SU623170A1 - Measuring apparatus for geoelectric survey - Google Patents

Description

(54) MEASURING DEVICE FOR GEOELECTRIC EXPLORATION

Claims (2)

The invention relates to measuring devices for geoelectroprospecting, used in electromagnetic sounding according to the method of becoming a field in the near field. Measuring devices for detecting a field becoming are known, consisting of a receiving sensor, a measuring amplifier and a recorder for measuring transients with relatively low signal change rates 1. The closest technical solution to the invention is a measuring device for detecting a becoming field in the near zone consisting of a receiving sensor, an amplifier with an adjustable gain factor, and a recorder 2. The signal to become a field arriving at the receiving one the sensor is amplified by a measuring amplifier and recorded, for example, by a loop oscilloscope. When measuring the first derivative of the magnetic induction in the near zone, the signal becomes within fractions of a second from several tens of millivolts (in some cases and tens of volts) to several microvolts. Measuring equipment with a large dynamic range is required to register a pOD signal. At present, it is difficult to build such an apparatus; therefore, usually the field formation is recorded by repeated measurements at different gain factors. The measurement accuracy is insufficient, since the rate of change of the signal is high. The aim of the invention is to reduce the dynamic range of the recorded signal, improving the measurement accuracy. The goal is achieved by the fact that a device for compensating the measured signal is inserted into the measuring device, the input of which is connected in parallel to the receiving sensor, and the output is connected to the resistance, which, in turn, is connected in series between the output of the sensor and the input of the amplifier. A device for compensating the measured signal consists of a series-connected matching stage, a pulse amplifier, a key, a pulse generator, and an amplitude controller, and a discriminator is switched on between the output of the pulse amplifier and the control input of the amplitude controller. The drawing shows a structural diagram of the proposed measuring device. The device consists of a receiving sensor 1, a measuring amplifier 2, a recorder 3, a high-resistance matching stage 4, a pulse amplifier 5, a key 6., a pulse generator 7, an amplitude controller 8, a discriminator 9 and a resistance 10. The matching stage 4 is connected to the outputs of sensor 1 parallel to the inputs of the measuring amplifier 2. The pulse generator 7 is connected in series with the sensor 1 through the amplitude regulator 8 to the input of the measuring amplifier 2. The matching cascade, the pulse amplifier and the switch are in series Full functions of the synchronizer. The device works as follows. The impulse of the magnetic field is differentiated and through the matching cascade 4 is fed to the pulse amplifier 5, where it is amplified to the magnitude necessary for the discriminator 9 and the key 6 to work. in form to the impulse of the field. The impulse from the generator output of the impulses through the amplitude regulator 8 and the low-impedance resistance 10, connected in series with the sensor, goes in antiphase with the impulse becoming to the input of the measuring amplifier 2. As a result of summing these impulses, a difference signal with a small dynamic range. This makes it possible to use an amplifier with a small dimming range and a larger gain, which improves the measurement accuracy. The amplitude regulator 8 is designed to set the optimal value of the compensation signal, the parameters of which are chosen so that the difference signal at the input of the measuring apparatus does not exceed its dynamic range. To automatically set the required value of the compensation signal between the pulse amplifier 5 and the amplitude adjuster 8, a multistage discriminator 9 is activated. Depending on the amplitude of the becoming signal, the multistage discriminator adjusts the magnitude of the compensation signal. Claim I. Measuring device for geoelectromagnetic, containing sequentially connected receiver, measuring amplifier and recorder, characterized in that, in order to reduce the dynamic range of the measured signal and improve the accuracy of measurements, a device for compensating the measured signal is added to the block diagram whose input is connected in parallel to the receiving sensor, and the output is connected to the resistance, which, in turn, is connected in series between the output of the sensor and Hodo .m amplifier. 2. A measuring device according to claim 1, characterized in that the device for compensating the measured signal consists of a series of matching cascade, a pulse amplifier, a key, a pulse generator and an amplitude controller, and between the output of the pulse amplifier and the amplitude regulator control input discriminator is enabled. Sources of information taken into account in the examination: 1. Ban L. L., Bobrovnikov L. 3. Electrical prospecting by the method of becoming a magnetic field. M., Gosgeoltekhizdat, 1963. with. 55-78. 2. Sidorov V. A., Tikshaev V. V. Electrointelligence by sounding the formation of a floor in the near zone. Inf. Post NVNIIGG, Saratov, 1969.