RU2069878C1 - Process of electromagnetic logging of holes - Google Patents

Abstract

FIELD: mineralogy. SUBSTANCE: process is meant for determination of electric parameters of crack collectors and for orientation of horizontal axis of electric anisotropy relative to cardinal points. In accordance with method of electromagnetic logging electromagnetic field is additionally excited along axis of hole and in horizontal plane at angle of 45 deg to one of directions of excited field. Intensity of magnetic field is measured in directions along axis of hole coinciding with directions of each of excited mutually perpendicular field and in each of two directions perpendicular to excited fields and shifted through 45 deg. EFFECT: improved operational reliability of process. 1 dwg

Description

 The invention relates to field geophysics, to electromagnetic logging and can be used to determine the electrical parameters of fractured reservoirs and the orientation of the horizontal axis of electrical anisotropy relative to the cardinal points.

A known method of electromagnetic logging, which is based on the excitation in the well using a transmitting vertical coil of an electromagnetic field and measuring using a vertical receiving coil of the reactive and active components of the magnetic field [1]
There is also known a method, which is a complex of dielectric and induction logging [2] Measurement integration in this method is achieved by changing the frequency of the exciting field from a low frequency for induction logging to high for dielectric.

These methods do not allow to unambiguously determine the electrical conductivity σ _t and the electrical anisotropy coefficient λ of the reservoir intersected by a system of vertical cracks, since the measured signal is proportional to the combination of these quantities, namely, s _t / λ. Determining the direction of the horizontal axis of anisotropy by these methods is in principle impossible.

 At the same time, a method of electromagnetic logging is known, which is based on the excitation using a pair of horizontal mutually perpendicular generator coils in the rock of a harmonic high-frequency electromagnetic field, the resulting vector of which rotates at a certain frequency in the horizontal plane, without changing its amplitude, and measured using a system of two pairs of mutually perpendicular horizontal measuring coils of attenuation of this field between the points of pair location by dividing the power at these points. Changing the attenuation value depending on the orientation of the excited field makes it possible to isolate rocks with an azimuthally inhomogeneous distribution of electrical resistivity, for example, fractured reservoirs.

 However, at high resistivities, which, as a rule, characterize fractured reservoirs, this method does not allow to distinguish rocks with a system of vertical cracks, for example, from rocks with an inclined fracture, since the dependence of the attenuation on the orientation of the cracks is significantly weakened. It is also unclear how to determine the electrical parameters of the collector and the orientation of the anisotropy axis in space from the measurement results. In addition, the excitation and registration of a rotating field complicates the design of the device and imposes restrictions on the speed of logging.

The closest in technical essence to the claimed invention is a method consisting in the excitation of an electromagnetic field in two mutually perpendicular azimuths, measuring the attenuation of the horizontal component of the magnetic field, comparing the measurement results and determining the azimuthal heterogeneity of the medium from the discrepancy of readings [3]
The disadvantage of this method is the low reliability of the allocation of azimuthally inhomogeneous media, including fractured reservoirs, as there may be cases when the readings of the probes are equal in the presence of fracturing of the rocks. The azimuthal heterogeneity of the fractured rocks is manifested as the anisotropy of their electrical resistance. If the rock has a basic system of cracks oriented in one direction, then the resistance in the directions parallel to the planes of the cracks differs from the resistance in the direction perpendicular to these planes. The latter direction is called the anisotropy axis. In the case of a system of vertical cracks, which is most likely due to the difference between vertical and lateral rock pressure, the anisotropy axis is horizontal and in the case when the angle between the anisotropy axis and each of the probes is 45 ^{o, the} readings of the probes will be equal. In addition, using the known potential values, it is easy to obtain an expression for the magnetic field H at the location of one of the measuring coils
H = H _c + H _a cos2β,
where H _{c the} component of the magnetic field, independent of the orientation of the probe; H _a is the component of the magnetic field corresponding to the maximum effect of anisotropy on the probe readings, β is the angle between the direction of field excitation and the axis of anisotropy.

толщина скин-слоя в исследуемой породе, w циклическая частота поля, m магнитная проницаемость породы, r_t удельное электрическое сопротивление породы в плоскости трещин. В этом случае L/δ≪ 1 и, следовательно, H_a<H_c, т.е. поля, регистрируемые двумя взаимно перпендикулярными зондами или затухания этих полей слабо отличаются друг от друга. В то же время для определения этим методом электрических параметров пород, пересеченных вертикальными трещинами, и установления ориентации оси анизотропии в пространстве не хватает информации.At high section resistances characteristic of fractured rocks, H _c ~ (L / δ) ² , and Ha _a ~ (L / δ) ³ , where L is the probe length,

the thickness of the skin layer in the studied rock, w is the cyclic frequency of the field, m is the magnetic permeability of the rock, r _{t is the} electrical resistivity of the rock in the plane of the cracks. In this case, L / δ≪ 1 and, therefore, H _a <H _c , i.e. the fields recorded by two mutually perpendicular probes or the attenuation of these fields differ slightly from each other. At the same time, there is not enough information to determine the electrical parameters of rocks intersected by vertical cracks by this method and to establish the orientation of the anisotropy axis in space.

The purpose of the invention is the expansion of the functionality to determine the electrical conductivity σ _t along the crack propagation, the electrical anisotropy coefficient λ and the orientation of the anisotropy axis in the bedding plane.

This goal is achieved by the fact that in the electromagnetic logging method, based on the excitation of the electromagnetic field in two mutually perpendicular azimuths, registration with the removal of the magnetic field components along the borehole axis and judgment based on measurements of azimuthal heterogeneity, additionally excite the electromagnetic field along the borehole axis and in the horizontal plane at an angle of 45 ^o to one of the directions of the excited field and measure the magnetic field in the directions of each of the excited mutually perpendicular fields and in each of the two directions perpendicular to the excited fields and shifted by 45 ^o and the measured values find the electrical conductivity, the anisotropy coefficient, and the angle that determines the position of the horizontal axis of the anisotropy of the electrical conductivity.

The inventive method differs from the prototype in that the third generator coil is placed in a horizontal plane at an angle of 45 ^o to one of the two generator coils, the magnetic field is measured in two directions, perpendicular to the excited field and shifted by an angle of 45 ^o , additionally excite the electromagnetic field in the direction perpendicular to the axes of the horizontal coils and measure the active or reactive component of the magnetic field in the same direction and determine from the measured values The electrical parameters of the formation and the horizontal orientation of the anisotropy axis with respect to the cardinal points. Thus, the claimed method meets the criteria of the invention of "novelty." Signs that distinguish the claimed method from the prototype are not identified in other technical solutions in the study of this technical field and, therefore, provide the claimed method with the criterion of "significant differences".

 The drawing 1 shows the location of the coils of the downhole tool, with which the proposed method is carried out.

The downhole tool includes generator coils 1,2,3,4 and receiver coils 5,6,7,8. The axis of the coils 1 and 6 are perpendicular to each other and rotated as a whole by an angle of 45 ^o relative to the system of mutually perpendicular coils 2 and 7. Coils 2 and 3, 5 and 7 are perpendicular to each other. The axis of the coils 4 and 8 lie on a straight perpendicular plane, on which lie the axis of the coils 1,2,3. An alternating current of 50 kHz is supplied to the generating coils 1,2,3,4 alternately with a distance between the receiving and generating coils of L 1 m.

In this case, the magnetic field is measured:
receiving coil 6 magnetic field excited by the generator coil 1;
the receiving coil 5 is a magnetic field excited by the coil 2;
the receiving coil 7 is a magnetic field excited by the coil 3;
the receiving coil 7 is a magnetic field excited by the coil 2;
the receiving coil 8 is a magnetic field excited by the coil 4.

In order to determine the orientation of the horizontal axis of anisotropy, it is necessary to pair the device proposed above with an inclinometer, then the angle a between the horizontal axis of anisotropy and the north direction will be equal to
a = β + γ,
where β is the angle between the axis of the receiving coil 7 and the horizontal axis of anisotropy;
g angle between the axis of the pickup coil 7 and the north direction.

 The essence of the proposed method is as follows.

It is known that the magnitude of the magnetic field excited in the horizontal direction, but measured in the horizontal direction perpendicular to the direction of the excited field is equal to / 6 /
H ₁ = H _y sin2β. (one)
If the magnetic field is excited in the horizontal direction at an angle of 45 ^o to the previous one, then the magnitude of the magnetic field strength, measured in the direction perpendicular to the direction of field excitation, is
H ₂ = -H _y cos2β. (2)
The magnetic field strength, measured in the direction coinciding with the direction of magnetic field excitation, is
H ₃ = H _c + H _y cos2β .. (3)
The magnetic field strength, measured in the direction coinciding with the direction of magnetic field excitation, perpendicular to the direction of field excitation for H ₃ , is
H ₄ = H _c -H _y cos2β. (4)
Here, H _c is the magnetic field component independent of the measurement direction, H _y is the magnetic field component corresponding to the maximum influence of anisotropy on the probe readings, β is the angle between the direction of registration of the field and the axis of anisotropy.

(5a)

(5б)
Рассмотрим сечение скважины горизонтальной плоскостью. Совместим ось Х с осью одной из приемных катушек (на чертеже изображена стрелкой). Угол β - это угол между осью Х и горизонтальной осью анизотропии l. Оси координат ОХ и OY делят сечение скважины на четыре квадранта I, II, III и IV (см. рис.1). Горизонтальная ось анизотропии l имеет четыре возможных положения, для которых мы можем определить значение угла b:
ось анизотропии l пересекает I и III квадранты, тогда величину угла b рассчитываем по формуле (5а);
ось анизотропии l пересекает II и IV квадранты, тогда величина угла b определяется по формуле (5б);
ось анизотропии l совпадает с осью ОХ, тогда
H₃-H₄-2H₂ 0 и b 0;
ось анизотропии l совпадает с осью OY, тогда
H₃-H₄+2H₂ 0 и b 90^o.When solving the inverse problem with respect to the angle b, it is necessary to get rid of the doubled angle b, since doubling the angle introduces ambiguity in solving the inverse problem. Then the solution to system (1), (2) will be represented in the form

(5a)

(5 B)
Consider the cross section of the well horizontal plane. Let's combine the X axis with the axis of one of the receiving coils (shown in the drawing by an arrow). The angle β is the angle between the X axis and the horizontal axis of anisotropy l. The coordinate axes ОХ and OY divide the well section into four quadrants I, II, III, and IV (see Fig. 1). The horizontal axis of anisotropy l has four possible positions for which we can determine the value of angle b:
the anisotropy axis l intersects the I and III quadrants, then we calculate the angle b by the formula (5a);
the anisotropy axis l intersects the II and IV quadrants, then the angle b is determined by the formula (5b);
the anisotropy axis l coincides with the axis OX, then
H ₃ -H ₄ -2H ₂ 0 and b 0;
the anisotropy axis l coincides with the axis OY, then
H ₃ -H ₄ + 2H ₂ 0 and b 90 ^o .

где ω = 2πf циклическая частота электромагнитного поля,
μ магнитная проницаемость среды, обычно принимаемая равной 4π•10^-7Гн/м,
L расстояние от генераторной катушки до приемной.In order to determine the sign of the angle b, it is necessary to know the electrical conductivity s _t in the plane of the crack propagation and the value of the anisotropy coefficient λ. It is possible to directly estimate s _t . From expressions (1) (4) in the approximation of a small parameter, we can obtain

where ω = 2πf is the cyclic frequency of the electromagnetic field,
μ magnetic permeability of the medium, usually taken equal to 4π • 10 ^-7 GN / m,
L is the distance from the generator coil to the receiver.

Подставляя найденные значения σ_t и λ в выражение для H_y

,
где K -(1-i)P_t,

длина зонда, нормированная на толщину скин-слоя, и, находя отношение H₁/H_y, определяем знак угла β:

Использование предлагаемого способа электромагнитного каротажа обеспечивает по сравнению с прототипом возможность количественного анализа электрических параметров трещинных коллекторов и позволяет судить о местоположении системы вертикальных трещин в коллекторе относительно сторон света.To determine the value of the anisotropy coefficient λ, we additionally excite the magnetic field along the axis of the well and measure the magnetic field strength H ₅ in the same direction at a distance L from the field excitation point, then

Substituting the found values of σ _t and λ into the expression for H _y

,
where K - (1-i) P _t ,

the probe length normalized to the thickness of the skin layer, and, finding the ratio H ₁ / H _y , we determine the sign of the angle β:

Using the proposed method of electromagnetic logging provides, in comparison with the prototype, the possibility of quantitative analysis of the electrical parameters of fractured reservoirs and allows you to judge the location of the system of vertical cracks in the reservoir relative to the cardinal points.

Claims (1)

The method of electromagnetic well logging, including the excitation of an electromagnetic field in a horizontal plane in two mutually perpendicular azimuths, registration with the removal of the magnetic field components of each of the generator coils along the axis of the well and judging based on measurements of azimuthal heterogeneity of the medium, characterized in that they additionally excite the electromagnetic field along the borehole axis and a horizontal plane at an angle of 45 ^o to one of the exciting field and the measured intensity of the magnetic Proportion along the borehole axis directions coinciding with the directions of each of excited by mutually orthogonal fields and in each of the two directions perpendicular to the excitable fields and shifted by 45 ^o, and an azimuthal nonuniformity of the medium is judged by the conductivity σ _t, the coefficient of anisotropy λ and angle b, which determines the position of the horizontal axis of the anisotropy of electrical conductivity, according to the formulas

where H _{1 is the} active or reactive component of the magnetic field strength, measured in the direction perpendicular to the axis of one of the generator coils;
H _{2 the} active or reactive component of the magnetic field, measured in the direction perpendicular to the generator axis and shifted by an angle of 45 ^o relative to the previous direction;
H _{3 the} active or reactive component of the magnetic field, measured in the direction coinciding with the direction of excitation of the magnetic field;
H _{4 is the} active or reactive component of the magnetic field strength, measured in the direction coinciding with the direction of excitation of the magnetic field, measured in the direction coinciding with the direction of excitation of the magnetic field, perpendicular to the direction of excitation for H ₃ ;
H _{5 the} active or reactive component of the magnetic field strength, measured in the direction coinciding with the direction of excitation of the magnetic field along the axis of the well.