RU2324208C1 - Seismograph calibration techique - Google Patents

Abstract

FIELD: measuring techniques.

SUBSTANCE: proposed seismograph calibration method is based on artificially stimulating oscillations of the pendulum of the seismograph to be calibrated and taking readings from a register. These readings are used to determine calibration characteristics of the seismograph, namely amplitude-frequency response of the seismograph. The exciting force is applied to the frame of the seismograph through vibrating electrostrictive material mounted between bearing adjustment screws and a pedestal, on the opposite sides of which are mounted capacitor plates. Frequency of oscillation of the electrostrictive material is given through stimulating a given value of the electrostatic field of the given capacitor. Amplitude frequency response of the seismograph is determined using given oscillation frequency values of the electrostrictive material and the known value of its linear deformation.

EFFECT: increased accuracy in determining the form of seismograph calibration characteristics.

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Description

The invention relates to the field of measuring equipment and can be used in means for recording soil vibrations to determine their frequency response and experimental calibration.

A known generator method for calibrating a seismic channel in which the exciting force is applied not to the bed of the seismometer, but to the moving mass, carrying out the so-called force excitation, in this case it is necessary to find the ratio between the applied force and the corresponding fictitious displacement of the bed of the seismometer. Schematic diagram of the generator calibration method is shown in figure 1. The fictitious acceleration of the base of the translational-type seismometer with force excitation is equal to the ratio of the applied force to the inert mass, while the force displacement of the pendulum of the seismometer having an electromechanical transducer is produced by an electric oscillator (for example, a sinusoidal current), which is switched on either to the attenuation coil or to the calibration coil . A low-frequency generator 2 is connected to one of the coils of the seismometer (for example, damping) 1, and a large decoupling resistance 3 is turned on between the generator and the seismometer so that the attenuation of the seismometer does not change. The value of the generator signal is selected so as to obtain readable amplitudes on the record, and, knowing the amplitude value of the generator signal for a specific period and the values of the included resistances in the circuit (working coil of the seismometer 4, galvanometer frame 5, shunt resistance 6, additional resistances 7, 8, 9 , reference galvanometer 10, external resistance of the damping coil 11), we determine the value of the current strength and the magnitude of the current, and also according to the data of the seismometer coil we determine the value of the fictitious displacement of the bed of the seismometer a [1, 2].

The disadvantage of this method is that the exciting force is applied to the moving mass, and not to the bed (base), as a result of which we obtain a fictitious acceleration of the base of the seismometer, and not real. In addition, in the transition from acceleration to the magnitude of the displacement itself, it is necessary to apply double integration, which leads to additional errors. For these reasons, the accuracy of determining the frequency response of a seismograph is low and the shape of the amplitude-frequency response is not fully true.

The objective of the invention is to develop a method for calibrating a seismograph that allows you to apply exciting force with the required amplitude and frequency directly to the frame of the seismometer, which will provide a technical result, which consists in increasing the accuracy of determining the shape of the amplitude-frequency characteristics.

This technical result in the proposed method, depicted in figure 2, is achieved by the fact that the exciter bed 1 is applied directly to the bed through the set screws 2 by introducing between the thrust bearings of the set screws 3 and pedestal 4 of the electrostrictive material 5. This material, for example, a ferroelectric relaxor ( ferroceramics) is a solid dielectric that deforms in a certain linear direction (for vertical seismometers - in the vertical, for horizontal - in the horizontal flax, respectively, in the north-south and west-east directions) when an electric field is applied to it. The sign of electrostrictive deformation (i.e., the dielectric sample expands or contracts under the influence of the field) does not depend on the direction of the field, and in an alternating electric field of frequency f, the dielectric is deformed with a frequency of 2f. An electric field can be created, for example, using two plates of the capacitor 6 located on opposite sides of the electrostrictive material 5. By controlling the charging and discharging of the capacitor 6, it is possible to achieve the desired vibration effect of the electrostrictive material 5, the oscillations of which are naturally transmitted to the frame of the seismometer. The advantages of electrostrictive converters are high sensitivity, high accuracy of mechanical displacement, uniform frequency response and low level of intrinsic noise, as well as a low temperature dependence of the properties (sensitivity, resonance frequency, electrical impedance, etc.). In addition, the amplitude and frequency of oscillations of the electrostrictive material 5 correspond to the values of real seismic vibrations of the soil. Setting the frequency of oscillations of the material 5 using the electric field of the capacitor 6 and knowing the value of its linear deformation from the passport data, the readings are taken from the register and the frequency response is compiled from them. If in the generator method the magnitude of the signal of the generator may be unknown and the form of the frequency response is obtained, that is, a relative increase in the seismic channel depending on the period, then in the proposed method it is possible to obtain an absolute increase in the entire seismograph and, accordingly, its more accurate amplitude-frequency response.

A comparative analysis with the prototype showed that the claimed invention, due to the application of exciting force with the required amplitude and frequency directly to the bed of the seismometer, allows to obtain a technical result consisting in increasing the accuracy of determining the shape of the amplitude-frequency characteristics of the seismograph, which was not possible in the prototype.

Therefore, the technical solution meets the criterion of "novelty."

In addition, since the claimed technical result is achieved by introducing the totality of essential features that are not found in the well-known patent and scientific literature at the filing date of the application, the invention meets the criterion of "inventive step."

Information sources

1. Technical description and instruction manual for the product (seismograph) K-215-C. / ILEV 416 542.001 TO, M., 1979, p. 38-40.

2. Technical description and instruction manual for the product (seismograph) K-212-C1. / DBI 2.787.006 TO, M., 1981, p. 38-39, 40-41.

Claims (1)

A method of calibrating seismographs, which consists in artificially exciting oscillations of the pendulum of the calibrated seismograph and taking readings from the register, based on which a calibration characteristic of the seismograph is compiled — the frequency response of the seismograph, characterized in that the exciting force is applied to the seismograph frame using the set screws installed between the thrust bearings and a pedestal of a vibrating electrostrictive material, on the opposite sides of which there are capacitor plates, often This oscillation of the electrostrictive material is set by excitation of a given value of the electric field of the given capacitor, and the frequency response of the seismograph is based on the specified values of the oscillation frequency of the electrostrictive material and the known value of its linear deformation.

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