SU832500A1 - Magnetic field induction meter - Google Patents

Description

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The invention relates to a magnetometer and can be used in geophysical surveys, the search for minerals, etc.

Magnetic field strength (induction) meters (magnetometers) are known, whose action is based on Hall effects, Farad, the use of magnetic probes, etc. These magnetometers contain a transducer for the intensity (induction) of the magnetic field, c1 the electrical voltage (current), the excitation circuit, the transducer, and the further transformation of its signal, as well as the power supply circuit of these circuits 1}.

The disadvantage of magnetometers of these types is the low measurement accuracy.

Also known are magnetometers containing a magnetic field induction transducer at - the frequency of the electric current.

The closest to the proposed technical entity is a mannometer of this type, which contains an induction converter into the frequency of elec- tric current, excitation and conversion units, a discrete frequency meter, a count interval generator, and a supply voltage generator f2.

The disadvantage of this magnetometer is the large measurement error, caused by the action of the output voltage ripple, the parasitic magnetic and electric field of the power generator and the connecting wires on the induction converter,

0 blocks for further conversion of the signal from the induction converter and a frequency counter equivalent to the parasitic signal at the input of the frequency meter, since the average value of these pulsations and fields over a time equal to the counter interval is generally nonzero.

The purpose of the invention is to improve the measurement accuracy of the magnetometer.

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The goal is achieved by the fact that -In a magnetic field induction meter containing a series-connected excitation unit, a magnetic field induction converter in

5 is the frequency of the electric current, a signal conversion unit and a discrete frequency meter, to the second input of which the interval / kcpa count / oscillator is connected

0 as well as the supply voltage generator associated with the first inputs of the excitation unit and the counting interval generator, the second input of the signal converting unit and the input of the discrete frequency meter, are connected in series with a frequency multiplier and power amplifier, the first input of the frequency multiplier is connected to the second output of the generator the counting interval, and the second input to the output of the generator of the supply voltage, the input of which is connected with the output of the power amplifier.

The drawing shows the functional diagram of the proposed meter.

The meter contains a magnetic field-to-electrical frequency converter 1, an exciter unit 2, a signal conversion unit 3, a discrete frequency meter 4, a count interval generator 5, a supply voltage generator 6, a frequency multiplier 7, and a power amplifier 8.

The meter works as follows.

The electrical signal generated by: under the action of induction B from the output of converter 1, excited by block 2, is fed to conversion block 3, where it is subjected to amplification, filtering and shaping, and then; frequency counter 4, which counts the number of periods of the electrical signal for the counting interval, the duration of which is determined by the generator 5. The power supply required for operation of all the blocks is provided by the generator b, generating various DC and AC voltages from the output voltage of the power amplifier 8. From output 9, the measured induction signal is fed to the recorder.

Due to this scheme, the parasitic voltages at the input of the frequency meter 4 by acting on the pulsation induction transducer, the parasitic magnetic and electric fields of the generator b and the power cables have a period that is always an integer number less than the length of the counting interval. Accordingly, the mean value of the parasitic voltage at the input of the frequency meter 4 is zero and the latter does not change its output signal under the influence of the parasitic input voltage.

Thus, the measured value of the measured magnetic induction does not contain an error due to the influence of the specified pulsations and fields, which improves the measurement accuracy.

Claims (2)

1.Chegernikov V.I. Magnetic Measurements, 1969, p. 48-51. 2. Aero magnetometer quantum KAM-28. Technical description NPO Geophysics, 1972.