EA036852B1 - Method for production of electromagnetic 3d scanner, and electromagnetic 3d scanner made by the method - Google Patents

Abstract

The invention relates to geophysical equipment for well survey using the electromagnetic logging method, and is designed for testing electrical properties of rocks and fluids, their spatial distribution and anisotropy in the well volume and the borehole environment. The method for production of an electromagnetic scanner comprises making slots in the elongated scanner case, mounting into the slots at least one transmitter emitting electromagnetic field, and at least one receiver receiving electromagnetic field, each containing antennas and electronic boards, wherein at least one antenna is preliminarily assembled by winding a conductor on a dielectric frame; at least one dielectric frame with the wound conductor being an antenna assembly is inserted into each slot intended for installation of antennas and made in the device case. The electromagnetic scanner made by said method is also described. The technical result is the higher efficiency of the inserted antennas used in the device and improved metrological characteristics of the device; better maintainability and manufacturability of the device as compared to prior art equivalents, due to its design and assembly method; measurement of the full matrix of magnetic field transmission ratios by a three-component receiver and transmitter at two or more frequencies, and, therefore, improved completeness and reliability of determination of the magnitude, distribution and anisotropy of electrical properties in the well and in the borehole environment, regardless of the device orientation; simpler data processing and interpretation due to the fact that the receiver and the transmitter are made using a quadrant method and, therefore, have more compact dimensions, which is preferable from the standpoint of theoretical description of the device sensibility to electrical properties of the environment; more precise description of electrical properties of the environment surrounding the device, and, therefore, higher quality of well construction and minerals prospecting, due to totality of particular features of the device design.

Description

The technical field to which the invention relates

The invention relates to geophysical equipment for surveying wells by the method of electromagnetic logging and is intended to study the electrical properties of rocks and fluids, their spatial distribution and their anisotropy in the volume of the well and near the wellbore space.

State of the art

Known downhole logging devices, the action of which is based on the propagation of electromagnetic waves and which are used to measure basic parameters, such as the amplitude and phase shift of electromagnetic waves propagating through the medium in order to determine the specific properties of the medium.

Electromagnetic propagation logging tools typically employ multiple longitudinally spaced transmitting and receiving antennas housed in an elongated tool body and operating at one or more frequencies. An electromagnetic wave propagates from the transmitting antenna into the formation near the borehole and is received by the receiving antenna (s). By combining basic measurements of phase and amplitude, many parameters of interest can be determined, including resistivity, dielectric constant, their anisotropy, and spatial distribution.

Resistivity (resistivity) and dielectric constant are important properties of underground rocks, determined during geological surveys and exploration for oil, gas and other minerals, because many minerals, hydrocarbons and their deposits have characteristic values of resistivity or dielectric constant. Thus, the magnitude of the resistivity and dielectric constant is often an indicator of the presence and amount of oil, gas or other minerals.

These devices are used in geophysical surveys (logging) of wells both during drilling and after completion of drilling. Drilling of oil and gas wells usually involves several stages. First, a vertical exploration well is drilled. Then, technological operations are carried out related to strengthening the wellbore. Then, lateral horizontal wells are drilled in order to increase the output from the oil or gas-bearing formation.

When drilling a vertical exploration well, logging equipment while drilling is usually not used and logging is done after drilling in order to determine potential oil / gas reservoirs and their depth. In this case, logging is carried out by wireline equipment (cable equipment, English designation Wireline).

Directional and horizontal wells are typically drilled using measurement while drilling (MWD) and logging while drilling (LWD) equipment. This is due to the fact that the depth of occurrence of oil / gas reservoirs can change significantly and without operational control of the position of the well and the properties of rocks in the near-wellbore space, there is a high probability of a well coming out of the productive formation or building a sub-optimal well in terms of oil / gas recovery.

Logging-while-drilling can be used when drilling a vertical well for the purpose of operational control of exposed formations and for the purpose of stopping drilling immediately after reaching the depth of occurrence of oil / gas formations.

Electromagnetic tools, often referred to as wireline induction tools, typically use coaxial antennas with magnetic moment directed along the tool axis. This antenna configuration works well in vertical wells and wells with a small inclination angle, it allows you to isolate the boundaries of the layers, determine the horizontal component of the resistivity and evaluate the filtration properties of the layers. Induction devices with coaxial antenna configurations mainly perform the tasks assigned to them.

Coaxial antenna configurations have traditionally been used in induction LWD tools. However, in this case, the information obtained from such devices is not sufficient to characterize and take into account the effect of anisotropy, as well as to determine the direction and distance to the boundaries of the layers. As a result, such tools do not allow to correct the well trajectory in advance and therefore are limited in application.

Modern induction logging tools contain antennas with different directions of the magnetic moment, due to which they are able to more fully and reliably characterize the electrical properties of the near-wellbore space. The production of antennas with the direction of the magnetic moment that does not coincide with the axis of the device under conditions of limited volume and difficult operating conditions is associated with great difficulties. Therefore, existing devices, as a rule, contain a limited number of antennas, the direction of the magnetic moment of which does not coincide with the axis of the device, and, in addition, most of these antennas are standard coaxial antennas, deformed so that their magnetic moment is inclined to the axis of the device. (patent US 7138803 B2, 21.11.2006).

Known device for logging resistivity with aligned antennas (RU 2459221 C2,

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20.08.2012), assuming the presence of antennas with the direction of the magnetic moment perpendicular to the axis of the device. This device comprises an elongated downhole tool element, a first group of recesses made at a predetermined location in an elongated downhole tool member, and a first electrical conductor laid through the first group of recesses to form a first antenna having a first orientation, and a second group of recesses made at a specified predetermined the location of the elongated element of the downhole tool, and a second electrical conductor laid through the second group of recesses to form a second antenna having a second orientation, so that essentially the first and second antennas are formed in one place of the downhole tool element, and the antennas are located in one location relative to the longitudinal axis and the radial axis of the downhole tool element. A conductor is inserted into a group of recesses made in the device body, which together with the body and the recesses forms an antenna. At the same time, in the description of the invention it is indicated that the recesses communicate with each other by means of holes through which the conductor is laid. According to the description and meaning, the recesses are intended for the passage of a magnetic field through them, which in itself implies that the recesses are made in the metal, since otherwise the magnetic field easily spreads in the device case and the recesses are not needed.

The disadvantages of this analogue are that the conductor, which together with the body and the recesses forms an antenna, is inserted not into one recess, but into a group of recesses made in the device body and communicating with each other through holes. The process of routing a conductor through a large number of holes is difficult, especially if the antenna must contain many turns, which, for example, is necessary from the point of view of the efficiency of the receiving antenna. Thus, such an antenna design significantly complicates both the manufacture of the device and its maintenance. In addition, if the body of the device is metal, such antennas are less effective in comparison with antennas made separately and installed in specially prepared recesses, since in such antennas the part of the conductor laid in the holes does not participate in the radiation of the electromagnetic field, but contributes into active resistance and into parasitic capacitance. A decrease in antenna efficiency leads to a deterioration in the accuracy of determining the spatial distribution of electrical resistivity and a deterioration in the quality of construction of oil and gas wells.

Disclosure of invention

The technical problem that the proposed invention solves is to study the electrical properties of their distribution and anisotropy in the well and near the wellbore space by the method of electromagnetic logging. Research can be carried out with the aim of: (i) improving the quality of oil and gas well construction through the prompt interpretation of measurement results, (ii) drawing up geological sections, (iii) determining the depth and assessing mineral reserves, (iv) determining the state of the wellbore, the presence of caverns and cracks.

The technical result consists in:

(i) increasing the efficiency of plug-in antennas used in the device and improving the metrological characteristics of the device, (ii) increasing the maintainability and manufacturability of the device in comparison with known analogues due to the design and assembly method, (iii) measuring the full matrix of magnetic field transfer coefficients with a three-component receiver, and transmitter at two or more frequencies and, consequently, increasing the completeness and reliability of determining the magnitude, distribution and anisotropy of electrical properties in the well and near the wellbore space, regardless of the orientation of the tool, (iv) simplifying data processing and interpretation due to the fact that the receiver and transmitter are made sector method and, therefore, have more compact dimensions, which is preferable from the point of view of the theoretical description of the sensitivity of the device to the electrical properties of the surrounding space, (v) increasing the accuracy of describing the electrical properties of the surrounding device p space and, consequently, improving the quality of well construction and mineral exploration in terms of the set of features of the construction of the device.

To solve the problem with the achievement of the claimed technical result, the method of manufacturing an electromagnetic scanner includes the following stages: grooves are made in the elongated body of the electromagnetic scanner, at least one transmitter emitting an electromagnetic field and at least one receiver receiving an electromagnetic field are installed in the grooves. which contains antennas and electronic boards, at least one antenna is pre-assembled by winding a conductor on a dielectric base, at least one dielectric base with a wound conductor is inserted into each recess for installing antennas and made in the device body, which is an antenna in assembled.

Assembled antennas inserted into recesses made in the housing are covered with dielectric covers or composite covers consisting of metal and dielectric.

The antennas operate at at least two predetermined frequencies from the radio wavelength range.

- 2 036852

The body of the electromagnetic scanner can be made collapsible and contain an elongated chassis element and at least one sleeve made in the form of a hollow cylinder. The bushings are sequentially put on the chassis in a predetermined order and secured to the chassis by a suitable connector that prevents the bushings from twisting and shifting relative to the chassis.

At least one transmitter emitting an electromagnetic field and at least one receiver receiving an electromagnetic field are installed in the body of the electromagnetic scanner. The receiver and the transmitter contain at least three antennas and at least three antennas in the receiver and transmitter have linearly independent directions of the magnetic moment.

At least two antennas of at least one receiver and one transmitter are installed in one place along the length of the housing in such a way that the cross-section of the housing is conventionally divided into sectors, and each antenna is installed in its own sector.

The electromagnetic scanner made in the above way comprises a body, recesses made in the body, installed in the recesses of the antenna and electronic boards, and at least one antenna is installed in each recess made in the body and intended for mounting antennas.

Antennas inserted into recesses made in the housing are covered with dielectric covers or composite covers made of dielectric and metal.

Antennas are capable of operating at least two predetermined frequencies from the radio wavelength range.

The scanner body is collapsible and contains an elongated chassis element and at least one sleeve made in the form of a hollow cylinder, in assembled form, the sleeves are put on the chassis in a predetermined order and fixed to the chassis by a suitable detachable connection that prevents the sleeves from turning and displacement relative to the chassis.

The electromagnetic scanner contains at least one transmitter emitting an electromagnetic field and at least one receiver that receives an electromagnetic field, which contain at least three antennas and at least three antennas in the receiver and transmitter have linearly independent directions of the magnetic moment.

At least two antennas of at least one receiver and one transmitter are installed in one place along the length of the body in such a way that each antenna is located in its own sector of the cross-section of the body.

The cross-section of the housing has three, or four, or six, or eight sectors intended for mounting the antennas of the receiver or transmitter, while when performing three sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna is directed across the axis of the housing, the magnetic moment of the second antenna is directed across the axis of the housing and rotated by 120 ° relative to the first antenna, and the magnetic moment of the third antenna is directed across the axis of the housing and rotated 120 ° relative to the second antenna, when performing four sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna is directed across the axis of the housing, the magnetic moment of the second antenna is directed across the axis of the housing and rotated 90 ° relative to the first antenna, the magnetic moment of the third antenna is directed across the axis of the housing and rotated 90 ° relative to the second antenna, and the magnetic moment of the fourth antenna is directed across hull axles and rotated by 90 ° relative to the third antenna when performing six sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna is directed across the axis of the housing, the magnetic moment of the second antenna is directed along the axis of the housing, the magnetic moment of the third antenna is directed across the axis of the housing and rotated by 120 ° with respect to the first antenna, the magnetic moment of the fourth antenna is directed along the axis of the housing, the magnetic moment of the fifth antenna is directed across the axis of the housing and rotated by 120 ° relative to the third antenna, and the magnetic moment of the sixth antenna is directed along the axis of the housing, with eight sectors each the antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna is directed across the axis of the housing, the magnetic moment of the second antenna is directed along the axis of the housing, the magnetic moment of the third antenna is directed across the axis of the housing and rotated 90 ° relative to the first antenna, the magnetic moment of the fourth antenna is directed along the axis of the housing, the magnetic moment of the fifth antenna is directed across the axis of the housing and rotated 90 ° relative to the third antenna, the magnetic moment of the sixth antenna is directed along the axis of the housing, the magnetic moment of the seventh antenna is directed across the axis of the housing and rotated 90 ° relative to the fifth antenna, and the magnetic the moment of the eighth antenna is directed along the axis of the body.

Brief Description of Drawings

FIG. 1 is a schematic representation of the device.

FIG. 2 - options for sector-by-sector laying of antennas for two-axis receivers or transmitters.

FIG. 3 - options for sector-by-sector laying of antennas for three-axis receivers or transmitters.

FIG. 4 - two-axis sector-by-sector paving with addition to three-axis paving.

In the figures, elements are indicated by the following reference numbers:

- oblong device body,

- 3 036852

- three-axis transmitter,

- three-axis receiver,

- Cartesian coordinate system associated with the device,

- sector for laying the first antenna in a three-sector installation,

- sector for laying the second antenna for three-sector laying,

- sector for laying the third antenna for three-sector laying,

- sector for laying the first antenna for four-sector laying,

- sector for laying the second antenna for four-sector laying,

- sector for laying the third antenna for four-sector laying,

- sector for laying the fourth antenna for four-sector laying,

- sector for laying the first antenna with six-sector laying,

- sector for laying the second antenna for six-sector laying,

- sector for laying the third antenna for six-sector laying,

- sector for laying the fourth antenna for six-sector laying,

- sector for laying the fifth antenna for six-sector laying,

- sector for laying the sixth antenna for six-sector laying,

- sector for laying the first antenna with six-sector laying,

- sector for laying the second antenna for six-sector laying,

- sector for laying the third antenna for six-sector laying,

- sector for laying the fourth antenna for six-sector laying,

- sector for laying the fifth antenna for six-sector laying,

- sector for laying the sixth antenna for six-sector laying,

- sector for laying the seventh antenna for six-sector laying,

- sector for laying the eighth antenna for six-sector laying,

- antennas with sector stacking and with two linearly independent directions of moments, orthogonal to the axis of the device,

- coaxial antenna with the direction of the magnetic moment along the axis of the device.

Implementation of the invention

The electromagnetic 3D scanner is designed for use in both drilled wells and already drilled wells.

In the first case, the electromagnetic 3D scanner is used as part of LWD equipment, which is part of the so-called bottom hole assembly (BHA), a drill string for drilling in rock strata. Drilling with a drill string is carried out on the basis of a drilling complex, which includes a number of devices and accessories for drilling. The process and equipment for drilling wells are well known and therefore not discussed in detail here. The LWD equipment includes (i) an electrical power source, which, for example, could be a battery of chemical batteries or an electric current generator driven by a flow of drilling fluid; (ii) sensors and devices for performing various measurements associated with the construction and operation of a well, which, for example, include gamma-ray logging tools, directional tools designed to measure the zenith and azimuth angle of the drill string, electromagnetic logging tools, which include electromagnetic 3D scanner; (iii) a telemetry system that provides the transmission of the received information to the surface of the earth and, possibly, receives control signals from the surface of the earth; various communication channels can be used to transmit information, for example, hydraulic, electromagnetic channels or a wire channel, the components of which are built into the drill pipes ... In the process of drilling, the data obtained using an electromagnetic 3D scanner is transmitted to the surface of the earth, using any communication channel, for example, using a hydraulic or electromagnetic communication channel. The data obtained during the drilling process from the electromagnetic 3D scanner is used for geosteering and direction control. In addition, data is written to the non-volatile memory of the equipment or device.

In the case of using an electromagnetic 3D scanner in already drilled wells, it is used as part of equipment for wireline logging, which is carried out in vertical exploration wells (wireline logging) or horizontal and deviated wells (logging on rigid cable or pipes), to determine the depth productive oil / gas reservoirs and assessments of their productivity and reserves. The equipment is powered by a logging cable or from an autonomous power source, which is a battery of chemical batteries. Similar to LWD, wireline LWD equipment includes sensors and devices for performing various measurements, including an electromagnetic 3D scanner. The data obtained by the electromagnetic scanner during the logging process is transmitted to the surface of the earth via a logging cable or is written into the non-volatile memory of the equipment or instrument and is used to search for oil / gas reservoirs, determine their depth and

- 4 036852 assessments of their productivity.

The logging process and equipment for logging using the above methods are well known in the art and are discussed only superficially.

Electromagnetic 3D scanner consists of an elongated body that provides placement and fixation of device elements, protection of elements from external physical influences;

at least one receiver and transmitter containing receiving and transmitting antennas, respectively, providing radiation and reception of the electromagnetic field;

electronic boards, connecting wires and connectors that ensure the operation of antennas, measurement, processing, transmission and storage of information;

an electrical power source, which can be either external or internal.

The electromagnetic 3D scanner contains at least one three-axis transmitter 2 and one three-axis receiver 3, which operate at two or more frequencies from the radio range. A receiver and a transmitter is hereinafter meant a combination of one or more antennas and corresponding electronic boards. Three-axis receivers 3 and transmitters 2 contain at least three antennas with a linearly independent direction of the magnetic moment. The magnetic moments are parallel to the axes of the Cartesian coordinate system 4.

When electric power is applied, the electronic boards are sequentially supplied to each of the transmitting antennas with alternating electric current. As a result, a primary alternating electromagnetic field is excited in the surrounding space, which, in turn, excites induction currents. The distribution of currents in space is determined by the distribution and anisotropy of electrical properties in the volume surrounding the antenna. The induced currents are the sources of the secondary electromagnetic field, which together with the primary field causes the induction EMF in all receiving antennas of the electromagnetic 3D scanner. The induction emf induced on the antennas is measured by the electronic boards corresponding to the antennas.

Due to the presence of three linearly independent magnetic moments in a three-axis transmitter and receiver, the device allows obtaining a complete matrix of the transmission coefficients of the magnetic field from the transmitter to the receiver, which is determined by the following equations:

^ Ri.Tj ⁼ * ^ω Μθ ^ Ri ^ Tj hj ^m Ri ^m Tj> ij - 1 <2,3 i ^ XX hyx ^ zx \ h ⁼ I h-xy hyy ^ zy I \ ^ XZ hyz h-ZZ / where i - complex unit, ω - angular frequency, μ ₀ - magnetic constant, V _Ri , ' _{T |} - EMF of induction in the receiving antenna i when the transmitting antenna j, S _{R |} and S _T j are the total area of the i-th receiving antenna and the j-th transmitting antenna, respectively, I _T j is the current in the j-th transmitting antenna, and are the unit vectors of the direction of the magnetic moment of the i-th receiving antenna and the j-th transmitting antenna respectively. Using the matrix of the magnetic field transfer coefficients, it is possible to characterize the magnitude of the resistivity and the anisotropy of the resistivity and the magnitude and anisotropy of the dielectric constant, regardless of the orientation of the device, and the presence of at least two frequencies and the simultaneous measurement of both delay and attenuation (t - complex), passed through the environment of the electromagnetic field, allows you to fix and characterize the inhomogeneity of the resistivity and dielectric constant. Thanks to this, the electromagnetic 3D scanner is able to solve the following tasks:

positioning the tool relative to the top and / or bottom of the geological formation;

determination of the distribution of electrical properties and their anisotropy of rocks and fluids in the volume of the well and in the near-wellbore space.

The housing of the electromagnetic 3D scanner can be made of various types, providing sufficient strength and protection of the device from external conditions.

For use in LWD equipment, the body of the electromagnetic 3D scanner can be made of drill pipe, preferably made of a non-magnetic material.

In the body of the pipe, recesses are made for placing antennas and electronic boards. The notches communicate with each other through channels. Also, if necessary, technological recesses are made, which additionally facilitate the installation of the device. The recesses and channels between the recesses can be made in a variety of ways, such as machining (turning, milling, drilling, etc.), casting, material forming (stamping, forging, etc.) or electrochemical machining. The recesses are closed by covers, which ensure the tightness of the recess against the external environment. The covers intended for the recesses in which at least one antenna is located are made using dielectric materials that ensure the passage of the electromagnetic field from the corresponding recess to the outside and back. For example, such covers can be

- 5 036852 fully dielectric or dielectric with mechanical reinforcement with metal inserts in specified places or metal with holes filled with a dielectric material. The tightness of the covers is ensured by the sealing elements placed between the cover and the body. The covers can be fastened in any suitable way. Can be used as detachable connections, such as: bolted, screw, keyway, pin, etc., and one-piece, such as gluing, soldering, welding.

Antennas are a dielectric base with a conductor wound around it. The base can be made of both magnetic and non-magnetic dielectric material. The conductor is made of highly conductive metals, for example copper, and can have an arbitrary cross-section, for example, round or rectangular, with a large ratio of width to thickness (foil). To improve the electrical properties of the antennas and compensate for parasitic circuits that change the direction of the magnetic moment from the target, the conductor can be wound on the base in various ways, for example, bifilar or sectional winding can be used. As a rule, technological channels and protrusions are made on the basis of the antenna, increasing the determinism of the winding. Antennas are assembled separately from the electromagnetic scanner and are separate devices that are inserted into the corresponding recesses during the installation of the device. This allows (i) control of antenna manufacturing quality and performance; (ii) simplifies the manufacture of the device, its repair and technological maintenance; (iii) allows for better performance of the device since such antennas have better electrical performance than prior art antennas. The antennas are mounted in the recesses in any suitable way. Can be used as detachable connections, such as: bolted, screw, keyway, pin, etc., and one-piece, such as gluing, soldering, welding.

Electronic boards can contain active and passive electronic components, microcontrollers, microprocessors and FPGAs. Electronic boards provide operation of antennas, measurement of characteristics of the field passed through the medium and, if necessary, processing, transmission and storage of measurement results.

The installation of the device takes place in the following sequence: (i) connecting and possibly transit wires are laid through the channels of the case, connectors are mounted and connected; (ii) the electronic boards are inserted into the corresponding recesses and connected to the wires; (iii) the antennas are inserted into the corresponding recesses and connected to the electronic boards; (iv) the recesses are covered by covers.

Also, if necessary, standard coaxial antennas or antennas with an inclined direction of the magnetic moment can be mounted on the housing, for example, the antenna base can consist of several parts that are assembled in a recess in the housing, after which the conductor is wound onto the finished base.

The body of the device can be made collapsible and contain a chassis and bushings. The chassis is made as follows, on the outer surface of the pipe there are seats for installing electronic cards, connecting channels and technological recesses. The sleeves are hollow cylinders, some of which have recesses for mounting antennas and / or technological recesses with corresponding covers. On the inner surface of the bushings and the outer surface of the chassis, elements or mechanisms are made to prevent the bushings from rotating relative to the pipe. Antennas, covers and electronic boards are the same as in the previous version.

In this case, the installation of the device takes place in the following sequence: (i) connecting and, possibly, transit wires are laid in the chassis of the device, connectors are mounted and connected; (ii) electronic boards are mounted on appropriate slots and connected to wires; (iii) the antennas are inserted into the corresponding recesses on the bushings; (iv) empty bushings and bushings with installed antennas are sequentially put on the pipe; (v) antennas are connected to the appropriate electronic boards; (vi) the installed bushings are secured in their respective places; (vii) technological recesses and recesses for antennas are closed with appropriate covers.

In the described embodiment, the covers on the sleeve with antennas can be made in the form of a cylindrical casing. The sealing of such covers can take place not only between the cover and the corresponding sleeve, but also between the cover and adjacent sleeves. Installation of such covers is carried out immediately after the installation of the corresponding sleeve.

In the case of application as part of equipment for wireline logging, the housing of the electromagnetic 3D scanner can, for example, be manufactured and mounted in general similar to the previous method. The main difference is that wireline logging does not require the internal space of the pipe through which the drilling fluid circulates in the case of logging while drilling. Therefore, instead of a pipe, a solid cylinder can be used, or the interior of the pipe can be used as a conduit for routing connecting wires.

The device can contain not only three-axis receivers and transmitters, but also two- and single-axis ones, which, by analogy with three-axis ones, must include at least two (two-axis) and one (one- 6 036852 axial) antennas with linearly independent magnetic moments. Examples of single-axis receivers (transmitters) are coaxial and tilt receivers (transmitters) known in the art.

The configuration and number of antennas in the receiver (transmitter) can be significantly different. One of the options is the sector-by-sector arrangement of the antennas in a given cross-section of the device. In this embodiment, the annular cross-section of the device is conventionally divided into sectors according to the number of antennas, and each of the antennas is located in its own sector.

Typical variants of the sector-by-sector stacking of antennas are shown in Fig. 2 and 3.

The cross-section of the housing can have three, or four, or six, or eight sectors for mounting the antennas of the receiver or transmitter. When performing three sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna 5 is directed across the axis of the housing, the magnetic moment of the second antenna 6 is directed across the axis of the housing and rotated by 120 ° relative to the first antenna 5, and the magnetic moment of the third antenna 7 directed across the axis of the housing and rotated by 120 ° relative to the second antenna 6. When performing four sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna 8 is directed across the axis of the housing, the magnetic moment of the second antenna 9 is directed across the axis of the housing and is rotated 90 ° relative to the first antenna 8, the magnetic moment of the third antenna 10 is directed across the axis of the housing and rotated 90 ° relative to the second antenna 9, and the magnetic moment of the fourth antenna 11 is directed across the axis of the housing and rotated 90 ° relative to the third antenna 10. When performing six sectors, each antenna is installed in its own sector in such sequence that the magnetic moment of the first antenna 12 is directed across the axis of the housing, the magnetic moment of the second antenna 13 is directed along the axis of the housing, the magnetic moment of the third antenna 14 is directed across the axis of the housing and rotated 120 ° relative to the first antenna 12, the magnetic moment of the fourth antenna 15 is directed along the axis housing, the magnetic moment of the fifth antenna 16 is directed across the axis of the housing and rotated by 120 ° relative to the third antenna 14, and the magnetic moment of the sixth antenna 17 is directed along the axis of the housing. When performing eight sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna 18 is directed across the axis of the housing, the magnetic moment of the second antenna 19 is directed along the axis of the housing, the magnetic moment of the third antenna 20 is directed across the axis of the housing and rotated by 90 ° relative to the first antenna 18, the magnetic moment of the fourth antenna 21 is directed along the axis of the housing, the magnetic moment of the fifth antenna 22 is directed across the axis of the housing and rotated by 90 ° relative to the third antenna 20, the magnetic moment of the sixth antenna 23 is directed along the axis of the housing, the magnetic moment of the seventh antenna 24 is directed across the axis of the housing and is rotated by 90 ° relative to the fifth antenna 22, and the magnetic moment of the eighth antenna 25 is directed along the axis of the housing.

FIG. 2 shows biaxial stacking options with three and four antennas, and FIG. 3 - Three-axis stacking options with six and eight antennas.

In the case of a biaxial sector-by-sector stacking, examples of which are shown in FIG. 2, the receiver or transmitter can be supplemented up to a three-axis with additional antennas located nearby along the axis of the device. For example, a biaxial stacking with magnetic moments of antennas 26 orthogonal to the axis of the device can be supplemented with a coaxial antenna 27 (FIG. 4).

The advantage of this antenna stacking method is that a large number of antennas can be located in one location along the length of the instrument body. This reduces the size of the receivers and transmitters of the device. Receivers and transmitters with smaller dimensions lend themselves better to theoretical description in terms of their sensitivity to the electrical properties of the surrounding space, which, in turn, leads to an increase in the accuracy of describing the electrical properties of the medium in the space surrounding the device.

Claims (12)

CLAIM 1. A method of manufacturing an electromagnetic scanner, including making recesses in the elongated body of the scanner, installing in the recesses at least one transmitter emitting an electromagnetic field and at least one receiver receiving an electromagnetic field, each of which contains antennas and electronic boards, characterized in that that at least two antennas with a linearly independent direction of the magnetic moment of at least one receiver and one transmitter are installed in one place along the length of the body in such a way that the cross-section of the body is conventionally divided into sectors and each antenna is installed in its own sector, while at least at least one antenna is pre-assembled by winding a conductor on a dielectric base, at least one dielectric base with a wound conductor, which is an assembled antenna, is inserted into each of the recesses intended for mounting antennas and made in the device body. 2. The method according to claim 1, characterized in that the assembled antennas inserted into the recesses made in the housing are closed with dielectric covers. - 7 036852 3. The method according to claim 1, characterized in that the assembled antennas inserted into the recesses made in the housing are closed with composite covers consisting of a metal and a dielectric. 4. The method according to claim 1, wherein the antennas operate at at least two predetermined frequencies from the radio wavelength range. 5. The method according to claim 1, characterized in that the scanner body is collapsible and contains an elongated chassis element and at least one sleeve made in the form of a hollow cylinder, the sleeves are sequentially put on the chassis in a predetermined order and fastened to the chassis by a suitable detachable connection, preventing the bushings from turning and displacement relative to the chassis. 6. The method according to claim 1, characterized in that it includes installing at least one transmitter emitting an electromagnetic field and at least one receiver receiving an electromagnetic field, which contain at least three antennas having linearly independent directions of the magnetic moment ... 7. Electromagnetic scanner for borehole surveys, comprising a body, recesses made in the body, antennas installed in the recesses and electronic boards, and at least two antennas with a linearly independent direction of the magnetic moment of at least one receiver and one transmitter are installed in one place along the length of the case in such a way that the cross-section of the case is conventionally divided into three, or four, or six, or eight sectors and each antenna is installed in its own sector, while in each of the recesses made in the case and intended for installing antennas, at least one antenna made in the form of a dielectric base with a conductor wound on it, and when performing three sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna is directed across the axis of the housing, the magnetic moment of the second antenna is directed across the axis of the housing and rotated to 120 ° with respect to the first antenna, and the magnetic the moment of the third antenna is directed across the axis of the housing and rotated by 120 ° relative to the second antenna when performing four sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna is directed across the axis of the housing, the magnetic moment of the second antenna is directed across the axis of the housing and is rotated 90 ° relative to the first antenna, the magnetic moment of the third antenna is directed across the axis of the housing and rotated by 90 ° relative to the second antenna, and the magnetic moment of the fourth antenna is directed across the axis of the housing and rotated 90 ° relative to the third antenna, when performing six sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna is directed across the axis of the housing, the magnetic moment of the second antenna is directed along the axis of the housing, the magnetic moment of the third antenna is directed across the axis of the housing and rotated by 120 ° relative to the first antenna, the magnetic moment of the fourth antenna is directed along the axis of the case, the magnetic moment of the fifth antenna is directed across the axis of the case and rotated by 120 ° relative to the third antenna, and the magnetic moment of the sixth antenna is directed along the axis of the case, when performing eight sectors, each antenna is installed in its sector in such a sequence that the magnetic moment of the first antenna is directed across axis of the housing, the magnetic moment of the second antenna is directed along the axis of the housing, the magnetic moment of the third antenna is directed across the axis of the housing and rotated by 90 ° relative to the first antenna, the magnetic moment of the fourth antenna is directed along the axis of the housing, the magnetic moment of the fifth antenna is directed across the axis of the housing and rotated by 90 ° relative to the third antenna, the magnetic moment of the sixth antenna is directed along the axis of the housing, the magnetic moment of the seventh antenna is directed across the axis of the housing and rotated by 90 ° relative to the fifth antenna, and the magnetic moment of the eighth antenna is directed along the axis of the housing. 8. Electromagnetic scanner according to claim 7, characterized in that the antennas inserted into the recesses made in the housing are closed with dielectric covers. 9. Electromagnetic scanner according to claim 7, characterized in that the antennas inserted into the recesses made in the housing are closed with composite covers consisting of a metal and a dielectric. 10. Electromagnetic scanner according to claim 7, characterized in that the antennas are capable of operating at at least two predetermined frequencies from the radio wavelength range. 11. Electromagnetic scanner according to claim 7, characterized in that the scanner body is collapsible and contains an elongated chassis element and at least one sleeve made in the form of a hollow cylinder, when assembled, the sleeve is put on the chassis in a predetermined order and fixed to the chassis by a suitable a detachable connection that prevents rotation and displacement of the bushings relative to the chassis. 12. Electromagnetic scanner according to claim 7, characterized in that it contains at least one transmitter that emits an electromagnetic field and at least one receiver that receives an electromagnetic field, which contain at least three antennas having linearly independent directions of the magnetic moment ...