SU1536332A1 - Apparatus for testing seismometers - Google Patents

Abstract

The invention relates to seismometry, namely, to devices for determining the metrological characteristics of seismometric equipment. The purpose of the invention is to improve the accuracy of determining the characteristics of seismometers. The device contains a shaker mounted on the foundation, on the moving system of which a vibrometer and a seismometer under test are installed, as well as a measuring unit. A second seismometer, having a calibration coil and installed on the foundation, is inserted in the device so that its measuring axis coincides with the direction of the vibrations reproduced by the vibration stand, the first and second correction units and the summation unit, while the output of the second seismometer is connected to the input of the first correction unit whose output is connected to the first input of the summation unit, the second input of which is connected to the output of the first seismometer, and the output to the input of the measuring unit, the input of the second correction unit is connected to the output of the vibrometer, and output - with the calibration coil input of the second seismometer. 1 il.

Description

The invention relates to seismometry, namely, devices for determining the metrological characteristics of seismometric equipment.

The purpose of the invention is to improve the accuracy of determining the characteristics of seismometers.

The drawing shows a block diagram of a device for testing seismometers.

The device comprises a vibrostand 1 fixed on the foundation 2, the vibrostand 1 (the first one) and the vibrometer 4, the measurement unit 5, the second seismometer 6, the first correction unit 7, the summation unit 8 and the second correction unit 9 are installed on the vibrostand 1, the second input 9 the seismometer 6 is connected to the input of the first correction unit 7, the output of which is connected to the first input of the summation unit 8, the second input of which is connected to the output of the first seismometer 3 and the output to the input of the measurement unit 5, the input of the second correction unit 9 is connected to the output of the vibrometer and 4, and an output coupled to an input of the second coil calibration seismometer 6. In this test the first and second 3 seismometer seismometer 6 mounted on the base should be the same type. The second seismometer 6 is installed on the foundation 2

so that its axis coincides with the direction of reproducible oscillations.

The device works as follows.

The test seismometer 3 mounted on the shaker table 1 converts into an electrical signal both the oscillations set by the shaker and the random oscillations of the foundation 2 caused by microseismic movements of the earth's surface. The second seismometer 6, which has characteristics identical to those of the test seismometer 3, converts only the oscillations of the foundation into an electrical signal. The signal from the second seismometer 6 passes through the correction block 7, which changes the spectrum of the signal caused by random vibrations of the foundation, in the same way as the vibrostand 1 changes the spectrum of these random vibrations when transmitting them from the foundation 2 to the tested seismometer 3. In block 8 summation occurs compensation of signals caused by microseismic oscillations of the foundation and passed along different paths: from the foundation through the shaker and the tested seismometer or through the second seismometer and correction unit. Thus, the output from the summation unit to the measurement unit comes from the tested seismometer, generated only by the movement of the shaker. The circuit containing the vibration meter 4 and the second correction unit 9 serves to compensate for the rotational and translational movements of the Foundation and the base of the vibration stand with the oscillation frequency of the moving system of the vibration stand caused by the nonideality of the latter. The signal from the vibrometer k, carrying information about the frequency and amplitude of oscillations of the moving system of the vibrostand, passes through the second correction unit 9, enters the calibration coil of the second seismometer 6. This causes the oscillation of the second seismometer to return to the unit summation, where the compensation of parasitic movements of the foundation and the foundation of the vibrostand measured by the tested seismometer occurs.

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Thus, to improve the accuracy of seismometer testing, two noise compensation loops were introduced. The first circuit, containing the second seismometer 6, the first correction block 7 and the summation block 8, is designed to compensate for random seismic noise transmitted from the foundation 2 via the vibrator 1 to the tested seismometer 3. The first correction block is designed to compensate for phase shifts and non-uniformity of amplitude-frequency characteristics vibrating tables.

The second circuit containing the vibrometer, the second correction unit 9 and the calibration coil of the second seismometer 6 is designed to compensate for the movements of the foundation with the oscillation frequency of the moving system. These movements, which are caused by the reaction of the foundation to the movements of the moving system of the shaker, are proportional to the amplitude of movement of the moving system and the square of the frequency.

Claims (1)

Invention Formula A device for testing seismometers, containing a shaker mounted on a foundation, on a moving system of which a vibrometer and a tested seismometer are installed, as well as a measuring unit, characterized in that, in order to improve the accuracy of determining the characteristics of seismometers, a second seismometer having a calibration coil and installed on the foundation so that its measuring axis coincides with the direction of the vibrations reproduced by the vibrostand, the first and second correction blocks and the summation block, with the output The second seismometer is connected to the input of the first correction unit, the output of which is connected to the first input of the summation unit, the second input of which is connected to the output of the first seismometer, and the output is connected to the input of the measuring unit, the input of the second correction unit is connected to the output of the vibrometer, and the output is connected to the input of the coil calibration of the second seismometer. ////////, x ////////