SU934419A1 - Electric well-logging device - Google Patents

Description

one

The invention relates to the field of downhole geophysical research and can be used in engineering surveys in the construction of hydraulic structures, for recording electrical and temperature parameters of the soil, when working in hard-to-reach areas.

A device is known in which a current switch is connected in series with mechanical contacts connected between current electrodes and. contactless type semiconductor control elements 11.

However, this device has little efficiency.

Closest to what is proposed is an electrical logging device that includes a power source, a voltage converter, a rectifier, a smoothing filter, current control devices, a set of control shunts, a polarization compensator, a control antiphase voltage generator, a current switch, and measuring and current electrodes, a measuring voltage converter, a recorder and a smoothing signal filter .. The device may also contain a driver current regulator and galvanic blocks CBA linker 2.

The drawbacks of such a device are low efficiency (due to the large amount of operations required when processing the results of experimental data), as well as the impossibility of measuring the temperature parameters.

This problem can be solved only by automating the process of processing experimental data on the use of computer equipment. For this, it is necessary to record the obtained information in a form suitable for entering into a computer at the most

20 Affordable and cheap media, which is impossible when using these devices ..

Claims (1)

The purpose of the invention is to expand the functionality of the device, increase its efficiency by using a data recording unit in a form that allows the use of computer technology to process the results of experimental data, which reduces the time and cost of research. The goal is achieved by the fact that a device for electrical, logging, containing voltage stabilizer, generator of control antiphase voltage, two galvanic isolation units, protecting current stabilizer, current switch, current electrodes, measurement electrodes, connected with a polarization compensator, which is connected in series with the voltage measuring transducer and a smoothing filter, and a recorder, with the first output of the voltage regulator connected to the master stabilizer m of the circuit, the second with the generator of controlling antiphase voltages, the output of the master current regulator is connected to the input of the current switch, the outputs of which are connected to current electrodes, two outputs of the generator of controlling antiphase voltages are connected to blocks of galvanic isolation, the first outputs of which connected to a current switch, and the latter to a voltage measuring converter; a DC amplifier, a voltage integrator, a key element, a generator of two stabilizers are additionally introduced At first frequencies, the pulse former is the first, second and third triggers, the logic element I and the second recorder, the input of the DC amplifier is connected to the output of the smoothing filter, and the first output of the DC amplifier is connected to the input of the first recorder. to the input of the voltage integrator, which is connected via a key element to the third output of the voltage regulator, the output of the voltage integrator is connected to the D input of the first trigger, the C input of which is connected to the high-frequency output generator and two stable frequencies, the Q-output of the first trigger is connected to the first input of the AND logic element, and the Q-output with the control input of the key element, the low-frequency output of the generator of two stable frequencies connected to the input of the pulse former and the R-input of the second trigger, and the input a generator of two stable frequencies is connected to the 5-output of the third trigger, the Q-output of which is connected to the second input of the logic element. The R input of the third trigger is connected to the output of the pulse former, and the C input is the device input, the output of the AND element one with a C-input of the second flip-flop, whose output is coupled to the input of the second recorder. The drawing shows a block diagram of a device for electrical logging. Voltage stabilizer 1 is connected to a master stabilizer 2 currents and generator 3 controlling antiphase voltages. The output of the master current regulator 2 through the current switch 4 is connected to the current electrodes 5. Two generator outputs of the 3 antiphase voltages are connected via galvanic isolating blocks b and 7 with the current switch 4 and the voltage measuring transducer 8. The measuring electrodes 9 are connected via a polarization compensator 10 to a voltage measuring transducer 8, the output of which is connected through a constant voltage amplifier 12 to the inputs of the first recorder 13 and the voltage integrator 14 via a smoothing filter 11. A voltage stabilizer 1 is also connected to the input of the voltage integrator 14 via the key element 15. The output of the voltage integrator 14 is connected to the D input of the first trigger 16, the C input of which is connected to the high frequency output of the generator 17 of two stable frequencies, the low frequency output of which is connected to the R input of the second trigger 18 and through the pulse former 19 to the R input of the third trigger 20.. O-entry of the first trigger 16 is connected to the first input of the element And 21, the other input of which is connected to the Q-output of the third trigger 20, and the output to the C-terminal of the second trigger 18, in which the Q-output is connected to the input of the second recorder 212. Q - the output of the first trigger 16 is connected to the control input of the key element. The Q-output of the third trigger 20 is connected to the generator input 17 of two stable frequencies. C-input of the third trigger 20 is connected to the source of the signal Impulse depth. The electrical logging device is fed through a voltage stabilizer 1 from an external voltage source of 15-30 V. The device operates as follows. The stabilized voltage through the setting current regulator 2 is switched by the current switch 4 and supplied to the current electrodes 5. The alternating voltage from the measuring electrodes 9 through the polarization compensator} 0 is fed to the voltage measuring converter 8, from the output of which the DC voltage is removed, smoothed by the filter 11, and fed further to the input of the constant voltage amplifier 12. The operation of the current switch 4 and the voltage converter 8 is carried out by the voltages taken from the generator 3 of the control antiphase voltages and supplied through blocks 6 and 7 of galvanic isolation to the current switch 4 and the voltage converter 8. From the output of the constant voltage amplifier 12, the amplified signal is fed to the inputs of the first recorder 13 and the voltage integrator 14. From the output of the voltage integrator 14, a slowly increasing voltage, the rate of increase of which is determined by the magnitude of the input voltage, is fed to the D input of the first trigger 16, to the C input of which is fed a high frequency signal from the generator 17 of two stable frequencies synchronizing the first trigger 16. The trigger 16 at a certain level of voltage on the D-input, changes its state and opens the key element 15 with a signal that turns on its Q-output, through which a stabilized voltage is connected to the input of the integrator 14 The voltage from the stabilizer 1 is the voltage of the polarity opposite to the voltage removed from the amplifier 12 by a constant voltage. In this case, the voltage at the output of the voltage integrator 14 drops sharply to the level at which the first trigger 16 returns to the initial state, the signal at its Q output is removed and the key element 15 closes, disconnecting the voltage stabilizer 1 from the input of the integrator 14. Thus, at the outputs of the first trigger 16, a sequence of pulses occurs, the frequency of which linearly depends on the value of the voltage at the input of the voltage integrator 14, i.e. on the value of the registered parameter. From the Q-output of the first trigger 16, a pulse arrives also at one of the inputs of the element I 21 and passes to its output only when at its second input there appears a signal from the Q-output of the third trigger 20, which is set only when entering its C-input signal Impulse depth from an external source. At the same time, from the 5-output of the third trigger 20, the signal is applied to the R input of the generator 17 of two stable frequencies, which after 1 s allow the pulse to pass from the low frequency output of the generator 17 of two stable frequencies to the input of the driver 19 of the pulses and the R input of the second trigger 18. A pulse from the low-frequency output of the generator 17 of two stable frequencies, the duration of which is determined by the driver of the 19 pulses, the third trigger 20 at the R input, returns to its previous state and waits for the next depth pulse to arrive. Thus, the pulses from the output of the first trigger 16 will pass through the element AND 21 only for 1 from the moment of arrival of the depth pulse from an external source. The second trigger 18, the C input of which is connected to the output of the element 21, converts a pulse signal into an alternating rectangular shape recorded on a magnetic tape of the second recorder 22. The pulse frequency is selected in the working frequency range of the second recorder 22. Recording is performed only at time points , determined by the arrival of pulses from the depth sensor, which makes it possible to record the depth at which measurements are made in the well, subject to the unidirectional uniform motion of the probe in the well. A second dosing of the signal at the output of the And element allows one to eliminate the registration error caused by the unevenness of the magnetic tape passing through the recorder 22.. The use of the proposed device allows, by reducing the number of service personnel, to increase the efficiency of using the equipment and to a large extent solves the problem of reducing labor costs for conducting research due to the possibility of directly using computational techniques for processing the experimental data obtained. An electric logging device comprising a voltage stabilizer, an antiphase control generator, two galvanic isolation units, a current regulator setting, a current switch, current electrodes, measurement electrodes connected to a polarization compensator, which is connected in series with a measuring transducer. - voltage and a smoothing filter, and a recorder, with the first output of the voltage regulator connected to the master current regulator, the second - with a generator of control antiphase voltages, the output of a master current regulator is connected to the input of a current switch, the outputs of which are connected to