself is improved.

[0009]

FIG. 1 shows an embodiment of an earthquake measuring apparatus according to the present invention.
It will be described in the light of the above. The earthquake measuring device of the present invention
Sensor unit 2 as sensor 2 for detecting motion ₁ Or sensor
Part 2_n Are provided. Soshi
The seismic intensity based on the acceleration signal output from the sensor 2.
Calculate and output warning signal and display and record seismic intensity
And a measurement processing unit 1. Multiple sensor units 2₁ Absent
Sensor part 2_n Is the wave of the earthquake at the time of the earthquake
Is detected and output. Measurement processing unit 1
Has a serial input / output device I / O, and has a sensor unit.
2₁ Or sensor part 2_n Receive the acceleration signal output from
Based on this, seismic intensity, maximum acceleration, earthquake occurrence time
Calculate other earthquake data. This measurement processing unit 1
In addition, I / O is applied to the earthquake data calculated for the external device.
And other devices that are active and output via
Output data.

FIG. 2 is a diagram conceptually showing an accelerometer and a detection output constituting the sensor section 2 of the earthquake measuring apparatus of the present invention. In FIG. 2, the accelerometer itself is constituted by a conventionally used one. That is, at the time of normal measurement, when an earthquake occurs and acceleration α is applied to the sensor unit 2,
The pendulum 3 having a mass m in the accelerometer constituting the sensor unit 2 swings and is angularly displaced. This angular displacement is converted into an electric signal by the angular displacement detecting section 4, and the detected signal is then converted into a servo amplifying section 5.
And a voltage signal proportional to the input acceleration α is obtained. The torquer 6 outputs a current I proportional to F = mα for returning the pendulum 3 to its original position by balancing the force due to the torquer current I and the force F proportional to the input acceleration α. This output current I of the ToruCa 6 is converted into a DC voltage via the reading resistor 7 and output, which is provided for an earthquake data measurement process. 8 is a torquer 6 when performing a current self-test.
Is a test current source that supplies a self-test current to the power supply. 9
Is the angular displacement detector 4 when performing the voltage self-test.
A test voltage source for supplying a self-test voltage to the 1
0 indicates a switch for switching the test voltage source 9. The accelerometer and the measurement processing unit 1, the test current source 8 and the test voltage source 9 are interconnected via pins 1 to 8.

The self-test method will be described with reference to FIG. 3 in addition to FIG. First, the current self-test will be described. In the current self-test, a constant self-test current is applied from the test current source 8 to the ToruCa 6. That is, the self-test current flows from the test current source 8 to the torquer 6 via the pin 2 and the resistor, flows through the read resistor 7 via the pin 1, and flows to the power return. As a result, a force proportional to the self-test current is fed back to the pendulum 3 to swing the pendulum 3. As a result, the pendulum 3 is displaced, and a DC voltage is output to the measurement processing unit 1 via the reading resistor 7. Since the current applied to the torquer 6 and the DC voltage output via the reading resistor 7 are in a proportional relationship, applying a constant current to the torquer 6 always outputs a constant DC voltage. It is measured and stored in advance as design output voltage data. Here, when a constant self-test current is applied to the torquer 6, but the DC voltage output via the read resistor 7 does not fall within the allowable range of the design output voltage data, this indicates that This means that damage, deterioration or other failure has occurred at any location. In FIG. 2, the self-test current is a DC current, but the period of the acceleration, which is the wave of the earthquake at the time of the earthquake, is usually a sine wave. Is preferably a sine wave.

Next, the voltage self test will be described. In the voltage self-test, the switch 10 is switched to apply a DC or AC self-test voltage from the test voltage source 9 to the servo amplifier 5 as simulated data. That is, the self-test voltage is supplied from the test voltage source 9 to the switch 10, the pin 7
Then, the voltage is applied to the servo amplifier 5 through the resistor and then flows to the current return via the torquer 6, the pin 1, and the read resistor 7. The reading resistor 7 outputs a DC voltage corresponding to the self-test voltage to the measurement processing unit 1. The self-test voltage and the DC output voltage generated in the reading resistor 7 are in a proportional relationship, and are measured and measured in advance as design output voltage data and stored. Here, when a constant self-test voltage is applied to the servo amplifier 5, but the DC output voltage generated in the read resistor 7 does not fall within the allowable range of the design output voltage data, this is caused by the circuit portion in the accelerometer. This means that damage, deterioration, or other failure has occurred in any portion after the servo amplifier 5.

The above-described voltage self-test and current self-test are periodically performed while the seismometer is in operation to detect a failure. Although illustration is omitted,
The measurement processing unit 1 has a configuration in which the sensor unit in the operating state is separated from the operating state or returned to the operating state by an instruction signal. At the time of the self-test, the measurement processing unit 1 simulates the self-test voltage and the self-test in the operating state of the sensor units 2 ₁ to 2 _n to be tested or in a state where the disconnection instruction signal is transmitted and disconnected. When the current is supplied, the sensor unit generates self-test data corresponding to the current and returns the self-test data to the measurement processing unit 1. The measurement processing unit 1 determines whether there is a failure based on the data.

The measurement processing unit 1 transmits an instruction signal for disconnecting the sensor unit in which the failure has been detected from the operating state, and disconnects the sensor unit. When the replacement connection to the new normal sensor unit is completed, a signal instructing return is transmitted to the new sensor unit, and the new sensor unit is returned to the operating state. The present invention, as described above, to a plurality of the sensor unit 2 ₁ as a sensor 2 for detecting the vibration of an earthquake comprising the 2 _n, in parallel with to 2 ₁ a plurality of the sensor unit 2 _n to the measurement processing unit 1 The measurement processing unit 1 calculates a seismic intensity based on an acceleration signal output from each operating sensor unit, outputs a warning signal, and displays and records the seismic intensity. Here, when the sensor 2 is composed of five sensor units, all of the five sensor units are in an operating state and output an acceleration signal to the measurement processing unit 1, and the measurement processing unit 1 It is possible to accurately calculate the seismic intensity based on the signal, output a warning signal, and display and record the seismic intensity.

If a failure is detected by performing the voltage self-test, it is possible to identify that the failure has occurred in the circuit section after the servo amplifier 5. Then, when a failure is detected by performing the current self-test and the voltage self-test is normal, it is possible to specify that the failure location is before the angular displacement detection unit 4.

[0016]

As described above, according to the present invention, a self-test is periodically performed at a predetermined time interval on a plurality of sensor units constituting a sensor of an earthquake measuring apparatus. Damage, deterioration, disconnection, and other failures of the accelerometer itself, the circuit unit, and the conductor cable constituting the sensor unit can be immediately detected, and the failure sensor unit can be separated and degenerated. Even if the faulty sensor unit is separated and degenerated, the other normal sensor units are in the operating state, so that the seismic measurement device itself does not become inactive. Therefore, by configuring the sensor with a plurality of sensor units, the reliability of the operation rate of the entire earthquake measuring apparatus is improved. Since the sensor data during the self-test is not used for the seismic intensity calculation, the self-test execution does not affect the seismic intensity output based on the output acceleration signal. can do.

[Brief description of the drawings]

FIG. 1 illustrates an embodiment.

FIG. 2 is a diagram illustrating a sensor unit according to the embodiment.

FIG. 3 is a diagram illustrating a self test.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Measurement processing part 2 ₁ to 2 _n sensor part 3 Pendulum 4 Angular displacement detection part 5 Servo amplification part 6 Toruca 7 Reading resistance 8 Test current source 9 Test voltage source

Claims (6)

[Claims] A plurality of sensor units connected in parallel to calculate a seismic intensity based on an acceleration signal output from each of the sensor units; And a measurement processing unit that outputs an alarm signal and displays and records the seismic intensity. The sensor unit has a pendulum that swings and angularly displaces when acceleration is applied, and converts the angular displacement of the pendulum into an electric signal. It has a displacement detector and has a servo amplifier that amplifies the detected electric signal to a voltage signal proportional to the input acceleration, and generates an electromagnetic force that returns the pendulum to its original position in balance with the force proportional to the input acceleration. It has a torquer that outputs current, has a read resistance that converts the torquer output current into a DC voltage and reads it, has a test current source that supplies a self-test current to the torquer, and supplies a self-test voltage to the servo amplifier. Supply Seismic measuring device, characterized in that those having a strike voltage source. 2. The earthquake measuring apparatus according to claim 1, wherein the measurement processing section has a configuration in which the sensor section in the operating state is separated from the operating state or returned to the operating state by an instruction signal. An earthquake measuring device characterized by the following. 3. The seismic measuring device according to claim 1, wherein the self-test current is an alternating current. 4. An earthquake measuring apparatus according to claim 1, wherein a current self-test is performed by applying a test current from a test current source to the ToruCa. Measurement device management method. 5. The method according to claim 4, further comprising: applying a test voltage from a test voltage source to a servo amplifier to perform a voltage self-test. Method. 6. The self-test according to claim 4, wherein the self-test activates the operating sensor unit according to an instruction signal transmitted from the measurement processing unit. Disconnect from the state,
Alternatively, the method is performed in an operating state.