RU2639558C2 - Method of pulse inductive geo-electrical exploration and device for its implementation - Google Patents

Abstract

FIELD: electricity.SUBSTANCE: method includes the placement of transmitting and measuring loops, a periodic feeding from the current pulse generator to the input of the loop and periodically, in pauses between pulses, recording the induced EMF in the measuring loop, presenting the pulse width of the generated current, measuring the current pulse value and recording the ratio of the induced EMF value to the measured value of the current, the accumulation in time of the indicated ratios and the calculation of the average value of the ratio by the number of points chosen on the decay curve. The software determines the step size of the time sampling on the decay curve for at least one microsecond, and for each chosen point recorded by the results of 2measurements of the average value of the ratio of the induced EMF to the measured value of the GC at the time before the switching off of the pulse of this current, where n is selected from 0 to 8. The device contains a light and sound board, batteries, a microprocessor, a PSU, a docking port, a switchboard, amplifiers, an ADC, a current pulse generator, a voltage meter on the battery, a transmitting loop, a measuring loop, a power key, a current measuring unit in the transmitter loop.EFFECT: increase accuracy and reliability of measurement results.4 cl, 3 dwg

Description

The present invention relates to the field of electrical exploration, and in particular to methods of electromagnetic sounding by the formation of a field in the near field, and can be used to assess changes in gas saturation of the gas storage object and the upper superproductive section.

There is a known method of geoelectrical exploration and a device for its implementation, in which a stationary generator circuit (GC) and a smaller measuring circuit (IR) system are located inside the horizontal well path for the duration of the development of highly viscous oil and bitumen. Each IR through a switch is connected to a registrar equipped with a delay time control device. During the registration of the electromotive force (EMF) in the IR, time delays are determined, on which, against the background of signals recorded simultaneously by all IR, a contrast increase in the induced EMF is observed, which corresponds to the signal from the metal casing of the well. Bind EMF on the selected delays to the path of passage. Based on the constructed dependence of the longitudinal conductivity (S) on the depth (h), the dependences of S on h are calculated on other IRs. They determine the power and depth of the reservoir. From the measured EMF for the studied formation, the apparent electrical resistivity (ρ _k ) is determined and the apparent bitumen saturation coefficient is calculated for each measurement cycle (US Pat. RF No. 2560997, G01V 3/08, published on 08.20.2015).

A device for implementing the known method consists of a pulse generator, generator and measuring circuits, a switch and a registrar, while the generator circuit is stationary above the path of horizontal wells, and inside it is stationary a system of measuring circuits of a smaller size, with each measuring circuit connected through a switch to a recorder equipped with a device for adjusting the delay time.

The known method is intended for periodically recording the current state of electrical conductivity of the rock in depth in the monitoring mode to monitor the dynamics of extraction of high viscosity oil and bitumen with reference to the profile of horizontal wells and solves the problem of express control of the dynamics of extraction of high viscosity oil and bitumen along the profile of horizontal wells in real time scale and timely adjustment of the coolant injection mode into the well bore, as well as the selection mode in the wellbore.

A device for geoelectro-sounding is known, with the help of which a periodic supply of current pulses from the pulse generator to the input of the generator circuit is carried out and periodically, in the intervals between pulses, the induced EMF is recorded in the measuring circuit, the pulse width of the generating current is preset, the value of the generating current pulse is measured, and the ratio the value of the induced EMF to the measured value of the generating current, the accumulation in time of the indicated relations and the calculation of the average The values of this ratio of the number of points selected in the measured signal decay curve (auth. svid. 1,637,547, G01V 3/10, Prior., the 02/02/1989 "DSP").

The known device comprises: a generator, a programmable control and registration unit, the first control output of which is connected to the control input of the generator, a generator circuit, the input of which is connected to the main output of the generator, a receiving circuit and a meter containing an amplifier and an analog-to-digital converter connected in series, an information output and the control input of which is connected to the information input and control output of the programmable control and registration unit, respectively, when it extra generator output is connected to a reference input of a measuring instrument, an information input coupled to an output of the receiving circuit.

A disadvantage of the known devices is as follows.

As a result of using the known devices, an insufficient amount of information taken from the decline curve is obtained due to the small number of discrete values selected on the decline curve, which leads to a decrease in the differentiation of the section during the final processing of the received information. In addition, due to the limited number of readings taken at a later time on the decline curve, a low reliability of the measurement results arises, which leads to a decrease in the depth of the studied object.

The task of the claimed group of inventions is to increase the accuracy and reliability of the measurement results while increasing the depth of the investigated object.

This problem is solved by the fact that in the method of pulsed inductive geoelectrical exploration, which includes placing the generator and measuring loops on the earth's surface above the geological object under study, periodically supplying current pulses from the pulse generator to the input of the generator loop and periodically, in the intervals between pulses, registering the induced EMF in the measurement circuit, pre-setting the pulse width of the generated current, measuring the magnitude of the pulse of the generated current and registering the value of the induced EMF to the measured value of the generated current, the accumulation of the indicated ratios over time and the calculation of the average value of the indicated ratio over the number of points selected on the decay curve of the measured signal, in contrast to the known one, programmatically set the sampling step on the decay curve of at least one microsecond, and for each selected point, according to the results of 2 ⁿ measurements, the average value of the ratio of the induced emf to the measured value of the generated current is recorded at the time before switching off the impulse of the current, where n is selected from 0 to 8.

In addition, the ratio of the induced EMF to the measured value of the generated current is integrated for each time value on the decay curve at late times by calculating the average value of the specified ratio in the vicinity of the selected time value based on the results of 2 ⁿ additional discrete measurements in increments from 1 microsecond to 4.6 microseconds where n is selected from 0 to 8.

The measurement time range of the measured signals is set from 3 microsecons to 1000 milliseconds.

This problem is solved by the fact that in the inventive device of pulsed inductive geoelectrical exploration, containing a current pulse generator, generator and measuring circuits installed on the earth's surface of the studied geological object, a programmable control unit for recording the measured signals with a permanently recording device, a signal meter, including a cascade of amplifiers, a switch and an analog-to-digital converter - an ADC, a power key for supplying generator pulses, in contrast to the known one, rer, ADC and power key provided with individual power supplies.

In FIG. 1 presents a block diagram of the inventive device.

In FIG. 2 is a diagram of the recording of current pulses J in time t, where I-II denotes the decay curve of the measured signal.

In FIG. 3 shows the decline curve of the measured signal with a highlighted area at late times - A ₁ -A ₂ .

To assess the change in gas saturation of the gas storage facility and the upper section of the near-wellbore space in order to detect in this space in real time accumulations of hydrocarbon gases associated with a leak in the well or the roof of the gas storage facility, it is necessary to monitor these changes over the entire gas storage area, for which a system of generator and measuring circuits on the earth's surface above the studied geological object and is carried out in the monitor mode ringa receiving signals from the measuring circuit.

The method used for sensing the formation of a field in the near field is based on measuring the emf of transients in ungrounded measuring circuits located above the geological object under study, while passing current pulses along the generator circuit. A feature of the method is the control of the nature of the late stage on the decline curve of the recorded signal characterizing the longitudinal conductivity of the object. In the late stage of the transition process, the influence of deeper conducting horizons is manifested (V. Sidorov. Pulse Inductive Electrical Exploration - M., Nedra, 1985, p. 14).

The inventive method of pulsed inductive geoelectrical exploration includes placing the generator and measuring loops on the earth's surface above the geological object under study, periodically supplying current pulses from the pulse generator to the input of the generator loop and periodically, in the intervals between pulses, registering the induced EMF in the measuring loop. Before the measurement, the duration of the generated current pulses is pre-set, during the measurements, the generated current pulse is measured and the ratio of the induced EMF to the measured generated current is recorded, the indicated ratios are accumulated over time and the average value of the indicated ratio is calculated by the number of points selected on the decay curve measured signal.

At the same time, the value of the sampling step on the decline curve of at least one microsecond is programmed, for each selected point, the average value of the ratio of the induced emf to the measured value of the generated current is recorded according to the results of 2 ⁿ measurements, where n is selected from 0 to 8.

The number n is selected depending on the intended measurement accuracy to be achieved. The larger n, the more accurate the measurement result.

The method provides for the possibility of integrating the ratios of the induced EMF to the measured value of the generated current for each time value on the decay curve at late times by calculating the average value of the specified ratio in the vicinity of the selected time value based on the results of 2 ⁿ additional discrete measurements in steps of 1 microsecond to 4.6 microseconds where n is selected from 0 to 8.

Thus, on the decline curve in late times, 2 ⁿ measurements are additionally performed for a more accurate result of the measured signal on the measuring circuit.

The measurement time range of the measured signals is set from 3 microsecons to 1000 milliseconds.

The implementation of the proposed method is carried out in the process of working with the proposed device.

The device contains generator 1 and measuring 2 circuits installed on the earth's surface of the geological object under study, a programmable control unit for recording the measured signals — a microprocessor 3 with a constantly recording device — ROM 4, a signal meter including a cascade of amplifiers 5, a switch 6, and an analog-to-digital converter - ADC 7, power switch 8 for supplying pulses to the current generator 9, while the cascade of amplifiers 5, ADC 7 and power switch 8 are equipped with individual power supplies - batteries 10, 11, 12, respectively etstvenno. The microprocessor 3 through the connection port 13 is connected to the computer 14. Pos. 15 - light panel, pos. 16 - sound scoreboard displaying the measurement results. Pos. 17 - battery voltage meter 12. Pos. 18 - unit for measuring current in the generator loop (Fig. 1).

Separate power supply provided for the power part (power switch), analog part (amplifier cascade), digital part (ADC), eliminates the mutual influence of nodes on the power supply from each other, which positively affects the accuracy of measurements.

As a programmable control unit and registration of the measured signals, a high-performance microprocessor from Microchip operating at a frequency of 20 MHz was selected with an integrated memory unit.

In the memory of a programmable control unit and registration of measured signals with a constantly recording device - the microprocessor records the number of measurements at a time - 2 ⁿ . The microprocessor contains memory cells containing 96 measurements at all points selected on the time decline curve and additional points selected at late times.

The microprocessor 3 issues a command to the ADC 7, which performs 2 ⁿ measurements, the values of these measurements are accumulated in the microprocessor's memory and the arithmetic mean value of the emf is calculated for each selected point on the decline curve. At the same time, the values of the generated current measured by block 18 at the time before the current was turned off (point “B” of the current pulse in Fig. 2) in the generator circuit 1 are written to the microprocessor in parallel, which makes it possible to more accurately measure the generated current. The indicated time is also set in the microprocessor memory. After the completion of the measurement cycle from the microprocessor memory, the obtained EMF values and the measured generated current are stored in ROM 4 and simultaneously output to port 13 on computer 14. Using the program, the ratios of the accumulated average EMF values to the measured generated current are determined. The results obtained are used in accordance with a known method for calculating the conductivity of a geological object depending on depth.

The microprocessor 3 contains an arithmetic-logical device - ALU (integrator), which summarizes the digital values of the measured signal and calculates the arithmetic mean values in the vicinity of each point, which transfers to ROM 4.

In addition, the program embedded in the microprocessor provides for the possibility of integrating the ratios of the induced EMF to the measured value of the generated current for each time value on the decay curve in late times by calculating the average value of this ratio in the vicinity of the selected time value according to the results of 2 ⁿ measurements, where n is chosen from 0 to 8 additional discrete values in increments of 1 microsecond to 4.6 microseconds. Thus, on the decline curve in late times, 2 ⁿ measurements are additionally performed for a more accurate result of the measured signal (Fig. 3).

By increasing the reliability of measurements at a later time, when using the integrator, an increase in the depth of measurements with constant dimensions of the measuring circuit is achieved.

Claims (4)

1. The method of pulsed inductive geoelectrical exploration, including placing the generator and measuring loops on the earth's surface above the geological object under study, periodically supplying current pulses from the pulse generator to the input of the generator loop and periodically, in the intervals between pulses, registering the induced EMF in the measuring loop, presetting the duration pulses of the generated current, measuring the magnitude of the pulse of the generated current and recording the ratio of the induced EMF to value of the generated current, the accumulation of the indicated relations in time and calculation of the average value of the indicated ratio by the number of points selected on the decline curve of the measured signal, characterized in that the sampling step on the decline curve is set at least one microsecond programmatically, and for each selected point the average value of the ratio of induced EMF to the measured value of the generated current according to the results of 2 ⁿ measurements, where n is selected from 0 to 8. 2. The method of pulsed inductive geoelectrical exploration according to claim 1, characterized in that they integrate the ratios of the induced emf to the measured value of the generated current for each time value on the decline curve at late times by calculating the average value of this ratio in the vicinity of the selected time value according to the results of 2 ⁿ additional discrete measurements in increments of 1 microsecond to 4.6 microseconds, where n is selected from 0 to 8. 3. The method of pulsed inductive geoelectrical exploration according to claim 1, characterized in that the measurement time range of the measured signals is set from 3 microseconds to 1000 milliseconds. 4. A pulsed inductive geoelectrical exploration device containing a current pulse generator, generator and measuring circuits installed on the earth's surface of the geological object under study, a programmable control unit for recording measured signals with a permanently recording device, a signal meter, including a cascade of amplifiers, a switch and an analog-to-digital converter , power switch for generating pulses of a generator, characterized in that the cascade of amplifiers, analog-to-digital converter and power to Uche provided with individual power supplies.

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