SU1283681A1 - Method and apparatus for determining electrical microanisotropy of well area of strata - Google Patents

Abstract

The invention relates to geophysical well studies and can be used to determine the electrical microanisotropy of the wellbore zone of the formation. The purpose of the invention is to improve the accuracy of determining the electrical microanisotropy of the wellbore zone. The method and device are based on focusing the measuring current of the central electrode of the probe unit by focusing screen current electrode. At the same time, multidirectional strengths of the electric field in the medium are created by using vertically and horizontally positioned relative to the well wall of the probe installation of reverse current electrodes. Apparent resistances are measured with at least two focusing coefficients of the measuring current of 1-2 and 0.1-0.3 for each arrangement of the return electrodes. All measurements are carried out in a single pass of the probe unit over the logging interval. 2 sec. f-ly, 7 ill. i (L

Description

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The invention relates to geophysical well studies, in particular for electric micro-focusing with current focusing using ond installations mounted on an insulating base and pressed against the borehole wall.

The purpose of the invention is to increase the dispersing ability of determining the electrical microanisotropy of the near-wellbore zone of the formations.

FIG. 1 shows a block diagram of a device implementing a method; FIG. 2 shows a group of synchronous keys on magnetically controlled contacts — reed switches; FIG. 3 is the same, but on field effect transistors; FIG. 4 is a timing diagram of the operation of the device; Fig. 5 shows the layout of the probe unit and the return current 20 electrodes in the downhole tool; 6, 6 shows an example of the arrangement of vertical reverse current electrodes on a single insulating base with a probe installation; Fig, 7 - pseudogeometric factors of installations with different focusing factors

The device for determining the electrical microanisotropy of the near-well zone of the formations (FIG. 1) is intended for measurements using an autocompensation circuit of a series-time action and contains the following components: probe installation 1, task generator 2, synchronization unit 3, multiphase pulse generator 4 (1 groups of synchronous switches 5–8, input transformers 9, amplifier 10 with a high gain, phase-sensitive rectifier 11, storage capacitors 12–15, converter — increase the power 16, measure ø amplifier b, the probe installation has three electrodes - central 18, measuring 19, screen 20, remote measuring electrode 21, vertically located 22 and horizontally located 23 reverse current electrodes.

The device works as follows.

The master oscillator 2 at a frequency of 280 Hz is the source of the measuring current I

. central electrode of probe installation and reference signal for phase-sensitive rectifier and converter - power amplifier, multiphase gene2836

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Pulse racer 4, in particular, which is a four-phase multivibrator with a pulse repetition rate in each phase of 7 Hz and, therefore, with a common frequency Hz, is synchronized with the master oscillator through the KS-chain connected to the common interstage connection of the multivibrator with the expectation that This multivibrator fitted exactly 10 periods of the master oscillator. However, based on the use of the device as part of the digital systems of newly developed logging J5 stations, it is advisable to use the frequency divider on the triggers in the synchronization block, and as a multiphase pulse generator. use a binary counter with a decoder, the output of which can be obtained phase-shifted pulses, rigidly synchronized with the frequency of the master oscillator. The four phases of the output signals of the multi-25 phase generator control the keys grouped into four groups of synchronous keys 5-8 for switching circuits in four directions to four positions, 30 Figures 2 and 3 show examples of the execution of a group of synchronous keys on magnetic contacts. -. , -. It should be borne in mind that 35 each phase of a multiphase pulse generator controls (turns on) only one key corresponding to this phase, a key from each group, the reed switches are placed into coils, each having 40 the number is equal to the number of phases of the switch, and the currents of the coils, the magnetic field, which includes the reed switches, is controlled by the phase signals of the multiphase generator, the potential of the potentials formed on the electrodes of the probe unit from the measuring current I of the central electrode 18, cut input transformers 9 are fed to amplifier 10, the total gain of which, together with the increasing ratio of input transformers, is about (3-5) 10. After phase-sensitive rectification, these signals through a group of synchronous switches 5 charge storage capacitors 12 -15, to which the input of converter 50 is connected simultaneously via a group of synchronous keys

55

l - power amplifier 16, whose circuit is similar to the corresponding node in the serial equipment, side microkarotazh MBK. At the output of the converter - power amplifier, a focusing current with a frequency of the master oscillator arrives at the screen electrode, 20, and through a group of synchronous switches 8 - at the vertical and horizontal reverse current electrodes 22 and 23. Due to the large gain of the amplifier 10, the screen current Ij is automatically set to fully compensate for the potential difference from the measuring current on any pair of selected electrodes,

Thus, a sequential-time measurement is carried out by four micro-devices focusing the current with a sampling frequency of each of 7 Hz. Thanks to the use of switchable storage capacitors, in which the signal level from the previous measurement cycle of each installation is stored and testing of compensation in the subsequent cycle is necessary an increment of apparent resistances in the interval of three centimeters at a logging speed of 800 m / h, as well as synchronization, in which all switchings are made c at the instants of time when the sinusoid of the signal of the master oscillator passes through i zero and there are no transients, a sufficient speed of the device circuit is achieved in order to simultaneously perform measurements using current-focused probe settings, the number of which can reach the scale. When measuring, the measuring current I, g had a constant amplitude, and the measured value, proportional to the resistance, was the potential of electrode 19 relative to the removed electrode 21, measured by measuring amplifier 17,

Fig. 4 shows; temporary pfi-patterns of operation of the device. The ordinates 29-39 respectively show the generator frequency, the multiphase generator MGI pulses, sync pulses from the leading edges of MGI pulses, the pulse from the first phase is clockwise negative, the rest positional (channel), then the ordinate 35 is variable in amplitude in phases measuring potential the electrode 19 with respect to the remote electrode 21, which are then, after phase-sensitive rectification, are distributed in the ground-based measurement and control circuit with the help of clock pulses through the channels (phases) in which integration, they are recorded by a multi-channel recorder. The distribution of signals by channels, their processing and registration are carried out according to known schemes.

Fig. 5 shows the location of the probe unit 1 and two horizontal reverse current electrodes 23 located on the levers of a large device, and vertical electrodes 22 are located on the casing of the borehole device covered with an insulating layer. These electrodes can be placed on the same insulating base, where the installation of the probe installation 24, as shown in Fig.6, the insulation gap between the electrodes 20 and 22 can be in the range of 50-100 mm No, on the angle between the shoes.

Fig. 7 shows an example of a change in the pseudogeometric factors from the magnitude of the focusing for a probe installation (base) with a size of UOx x 200 mm, having a central electrode with a size of 34x100 mm, covered by a measuring electrode, 5 mm wide, which is divided by 5 mm in insulating gaps. Focusing was performed between electrodes 18 and 19 - the coefficient is equal to the 2nd coefficient between electrodes 19 and 20, the coefficient of 0.22. The focusing coefficient is determined by the relative change in the ratio of the currents of the -th -18 units in a homogeneous environment compared to this ratio for focusing between the electrodes 18 and 20, in which a side is produced, perceptible to the wall of the well. focusing the current beam I - and whose coefficient is taken as a unit,

Fig. 7 shows the dependences of the pseudogeometric factor g as a function of the radial direction g for two values of f / f

where fn, GSK is the electrical resistance of the near-wellbore zone and the mudcake, equal to 0.1 and 10, and for these ratios the curves .25 and 26 correspond to the focusing coefficient 0.22, and the curves 27 and 28 for the ratio 2.

From the above example, one can see a significant difference in g from focusing, as well as from the relationship between Pri.5 and Jj. i.e. depth depends on the type of penetration (turning or decreasing).

The technical and economic effect of the proposed method and device consists in increasing the geological efficiency of detecting and researching reservoirs in wells, determining their complex structure and detailing, improving the accuracy of determining the ratio of formation resistance and the washed zone used to determine mobile oil and gas saturation ratios by taking into account microanisotropy interlayers and determine the total anisotropy of reservoirs of layers, the values of which are used in the complex interpretation of geophysical data eskih issledovaniyg wells and counting reserves of deposits.

F

rmula of invention

1. A method for determining the electrical microanisotropy of the near-wellbore zone of the formations, including focusing the measuring current of the central electrode of the probe unit with the focusing current of the screen electrode, which is based on the fact that, in order to increase the resolution of determining the electrical microanisotropy of the near-wellbore zone of the formations, measurements of apparent resistances are performed consistently with the vertical and horizontal arrangement of the reverse current electrodes relative to the probe installation at least at two focusing coefficients of the measuring current equal to 1-2 and 0.1-0.3 in the time division mode, according to the dependencies of the apparent resistance on the near-wellbore zone and the size of the mudcake on the borehole wall for these focusing coefficients

finding the resistance values of the near-wellbore zone with the vertical and horizontal arrangement of the reverse current electrodes and determining the value of the electrical microanisotropy of the near-wellbore zone of the formations with respect to the values found. 2. A device for determining the electrical microanisotropy of the near-well zone of the formations, which contains a probe installation with a HtiMH mounted on it with central and screen electrodes, input transformers, controllable switches, a second generation generator, a multiphase pulse generator, a measuring amplifier, a remote electrode , wherein the outputs of the phases of the multiphase pulse generator are connected to the control inputs of the controlled switches, characterized in that, in order to increase the resolution of determining the electrical microanisot ropy borehole formation zones, the device additionally contains measuring electrodes, the measuring circuit additionally contains an amplifier, a sensitive rectifier, memory capacitors, a power amplifier converter, a synchronization unit, two reverse current electrodes, the first output of the master oscillator being connected via a synchronization unit to the multiphase the pulse generator, controlled keys are combined into four groups of synchronous keys, the second output of the master oscillator is connected to the first inputs and phase sensitive straightener

and the power amplifier converter and the third - its symmetrical output and connected to the central electrode of the probe installation and through the first group of synchronous switches to the reverse current electrodes, the input of the amplifier through the second group of synchronous switches and input transformers is connected to the electrodes of the probe installation, and its output through phase-sensitive rectifier and the third group of synchronous keys connected to memory capacitors, to which simultaneously through the fourth group of synchronous keys

A second input of a power amplifier is connected, the symmetrical output of which is connected to the reverse current electrodes through the first group of synchronous switches and

712836818

with the screen electrode of the probe device and to the remote electrode of the mounting, the input of the measuring amplifier is connected to the measuring electrode.

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Claims (3)

Claim 1. A method for determining the electrical microanisotropy of the near-wellbore zone of the strata, comprising focusing the measuring current of the central electrode of the probe installation with the focusing current of the screen electrode, characterized in that, in order to increase the resolution of determining the electrical microanisotropy of the near-wellbore zone of the strata, the apparent resistances are measured sequentially with vertical and horizontal the location of the reverse current electrodes relative to the probe installation at least at two the focusing coefficients of the measuring current, equal to 1-2 and 0.1-0.3 in the time sharing mode, according to the dependences of the apparent resistances on the resistance of the borehole zone and the size of the clay cake on the borehole wall previously built on models for these focusing factors 1283681 6 find the resistance values of the near-wellbore zone with a vertical and horizontal arrangement of reverse current electrodes and, with respect to the found values, determine the electrical microanisotropy of the near-wellbore zone of the strata. 2. A device for determining electrical microanisotropy at 10 borehole formation zones, comprising a probe installation with a central and screen electrodes mounted on it, input transformers, controlled keys, a generator, a multiphase pulse generator, a measuring amplifier, a remote electrode, and multiphase phase outputs the pulse generator is connected to the control inputs of the controlled keys, which is characterized by the fact that, in order to increase the resolution of determining the electrical microanisation Trop reservoir near-well zone device. 25 further comprises measuring electrodes, the measuring circuit further comprises an amplifier, a phase-sensitive rectifier, storage capacitors, a converter 30 a power amplifier, a synchronization unit ¹ , two reverse current electrodes, the first output of the master oscillator being connected via a synchronization unit to a multiphase pulse generator 35 , controlled keys are combined into four groups of synchronous keys, the second output of the master oscillator is connected to the first inputs of the phase-sensitive rectifier 40 and a power converter / amplifier, and the third is its balanced output and is connected to the central electrode of the probe installation and through the first group of synchronous keys to the reverse current electrodes, the input of the amplifier through the second group of synchronous keys and input transformers is connected to the electrodes of the probe installation, and its output through a phase-sensitive rectifier and a third group of synchronous keys are connected to storage capacitors, to which simultaneously through the fourth group of synchronous keys 55, the second input of the power converter / amplifier is connected, the symmetric output of which is connected to the reverse current electrodes through the first group of synchronous keys and 7 1283681 8 with the display electrode probe mouth ^- and which remote electrode under ^- Novki, to a measuring electrode of the measuring amplifier input keys. Fi.2.1 1,283,681 f / / ABOUT ------- <A> k_ J ABOUT about _ g \ /// Figure 2 / / / t VAWAAAA / VWW Figure 5