RU2525149C1 - Method to measure specific electric conductivity and electric macroanisotropy of rocks - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: method is proposed to measure specific electric conductivity and electric macroanisotropy of rocks, including electromagnetic excitation of current passing along conducting surface of a metal body of a logging device, with a toroid coil. At the same time actual and imaginary components of current are measured, flowing from different sections of logging device body surface. Measurement is carried out using the specified number of coaxially arranged toroid coils, extreme of which are generator ones and are included into an electric circuit as co-phased and anti-phased, and the remaining ones are receiving. Electromagnetic excitation of current is executed in a wide range of frequencies, at the same time on each frequency they measure actual and imaginary components of the surface current density component coaxial to the logging device and electromotive force with several probes of different length. Using data of measurements, they determine spatial distribution of vertical and horizontal specific electric conductivity of the medium and coefficient of electric macroanisotropy.

EFFECT: increased accuracy of surveillance data.

7 cl, 4 dwg

Description

The invention relates to the field of geophysical research in oil and gas wells, and in particular to methods for studying the electrical properties of rocks (reservoirs) surrounding a well by electromagnetic logging.

Currently, the prior art knows a number of analogue methods used to determine electrical macroanisotropy of rocks, in particular, a method for determining the coefficient of electrical macroanisotropy during drilling "PeriScope" (Schlumberger, www.slb.com). Measurements are performed with probes, including coaxial and transverse generator coils and coaxial inclined (45 °) receiving coils. This method is used to determine the electrical conductivity (hereinafter - UEP) or its inverse value of the electrical resistivity (hereinafter - resistivity), as well as the coefficient of electrical macroanisotropy and the angle of inclination of the boundaries of the layers relative to the well.

The main disadvantages of this method for determining electrical macroanisotropy of rocks are the small values of the signals of the cross components, the strong influence of the well shape, the incompatibility of the measurements due to different resistivity averaging mechanisms for different components in thin-layered media, as well as a sharp loss in the accuracy of determining the vertical resistivity at high values of the electrical macroanisotropy coefficient .

Closest to the claimed technical solution, a method for determining the coefficient of electrical macroanisotropy of rocks (prototype) is the invention according to US Patent No. 7227363. This method is implemented as follows:

by means of a special generator create an “flow” of alternating current along the device’s body, part of which flows into the environment (the so-called “lateral current”). Then, the signal difference between the receiving toroidal coils is measured, highlighting the real and imaginary components of the side current, after which the apparent UEP is determined from each of the components. Subsequently, the electrical macroanisotropy coefficient is calculated based on the measured both values of the apparent UEP.

The disadvantages of the prototype include: the lack of the possibility of high spatial resolution due to the limited number of independent measurements; lack of multi-frequency measurements.

The technical goal (task) of the claimed invention is to eliminate the above disadvantages, and its technical result is to create a method for measuring electric conductivity and electrical macroanisotropy of rocks, providing high spatial resolution and allowing measurements of electric conductivity and electrical macroanisotropy of rocks surrounding the well.

The problem is achieved in that in the claimed technical solution, electromagnetic current excitation is carried out by a toroidal coil, the current "flows" along the conductive surface of the logging tool body, while the real and imaginary components of the current flowing from different parts of the surface of the logging tool body are measured, the measurement is carried out directly at using a given number of coaxially arranged toroidal coils, the last of which are generator and are included in the sync electrical circuit aznoe and antiphase, and the rest are receiving, the electromagnetic excitation of the current is carried out in a wide range of frequencies, while at each frequency, the real and imaginary components of both the current density component and the electromotive force coaxial to the logging tool are measured by several probes of different lengths, then, according to the measurement data, spatial distribution of vertical and horizontal UEP and coefficient of electrical macroanisotropy (the essential features of the invention distinguishing it from the prototype are highlighted in bold a). It is the above set of features that provides the invention with the claimed technical result.

The invention, in its particular cases of execution, is characterized by the features specified in the previous paragraph, in conjunction with the following:

1) Electromagnetic excitation of current is carried out by two toroidal generator coils that are switched on in the opposite direction, while in one of the compensation coils, the current magnitude changes so that the measured amplitudes of the electromotive force and surface current in one of the receiving coils located between the generator coils are are equal to zero, in this case it is possible to measure the real and imaginary components of the current of the compensation coil.

2) It is proposed to carry out electromagnetic current excitation with generator toroidal coils in the frequency range from 5 to 500 kHz.

3) Measurements are proposed to be carried out by probes in the range of lengths from 0.2 to 1.0 m.

The list of graphic drawings explaining the essence of the claimed invention:

Figure 1 - dependence of the amplitudes of the current density and emf on the resistivity of a homogeneous medium for a two-coil probe (length 0.6 m, frequency 5-500 kHz);

Figure 2 - dependence of the amplitudes of the current density and emf on the resistivity of a homogeneous medium for a two-coil probe (length 0.2-1.2 m, frequency 50 kHz);

Figure 3 - dependence of the amplitudes of the current density and emf on the horizontal electrical resistivity of a homogeneous medium (electrical anisotropy coefficient 1-4) for a two-coil probe (length 0.6 m, frequency 50 kHz);

Figure 4 - dependence of the amplitudes of the current density and emf on the coefficient of electrical anisotropy of a homogeneous medium for a two-coil probe (length 0.6 m, frequency 50 kHz).

The claimed invention is implemented as follows: an alternating electric current is supplied to the winding of the generator toroidal coils, whereby an alternating electric field is excited in the environment, penetrating to a depth sufficient for the study and having both horizontal and vertical components. Then it successively measures the electric current at the terminals of the receiving toroidal coils, the real and imaginary components of the electromotive force, the real and imaginary components of the eddy current density component parallel to the housing. After that, the spatial distribution of the horizontal and vertical UEP of the medium and the coefficient of electrical macroanisotropy are determined from the measurement data. Further, data on electrical macroanisotropy obtained from the values of electromotive force in toroidal receiving coils and surface current are compared with data on the detailed structure of a thin-layered collector in a section obtained from the values of compensation currents, which allows one to reliably establish the type of fluid saturation and the effective power of the studied collector.

The technical solution allows for two measurement modes. The first, summary mode: electromagnetic excitation of current is carried out by two generator toroidal coils, switched on in the opposite direction, while in one of the generator coils, which is compensation, the electric current is changed so that the measured amplitudes of the emf and surface current in one of the receiving coils are equal to zero. The meaning of the second differential mode is that with a stable electric current in the lower generator toroidal coil - in the upper generator coil a compensating current is set. Its value is set so that in each of the receiving coils, the measured amplitude of the emf and the surface eddy current are equal to zero.

The high spatial resolution of the electromagnetic probe with toroidal coils is due to the use of a set of frequencies and coils (frequency-geometric sounding), the use of two measurement modes (total and differential), as well as a high level of the useful signal.

Based on the numerical simulation and analysis of electromagnetic signals in homogeneous, layered-homogeneous isotropic and macroanisotropic media, a full-scale analysis of the measured signals in a given configuration of a logging tool is performed. An analysis of the sources of the measured signals showed that when a toroidal coil is excited on a metal casing, a vortex alternating electric field appears in the medium, having both horizontal and vertical components. This determines the dependence of the measured electromagnetic signals on the horizontal and vertical UEP of the formation.

Figures 1 and 2 show the dependences of the amplitudes of the current density and emf on the resistivity of a homogeneous medium for a two-coil probe (Fig. 1 — length 0.6 m, frequency 5–500 kHz; FIG. 2 — lengths 0.2–1.2 m, frequency 50 kHz).

The generator toroidal coil is located on a metal case with a radius of 0.051 m with a resistivity of 0.57 · 10 ^-9 Ohm · m Numerical simulation of the measured signals is performed provided that the product of the moments of the generator coil and the measuring sensor is equal to unity. The dependences of the amplitudes of the current density on the instrument body and the emf in the receiving toroidal coil on the resistivity of a homogeneous medium (1-200 Ohm · m) are given. The measured amplitudes of the current density and emf are characterized by a high level and have a large dynamic range. The measured signals are significantly dependent on the frequency, which indicates the predominance of frequency sounding. Moreover, with increasing frequency, the dependence of the signals on the length of the probe increases.

Figure 3 and 4 shows the dependences of the amplitudes of the current density and emf on the horizontal resistivity of a homogeneous medium (Figure 3) and the coefficient of electrical macroanisotropy of a homogeneous medium (Figure 4). The measured signals were simulated for a homogeneous macroanisotropic medium with a horizontal resistivity of 1-200 Ohm · m and an electrical macroanisotropy coefficient of 1-4 for a two-coil probe (length 0.6 m, frequency 50 kHz). The presented dependences indicate an unambiguous relationship between the measured characteristics and the coefficient of electrical macroanisotropy. The indicated dependences make it possible to create appropriate transformants of the measured characteristics to estimate the coefficient of electrical macroanisotropy.

The numerical simulation and comparative analysis of the electromagnetic characteristics show that the measurements are linearly independent and they are uniquely related to the resistivity of the formation and the coefficient of electrical macroanisotropy.

Claims (7)

1. The method of measuring the electrical conductivity and electrical macroanisotropy of rocks, in which a toroidal coil is used to electromagnetically excite a current flowing along the conductive surface of its body, measure the real and imaginary components of the current flowing from different parts of the surface of the body of the logging tool, characterized in that the measurement is carried out using a given number of coaxially arranged toroidal coils, the extreme of which are generator and included in the electric circuit in-phase and out-of-phase, and the others receiving, electromagnetic current excitation is carried out in a wide frequency range, while at each frequency the real and imaginary components of the surface current and electromotive force density components are coaxial to the logging tool with several probes of different lengths, then, according to the measurement data, spatial distribution of the vertical and horizontal electrical conductivity of the medium and the coefficient of electrical macroanisotropy. 2. The method for measuring the electrical conductivity and electrical macroanisotropy of rocks according to claim 1, characterized in that the electromagnetic excitation of the current is carried out by two toroidal generator coils, while in one of these coils, which is compensation, change the current value so that the measured amplitudes of the electromotive force and the surface current in one of the receiving toroidal coils were equal to zero. 3. The method for measuring the electrical conductivity and electrical macroanisotropy of rocks according to claim 2, characterized in that they additionally measure the real and imaginary components of the current of the compensation coil. 4. The method for measuring the electrical conductivity and electrical macroanisotropy of rocks according to claim 1, characterized in that the electromagnetic excitation of the current is carried out by two toroidal generator coils, while in one of the generator coils, which is compensation, change the current value so that the measured amplitudes of the electromotive force and the surface current in each of the receiving toroidal coils were alternately zero. 5. The method for measuring the electrical conductivity and electrical macroanisotropy of rocks according to claim 4, characterized in that it further measures the real and imaginary components of the current of the compensation coil. 6. The method for measuring the electrical conductivity and electrical macroanisotropy of rocks according to claim 1, characterized in that the electromagnetic excitation of current is carried out by generator toroidal coils in the frequency range from 5 to 500 kHz. 7. The method for measuring electrical conductivity and electrical macroanisotropy of rocks according to claim 1, characterized in that the measurements are carried out by probes in the range of lengths from 0.2 to 1 m

Images