RU2739230C1 - Method of organizing an antenna of a downhole resistivity meter for a telemetric system (versions), an antenna of a downhole resistivity meter for a telemetric system (versions) - Google Patents

Abstract

FIELD: drilling of wells.

SUBSTANCE: disclosed technical solution relates to geophysical equipment for tracking drilling of wells, specifically to versions of well resistor meter for telemetry system, intended for measurement of specific electric resistance (SER) of rocks and fluids, filling the well and porous space of rocks, its anisotropy, determining the presence of non-uniformity of SER in the study zone, associated, for example, with boundaries of geological bodies with different SER, contacts of fluids with different resistivity, as well as determining distances to these inhomogeneities of SER both during drilling of wells, and in drilled wells. Technical result is achieved by the fact that in antenna of borehole resistivity meter for telemetric system, including housing, in which case well resistor meter for telemetry system is used, at least one pair of antenna modules, which are arranged in in-phase, forming total magnetic moment and installed on opposite sides of housing, on same section of housing, in particular, antenna module is made in form of coil, which wire is wound on its base, latter is made of diamagnetic material of at least one part in form of rod, the shape of which is matched with the shape of the body section in the area of location of antenna modules.

EFFECT: technical result is creation of antenna with higher efficiency of transmission and reception of electromagnetic waves for directed measurements.

36 cl, 7 dwg

Description

The claimed technical solution relates to geophysical equipment for accompanying drilling of wells, namely, to variants of the antenna of a borehole resistivity meter for a telemetric system designed to measure the resistivity (resistivity) of rocks and fluids filling the well and the pore space of rocks, its anisotropy, determination the presence of resistivity inhomogeneities in the study area, associated, for example, with the boundaries of geological bodies with different resistivity, contacts of fluids with different resistivity, as well as determining the distances to these resistivity inhomogeneities both in the process of drilling wells and in drilled wells

In directional drilling of inclined and horizontal wells, the passage of the wellbore through the specified zones of geological bodies is of great importance. To do this, in the process of drilling, the trajectory of the wellbore is corrected relative to the design trajectory, based on the continuous analysis of various geophysical and technological data coming in real time from the downhole part of the telemetry system to its surface system.

One of the requirements for borehole resistivity meters that are part of the borehole part of the telemetry system is their large radial depth of research, which is necessary for obtaining early information about the approach of the borehole to any resistivity heterogeneity in order to correct the wellbore trajectory in advance, as well as high measurement accuracy for improving the unambiguity when making a decision to adjust the wellbore trajectory. In addition, an important requirement for borehole resistivity meters is also the radial directionality of measurements, i.e. the ability to measure rock parameters not only integrally around the wellbore, but also in a certain radial direction from the wellbore, in order to obtain information about the direction to the detected resistivity heterogeneity, in order to correct the wellbore trajectory in the required direction. Investigations with borehole resistivity meters can be performed in wells and after the end of drilling: when lifting a drilling tool with a downhole part of the telemetry system to the surface, with a separate lowering of a borehole resistivity meter into a well using drill pipes or a specialized cable.

To use borehole resistivity meters for this purpose, transmitting and receiving antennas are included in its probe installation. During the measurements, the transmitting antennas of the borehole resistivity meters generate electromagnetic waves in the rock that induce secondary eddy currents, while the receiving antennas of the borehole resistivity meter register the electromotive force induced by these currents. The frequency range of electromagnetic waves is selected depending on the purpose and conditions of use of borehole resistivity meters, and in one borehole resistivity meter not only one, but also several frequencies can be used, both in different probes, and alternately in the same probe.

Depending on the tasks being solved, borehole resistivity meters use antennas, the directions of the magnetic moments of which are at different angles to the axis of the borehole resistivity meter body. For transmission and reception of longitudinal and transverse components of the electromagnetic wave, longitudinal and transverse antennas are intended, respectively. The direction of the magnetic moment of the longitudinal antenna is parallel to the axis of the borehole resistivity meter body, and the direction of the magnetic moment of the transverse antenna is orthogonal to it. Also, borehole resistivity meters use inclined antennas that transmit and receive both components of the electromagnetic wave, the direction of the magnetic moment of the inclined antenna is at an angle to the axis of the borehole resistivity meter body.

The probes of the borehole resistivity meter, which include only longitudinal antennas, are designed to measure the integral resistivity of rocks and fluids filling the well and the pore space of rocks around the well. To measure the anisotropy of rocks by resistivity, to determine the presence of resistivity inhomogeneities in the study area, to determine directions to these resistivity inhomogeneities and distances to them, that is, for radially directed measurements, inclined, transverse antennas are included in the probes.

In modern borehole resistivity meters for telemetry systems, complex probe systems are used, which include several probes with different purposes, directions and radial depths of research. To minimize the length of the borehole resistivity meter with such complex probe systems, the antenna designs of the borehole resistivity meter for the telemetry system should provide for the possibility of installing more than one antenna of the borehole resistivity meter for the telemetry system on one section of the housing. The presence of more than one antenna of a borehole resistivity meter for a telemetry system with different directions of magnetic moments on one section of the body allows, using the principle of superposition, to calculate directions on resistivity inhomogeneities when the drilling mode is used without rotating the drilling tool, while, accordingly, the borehole resistivity meter does not rotate around the axis your body.

Terms used in this technical solution.

Antenna (Antenna) - a system of wires used to emit electromagnetic waves (transmitting A.) or to capture them (receiving A.) ./ Samoilov K.I. Marine dictionary. - M. - L .: State Naval Publishing House of the NKVMF of the USSR, 1941, URL: https://dic.academic.ru/dic.nsf/sea/219/%D0%90%D0%9D%D0%A2 % D0% 95% D0% 9D% D0% 9D% D0% 90

Antenna (from Lat. Antenna mast, ray), a device for emitting or receiving radio waves. A. optimally converts the electromagnetic oscillations supplied to it into radiated electromagnetic waves. waves (transmitting A.) or, conversely, converts the electromagnet falling on it. waves in e-magn. vibrations, which then act on the receiver (receiving A.). / Physical encyclopedia, URL: https://dic.academic.ru/dic.nsf/enc_physics/103/%D0%90%D0%9D%D0%A2%D0%95%D0%9D%D0%9D%D0 % 90

Probe

1. The name of various tools and devices for examining the soil, wells during drilling, the viscera of the body. Ozhegov's Explanatory Dictionary. S.I. Ozhegov, N.Yu. Shvedova. 1949-1992.

A longitudinal antenna is an antenna whose magnetic moment is directed parallel to the axis of the borehole resistivity meter body.

An oblique antenna is an antenna whose magnetic moment is directed at an angle to the axis of the borehole resistivity meter body.

A transverse antenna is an antenna whose magnetic moment is directed orthogonal to the axis of the borehole resistivity meter body.

The terms used in this technical solution are taken from antenna theory and are mainly used in the field of wireless communication. In this technical solution, antennas are used to study rocks, other frequencies of electromagnetic waves are used, therefore, to assess the effectiveness of antennas in this technical solution, other approaches are used.

Known technical solution, selected as a prototype, in which a transverse antenna of the borehole resistivity meter for the telemetry system is organized, in the form of a pair of antenna modules, which are installed on opposite sides of the body of the borehole resistivity meter so that the direction of the magnetic moment of the pair of antenna modules is orthogonal to the axis of the body of the borehole resistivity meter (Application USA 2010/0225323 A1, IPC G01V 3/36, priority 09-09-2010) Each of the antenna modules is a printed circuit board with a conductor that forms a coil on the printed circuit board, the dimensions of the coil turns decreasing towards the center of the printed circuit board.

The disadvantage of the known technical solution, selected as a prototype, is insufficient efficiency, which is due to a decrease in the area of each subsequent turn on the printed circuit board of the antenna module and the lack of design solutions to improve the efficiency of this known technical solution. The disadvantage of the known technical solution, selected as a prototype, is also the limitation of the number of turns by the outer diameter of the borehole resistivity meter and the diameter of the body of the borehole resistivity meter.

Also known is a technical solution in which the transverse antenna wire is inserted into a group of recesses located on different sides of the body of the borehole resistivity meter, made of metal, connected by holes in the body of the borehole resistivity meter (RU 2459221 C2, IPC G01V 3/10, H01Q 1/04).

The disadvantages of the known technical solution is insufficient efficiency, which is due to the fact that the large length of the wire sections of the transverse antenna is shielded by the metal of the body of the borehole resistivity meter for receiving or transmitting an electromagnetic wave, the wire is open only in short sections of the recesses in the body of the borehole resistivity meter. The disadvantage of this known technical solution is also the complexity of manufacturing and maintenance of this transverse antenna, because the antenna wire is laid in internal channels in the wall of the borehole resistivity meter housing and in the holes between the notches.

Also known is a technical solution in which oblique antennas are used, the wires of which are wound around the metal body of the borehole resistivity meter at an angle to the axis of the borehole resistivity meter, and, accordingly, the magnetic moment of which is directed to the axis of the borehole resistivity meter at the same angle. (US patent 7138803, IPC G01V 3/30 priority 16-02-2006).

The disadvantages of the known technical solution is the impossibility of manufacturing a transverse antenna in such a design, and the inclined antenna has insufficient efficiency for measuring the transverse component of an electromagnetic wave, which is due to the fact that the direction of the magnetic moment of the inclined antenna cannot be orthogonal to the axis of the borehole resistivity meter body.

The objective of the proposed technical solution is to develop a method for organizing an antenna of a borehole resistivity meter for a telemetry system with a higher efficiency of transmission and reception of electromagnetic waves for directional measurements, while its design should allow performing antennas of a borehole resistivity meter for a telemetry system with the direction of the magnetic moment parallel, orthogonal to the axis of the borehole body. resistivity meter located at an angle to the axis of the borehole resistivity meter body.

Also, the method of organizing the antenna of the borehole resistivity meter for the telemetry system should provide for the possibility of installing more than one antenna of the borehole resistivity meter for the telemetry system with different directions of the magnetic moment on one section of the borehole resistivity meter, and each of them can be both receiving and transmitting at a certain point in time. The task is solved as follows. Option 1 of the method of organizing the antenna of a borehole resistivity meter for a telemetry system.

The problem is solved by the fact that according to the first option, in the method of organizing the antenna of the borehole resistivity meter for the telemetry system, the body of the borehole resistivity meter for the telemetry system is used as its body. At least one pair of antenna modules is placed on the housing, which operate in phase, form the total magnetic moment and are installed on opposite sides of the housing on the same section of the housing. The antenna module is made in the form of a coil, the wire of which is wound on its base using winding types and insulating by any methods known in the industry. The base of the coil is made of a diamagnetic material of at least one piece in the form of a rod, the shape of which is chosen to match the shape of the cross-section of the body at the site where the antenna modules are located. The length of the antenna module is chosen to allow at least one pair of antenna modules to be placed around the body at the location of the antenna modules, which can be both transmitting and receiving. Antenna modules are attached to the housing by any methods known in the industry so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, and is at an angle to the housing axis. The dimensions of the cross-section of the antenna module in order to increase the area of the coil wire of the coil are made as possible as possible, matching them with the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module, the cross-section of the case in the area where the antenna modules are located can be round, rectangular or of another shape, the cross-section of the coil base can be round, rectangular, or other shapes, and the coil base length can be greater than the coil length. For protection from external mechanical influences from the outside, antenna modules are covered with a common cover that transmits electromagnetic waves, with separate covers, which are attached to the housing, to each other. Antenna modules for protection against contact with drilling fluid are sealed using any methods known in the industry. If necessary, recesses are made on the housing at the location of the antenna modules, at least one groove for accommodating antenna modules and covers transmitting electromagnetic waves in order to organize the sealing of the antenna modules and protect them from external mechanical influences.

Option 2 of the method of organizing the antenna of the borehole resistivity meter for the telemetry system.

According to the second option, in the method of organizing the antenna of the borehole resistivity meter for the telemetry system, the task is solved by the fact that the body of the borehole resistivity meter for the telemetry system is used as its body. At least one pair of antenna modules is placed on the housing, which operate in phase, form the total magnetic moment and are installed on opposite sides of the housing on the same section of the housing. The antenna module is made in the form of a coil, the wire of which is wound on its base using winding types and insulating by any methods known in the industry. The base of the coil is made of a material with high magnetic permeability, the type of material with high magnetic permeability is chosen to match the frequencies of electromagnetic waves used in the antenna module, the base of the coil is made of at least one part in the form of a rod, the shape of which is chosen to match the shape of the cross-section of the body on the site of the antenna modules. The length of the antenna module is chosen to allow at least one pair of antenna modules to be placed around the body at the location of the antenna modules, which can be both transmitting and receiving. Antenna modules are attached to the housing by any methods known in the industry so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, and is at an angle to the housing axis. The dimensions of the cross-section of the antenna module in order to increase the area of the coil of the coil wire are made as possible as possible, matching them with the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module. The cross-section of the housing in the area where the antenna modules are located can be round, rectangular or of another shape, the cross-section of the base of the coil can be round, rectangular or of another shape, and the length of the base of the coil can be equal to greater than the length of the coil. For protection from external mechanical influences from the outside, antenna modules are covered with a common cover that transmits electromagnetic waves, with separate covers, which are attached to the housing, to each other. Antenna modules for protection against contact with drilling mud are sealed by any methods known in the industry; if necessary, recesses are made on the housing at the site of the antenna modules, at least one groove is made to accommodate antenna modules and covers transmitting electromagnetic waves in order to organize the sealing of the antenna modules and their protection from external mechanical influences.

Option 3 of the way of organizing the antenna of the borehole resistivity meter for the telemetry system.

According to the third variant, in the method of organizing the transverse antenna of the borehole resistivity meter for the telemetry system, the task is solved by the fact that the body of the borehole resistivity meter for the telemetry system is used as its body. At least one pair of antenna modules is placed on the housing, which operate in phase, form the total magnetic moment and are installed on opposite sides of the housing on the same section of the housing. The antenna module is made in the form of a coil, the wire of which is wound on its base using winding types and insulating by any methods known in the industry. The base of the coil is made of material with high magnetic permeability, the type of material with high magnetic permeability is chosen to match the frequencies of electromagnetic waves used in the antenna module. The base of the coil is made of at least one part in the form of a rod completely surrounding the body, the shape of which is chosen to match the shape of the cross-section of the body at the location of the antenna modules, the length of the coil is chosen to allow at least one pair of coils to be placed around the body in the location of the coils, which can be , both transmitting and receiving. Antenna modules are attached to the housing by any methods known in the industry so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, and is at an angle to the housing axis. The dimensions of the cross-section of the antenna module in order to increase the area of the coil of the coil wire are made as possible as possible, matching them with the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module. The cross-section of the housing in the area where the antenna modules are located can be round, rectangular or of another shape, the cross-section of the base of the coil can be round, rectangular or of another shape, and the length of the base of the coil can be equal to greater than the length of the coil. For protection from external mechanical influences from the outside, antenna modules are covered with a common cover that transmits electromagnetic waves, with separate covers, which are attached to the housing, to each other. Antenna modules for protection against contact with drilling mud are sealed by any methods known in the industry; if necessary, recesses are made on the housing at the site of the antenna modules, at least one groove is made to accommodate antenna modules and covers transmitting electromagnetic waves in order to organize the sealing of the antenna modules and their protection from external mechanical influences.

Option 1 of borehole resistivity meter antenna for telemetry system.

Antenna of the borehole resistivity meter for the telemetry system according to the first version, including the case, which is the case of the borehole resistivity meter for the telemetry system, at least one pair of antenna modules, which are made operating in phase, forming the total magnetic moment and are installed on opposite sides of the case on one and the same the same section of the body. The antenna module is made in the form of a coil, the wire of which is wound on its base using any types of winding known in the industry and insulated by any methods known in the industry. The base of the coil is made of a diamagnetic material of at least one piece in the form of a rod, the shape of which is matched with the shape of the cross-section of the body at the location of the antenna modules. The length of the antenna module is chosen to make it possible to place at least one pair of antenna modules around the body at the location of the antenna modules, which can be both transmitting and receiving. Antenna modules are attached to the housing by any methods known in the industry so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, and is at an angle to the housing axis. The dimensions of the cross-section of the antenna module in order to increase the area of the coil of the coil wire are made as possible as possible and are coordinated with the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module, the cross-section of the case at the site where the antenna modules are located can be rounded, rectangular or of another shape, transverse the cross-section of the coil base can be round, rectangular or of any other shape, and the length of the coil base can be equal to greater than the length of the coil, antenna modules for protection from external mechanical influences from the outside are closed by a common cover that transmits electromagnetic waves, separate covers that are attached to the body, to each other, antenna modules for protection against contact with drilling fluid are sealed by any methods known in the industry; if necessary, recesses are made on the housing at the site of the antenna modules, at least one groove for placing antenna m modules and covers transmitting electromagnetic waves in order to organize the sealing of antenna modules and their protection from external mechanical influences.

Option 2 of borehole resistivity meter antenna for telemetry system.

Antenna of a borehole resistivity meter for a telemetry system according to the second version, including a case, which is used as a case of a downhole resistivity meter for a telemetry system, at least one pair of antenna modules, which are made operating in phase, forming a total magnetic moment and installed on opposite sides of the case on one and the same the same section of the body, the antenna module is made in the form of a coil, the wire of which is wound on its base using any types of winding known in the industry and is insulated by any methods known in the industry, the coil base is made of a material with high magnetic permeability, the type of material with high magnetic permeability is selected coordinated with the frequencies of electromagnetic waves used in the antenna module, the base of the coil is made of at least one part in the form of a rod, the shape of which is consistent with the shape of the cross-section of the body at the location of the antenna modules, the length of the antenna module is a brane that allows at least one pair of antenna modules to be placed around the body at the location of the antenna modules, which can be both transmitting and receiving, the antenna modules are attached to the body by any methods known in the industry so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the body axis, orthogonal to the body axis, is at an angle to the body axis. The dimensions of the cross-section of the antenna module in order to increase the area of the coil wire are made as large as possible and are matched with the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module. The cross-section of the housing in the area where the antenna modules are located can be round, rectangular or of another shape, the cross-section of the base of the coil can be round, rectangular or of another shape, and the length of the base of the coil can be equal to greater than the length of the coil. For protection from external mechanical influences, antenna modules are closed from the outside by a common cover that transmits electromagnetic waves, with separate covers that are attached to the housing, to each other. Antenna modules for protection against contact with drilling fluid are sealed by any methods known in the industry, if necessary, recesses are made on the case at the site of the antenna modules, at least one groove for placing antenna modules and covers transmitting electromagnetic waves in order to organize the sealing of the antenna modules and their protection from external mechanical influences.

Option 3 of borehole resistivity meter antenna for telemetry system.

Antenna of a borehole resistivity meter for a telemetry system according to the third version, including a body, which is used as a body of a borehole resistivity meter for a telemetry system, at least one pair of antenna modules that are made operating in phase, forming a total magnetic moment and installed on opposite sides of the body on one and the same the same section of the body. The antenna module is made in the form of a coil, the wire of which is wound on its base using any types of winding known in the industry and insulated by any methods known in the industry. The base of the coil is made of a material with high magnetic permeability, the type of material with high magnetic permeability is chosen to match the frequencies of electromagnetic waves used in the antenna module, the base of the coil is made of at least one piece in the form of a rod completely surrounding the body, the shape of which is consistent with the shape of the body section in the area where the antenna modules are located, the length of the coil is selected to allow at least one pair of coils to be placed around the body on the area where the coils are located, which can be both transmitting and receiving. Antenna modules are attached to the housing by any methods known in the industry so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, and is at an angle to the housing axis. The dimensions of the cross-section of the antenna module in order to increase the area of the coil of the coil wire are made as possible as possible and are coordinated with the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module, the cross-section of the case at the site where the antenna modules are located can be rounded, rectangular or of another shape, transverse the cross-section of the coil base can be round, rectangular or of any other shape, and the length of the coil base can be equal to greater than the length of the coil. For protection from external mechanical influences, antenna modules are closed from the outside by a common cover that transmits electromagnetic waves, with separate covers that are attached to the housing, to each other. Antenna modules for protection against contact with drilling fluid are sealed by any methods known in the industry. If necessary, recesses are made on the case at the site of the antenna modules, at least one groove for accommodating antenna modules and covers transmitting electromagnetic waves in order to organize the sealing of the antenna modules and protect them from external mechanical influences.

The technical effect of the proposed technical solution is to expand the arsenal of tools for this purpose.

The claimed technical solution is illustrated by schematic drawings. For greater clarity of the figures, they do not show fastening elements, sealing and insulation of antenna modules, transmitting electromagnetic waves, common covers, separate covers with fastening elements that protect antennas from external mechanical influences. In all the figures, the antenna modules are, for example, placed in a groove made on the body, which also shows a groove for installing a common cover, separate covers. Placement of antenna modules in grooves is not the only possible one. Antenna modules can be installed on a housing on which no grooves, recesses are made for placing antenna modules and covers transmitting electromagnetic waves in order to organize the sealing of the antenna modules and protect them from external mechanical influences. In this case, the antenna modules are protected from external influences by an external casing organized from the outside, which covers at least one section of the antenna modules, while the outer casing, at least in the area of the antenna modules, is capable of transmitting electromagnetic waves.

In addition, the schematic drawings are examples and do not limit the number of antenna modules in one area of the housing, do not limit the length of the base of the coils, the material of the base of the coils can be either diamagnetic or with high magnetic permeability.

FIG. 1 shows a model of a borehole resistivity meter for a telemetry system, used to compare the effectiveness of antennas of a borehole resistivity meter for a telemetry system, where 1 is the body of a borehole resistivity meter for a telemetry system, 2 is an antenna of a borehole resistivity meter for a telemetry system.

FIG. 2 shows a model for explaining the first version of the proposed technical solution, where 1 is the body of a downhole resistivity meter for a telemetry system, 3 is a groove for installing a cover, 4 is a groove for installing antenna modules, 5 is a coil wire, 6 is a coil base made of diamagnetic material.

FIG. 3 shows a model for explaining the second version of the proposed technical solution, where 1 is the housing of a downhole resistivity meter for a telemetry system, 3 is a groove for installing a cover, 4 is a groove for installing antenna modules, 5 is a coil wire, 7 is a coil base made of material with a high magnetic susceptibility.

FIG. 4 shows a model for explaining the third version of the proposed technical solution, where 1 is the housing of a downhole resistivity meter for a telemetry system, 3 is a groove for installing a cover, 4 is a groove for installing antenna modules, 5 is a coil wire, 8 is a coil base made of a material with a high magnetic susceptibility completely surrounding the body.

FIG. 5 shows an example of the proposed technical solution with two pairs of antenna modules, where 1 is a housing of a downhole resistivity meter for a telemetry system, 3 is a groove for installing a cover, 4 is a groove for installing antenna modules, 5 is a coil wire, 6 is a coil base made of diamagnetic material.

FIG. 6 shows an example of the proposed technical solution with a pair of antenna modules installed so that the direction of their total magnetic moment of the pair is directed at an angle of 45 degrees relative to the axis of the body, where 1 is the body of the downhole resistivity meter for the telemetry system, 3 is the groove for installing the cover, 4 is the groove for installing antenna modules, 5 - coil wire, 6 - coil base made of diamagnetic material.

FIG. 7 shows the calculated graphs of the dependences of the coupling coefficients on the angular length of the coil for three variants of the proposed technical solution, where 1 is the graph for the first variant of the proposed technical solution, 2 is the graph for the second variant of the proposed technical solution, 3 is the graph for the third variant of the proposed technical solution.

FIG. 1 shows a model of a borehole resistivity meter for a telemetry system, used to compare the effectiveness of antennas of a borehole resistivity meter for a telemetry system, which consists of two identical test antennas of a borehole resistivity meter for a telemetry system, installed on the body of the borehole resistivity meter and identically oriented relative to each other, with one of the antennas The downhole resistivity meter for the telemetry system is used as a transmitting one, and the second one is used as a receiving one. To quantitatively evaluate the effectiveness of the antennas of the borehole resistivity meter for the telemetry system, the coupling coefficient between the transmitting and receiving antennas of the borehole resistivity meter for the telemetry system of various technical solutions is used, which is calculated by the formula:

K = 20 * lg (Ur / Ut), dB,

where K is the coupling coefficient between the transmitting and receiving antennas of the borehole resistivity meter for the telemetry system, Ur is the voltage at the receiving antenna of the borehole resistivity meter for the telemetry system, Ut is the voltage at the transmitting antenna of the borehole resistivity meter for the telemetry system.

The value of the coupling coefficient between the transmitting and receiving antennas of the borehole resistivity meter for the telemetry system in this probe model is mainly determined only by their geometry, which makes it possible to use this coupling coefficient to compare the effectiveness of the antennas of the borehole resistivity meter for the telemetry system.

The calculations were carried out by a numerical method. When carrying out calculations, the distance between the transmitting and receiving antennas of the downhole resistivity meter for the telemetry system is 1 m, the frequency of the electromagnetic wave is 400 kHz, the environment is vacuum, the body of the downhole resistivity meter is made of non-magnetic steel with a relative magnetic permeability equal to 1, the relative magnetic permeability of the base of the coil is made of diamagnetic material is equal to 1, the relative magnetic permeability of the base of the coil made of material with high magnetic permeability is 100, the cross-section of the coil wire is 1 mm. When calculating the coupling coefficient for the proposed technical solution, the antenna of the borehole resistivity meter for the telemetry system was used, made according to the first version of the proposed technical solution, which is shown in Fig. 2, where the coil wire is wound on a coil base made of diamagnetic material, antenna modules are mounted orthogonal to the body axis.

When calculating the coupling coefficients of antennas of known technical solutions, antennas were also located on a housing made of non-magnetic steel, in grooves for installing antenna modules with the same overall dimensions as the proposed technical solution, while the coil winding width for the proposed technical solution, known technical solutions (US Patent 7138803), (Patent RU 2459221 C2) is equal to 27 mm, while in the model of the borehole resistivity meter used to calculate the coupling coefficient, the angle between the direction of the magnetic moment to the axis of the body of the borehole resistivity meter of the known technical solution (US Patent 7138803) was 45 degrees, and the coil wire of the known technical solution (Patent RU 2459221 C2) was not laid through the groups of recesses made in the metal case of the borehole resistivity meter, as indicated in the patent (Patent RU 2459221 C2), but was located outside the case. The width of the printed circuit board on which the coil is made according to a known technical solution, selected as a prototype (US Application 2010/0225323 A1), was limited by the depth of the groove and was equal to 10 mm. As a result of the calculations, the following coupling coefficients were obtained for the proposed technical solution and known technical solutions.

The coupling coefficient for the antenna of the borehole resistivity meter for the telemetry system of the known technical solution, selected as a prototype (US Application 2010/0225323 A1) is equal to -115.43 dB.

The coupling coefficient for the transverse component of the electromagnetic wave of the antenna of the borehole resistivity meter for the telemetry system of the known technical solution (US Patent 7138803) is -112.65 dB.

The coupling coefficient for the antenna of the borehole resistivity meter for the telemetry system of the known technical solution (Patent RU 2459221 C2) is -109.86 dB.

The coupling coefficient for the antenna of the borehole resistivity meter for the telemetry system according to the first embodiment of the proposed technical solution is equal to -100.53 dB.

Thus, the antenna of the borehole resistivity meter for the telemetry system according to the first embodiment of the proposed technical solution has a coupling coefficient higher than the coupling coefficients of the antennas of the borehole resistivity meter for the telemetry system of known technical solutions.

FIG. 3 shows the antenna of the borehole resistivity meter for the telemetry system of the second version of the proposed technical solution, where the coil wire is wound on the coil base made of a material with high magnetic permeability, the antenna modules are installed orthogonal to the housing axis. The coupling coefficient for the antenna according to the second variant of the proposed technical solution is --91.97 dB.

FIG. 4 shows the antenna of the borehole resistivity meter for the telemetry system of the third version of the proposed technical solution, where the coil wire is wound on the coil base, which completely surrounds the body and is made of material with high magnetic permeability, the antenna modules are installed orthogonal to the body axis. The coupling coefficient for the antenna according to the third variant of the proposed technical solution is -74.35 dB.

Thus, the use of a high permeability material for the coil base increases the coupling coefficient of the antenna of the borehole resistivity meter for the telemetry system, while increasing the length of the coil base made of a material with high permeability also increases the coupling coefficient of the antenna of the borehole resistivity meter for the telemetry system, which reaches its maximum in the antenna of the borehole resistivity meter for the telemetry system according to the third variant of the proposed technical solution, when the base of the antenna of the borehole resistivity meter for the telemetry system completely surrounds the body of the borehole resistivity meter.

The method of organizing the antenna of the borehole resistivity meter for the telemetry system of the proposed technical solution allows placing several pairs of antenna modules on one section of the body. FIG. 5 shows an example of an antenna of a borehole resistivity meter for a telemetry system, where two pairs of antenna modules are located on one section of the housing.

The method of organizing the antenna of the borehole resistivity meter for the telemetry system of the proposed technical solution allows the antenna modules to be installed on the housing so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, is at an angle to the housing axis. FIG. 6 shows an example of an arrangement of a pair of antenna modules with the direction of their total magnetic moment at an angle of 45 degrees relative to the axis of the housing.

To determine the optimal lengths of the coils for the three variants of the proposed technical solution, the dependences of the coupling coefficients of the antennas of the borehole resistivity meter for the telemetry system with one pair of antenna modules shown in FIG. 2, fig. 3 and FIG. 4, from the lengths of the coils. FIG. 7 shows the graphs of the dependences of the coupling coefficients on the angular lengths of the coils. As can be seen from these graphs, with an increase in the lengths of the coils, the antenna coupling coefficients first increase; with a further increase in the coil lengths, the coupling coefficients decrease, while the optimal angular coil length is in the region of 130 degrees.

The claimed technical solution is as follows.

Option 1.

By any method known in the industry, the base of the coil 6 is made of a diamagnetic material. If necessary, outside the base of the coil 6, by any method known in the industry, they install, apply insulation elements, elements for laying the coil wire. On the base of the coil 6, a wire of the coil 5 of the required length is wound, using the required type of winding, the wire of the coil 5 is fixed on the base of the coil 6 by any method known in the industry. Thus, an antenna module is obtained. The required number of antenna modules is produced in the same way. The manufactured modules are installed in pairs on opposite sides on one section of the housing of the borehole resistivity meter 1 by any method known in the industry. If necessary, before installing the antenna modules on the case at the site where the antenna modules are located, recesses are made, at least one groove 4 for placing the antenna modules and at least one groove 3 for installing covers transmitting electromagnetic waves in order to organize the sealing of the antenna modules and their protection from external mechanical influences ... The wires of the coils are connected to the corresponding contacts of the printed circuit board installed on the same section of the borehole resistivity meter body, on another section of the borehole resistivity meter body. The antenna modules are sealed by any method known in the industry. Outside the antenna modules, a common cover, transmitting electromagnetic waves, is installed, separate covers, which are attached to the housing 1, to each other by any methods known in the industry.

Option 2.

By any method known in the industry, the base of the coil 7 is made of a material with high magnetic permeability. If necessary, outside the base of the coil 7, by any method known in the industry, insulation elements and elements for laying the coil wire are installed, applied. On the base of the coil 7, a wire of the coil 5 of the required length is wound, using the required type of winding, while the base of the coil 7 is equal to greater than the length of the coil, the wire of the coil 5 is fixed on the base of the coil 7 by any method known in the industry. Thus, an antenna module is obtained. The required number of antenna modules is produced in the same way. The manufactured modules are installed in pairs on opposite sides on one section of the housing of the borehole resistivity meter 1 by any method known in the industry. If necessary, before installing the antenna modules on the case at the site where the antenna modules are located, recesses are made, at least one groove 4 for placing the antenna modules and at least one groove 3 for the covers transmitting electromagnetic waves in order to organize the sealing of the antenna modules and their protection from external mechanical influences. The wires of the coils are connected to the corresponding contacts of the printed circuit board installed on the same section of the borehole resistivity meter body, on another section of the borehole resistivity meter body. The antenna modules are sealed by any method known in the industry. Outside the antenna modules, a common cover that transmits electromagnetic waves is installed, separate covers, which are attached to the housing, to each other by any methods known in the industry.

Option 3.

By any method known in the industry, at least two parts of the base of the coil 8 of such length are made from a material with high magnetic permeability so that after their installation on the housing 1 of the borehole resistivity meter with coils wound on them, the base of the coil completely surrounds the housing 1 of the borehole resistivity meter. If necessary, insulation elements and elements for laying the coil wire are installed and applied outside the parts of the coil base by any method known in the industry. A coil wire of the required length is wound onto the part of the base of the coil 8 using the required type of winding, the wire of the coil 5 is fixed on the part of the base of the coil 8 by any method known in the industry. Thus, an antenna module is obtained. The required number of antenna modules is produced in the same way. The manufactured antenna modules with wires of coils 5 wound on them are installed around the housing 1 of the borehole resistivity meter and attached to the housing 1, to each other by any methods known in the industry. If necessary, before installing the parts of the base of the coils 8 on the housing 1, at the site where the antenna modules are located, recesses are made, at least one groove 4 for placing the antenna modules and at least one groove 3 for placing the covers transmitting electromagnetic waves in order to organize the sealing of the antenna modules and protect them from external mechanical influences. The wires of the coils are connected to the corresponding contacts of the printed circuit board installed on the same section of the borehole resistivity meter body, on another section of the borehole resistivity meter body. The antenna modules are sealed by any method known in the industry. Outside the antenna modules, a common cover, transmitting electromagnetic waves, is installed, separate covers, which are attached to the housing 1, to each other by any methods known in the industry.

When making a body part with cross-sectional dimensions from the end of the body part to the installation site of the antenna modules smaller, equal to the dimensions of the cross-section of the body in the installation site of the antenna modules, it is possible to manufacture the coil base from one part in the form of a ring with the subsequent installation of the coil base on the body from the end of the part housing.

The advantages of the proposed technical solution are as follows: the antenna of the borehole resistivity meter for the telemetry system of the proposed technical solution, other things being equal, has a higher efficiency compared to antennas for the borehole resistivity meter of the telemetry system of the known technical solutions, while the antenna design for the borehole resistivity meter of the telemetry system of the claimed The technical solution allows to install pairs of antenna modules of different types on the same section of the borehole resistivity meter body: transmitting and receiving, the direction of the total magnetic moment of each pair of antenna modules can be parallel to the body axis, orthogonal to the body axis, directed at an angle to the axis of the borehole resistivity meter body.

Claims (36)

1. A method of organizing an antenna of a borehole resistivity meter for a telemetry system, including the use of a housing, which is used as a housing of a borehole resistivity meter for a telemetry system, at least one pair of antenna modules that are made operating in phase, forming a total magnetic moment and are installed on opposite sides of the housing on one and in the same section of the housing, characterized in that the antenna module is made in the form of a coil, the wire of which is wound on its base, the latter is made of a diamagnetic material from at least one part in the form of a rod, the shape of which is chosen to match the shape of the cross-section of the housing at the location antenna modules. 2. The method according to claim 1, characterized in that the length of the antenna module is chosen to allow at least one pair of antenna modules to be placed around the housing at the location of the antenna modules, which can be both transmitting and receiving. 3. The method according to claim 1, characterized in that the antenna modules are attached to the housing so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, and is at an angle to the housing axis. 4. The method according to claim 1, characterized in that the dimensions of the cross-section of the antenna module are selected to match the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module. 5. The method according to claim. 1, characterized in that the cross-section of the housing at the location of the antenna modules can be round, rectangular or of another shape. 6. The method according to claim. 1, characterized in that the cross-section of the base of the coil can be round, rectangular or other shape. 7. A method according to claim 1, characterized in that the length of the base of the coil may be greater than the length of the coil. 8. A method of organizing an antenna of a borehole resistivity meter for a telemetry system, including the use of a case, which is used as a case of a borehole resistivity meter for a telemetry system, at least one pair of antenna modules that are made operating in phase, forming a total magnetic moment and are installed on opposite sides of the case on one and in the same area of the housing, characterized in that the antenna module is made in the form of a coil, the wire of which is wound on its base, the latter is made of a material with high magnetic permeability, the type of material with high magnetic permeability is chosen to match the frequencies of electromagnetic waves used in the antenna module , the base of the coil is made of at least one part in the form of a rod, the shape of which is chosen to match the shape of the cross-section of the housing at the location of the antenna modules, which can be both transmitting and receiving. 9. The method according to claim 8, characterized in that the length of the antenna module is chosen to allow at least one pair of antenna modules to be placed around the housing at the location of the antenna modules. 10. The method according to claim 8, characterized in that the antenna modules are attached to the housing so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, is at an angle to the housing axis. 11. The method according to claim 8, characterized in that the dimensions of the cross-section of the antenna module are selected to match the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module. 12. The method according to claim 8, characterized in that the cross-section of the housing at the location of the antenna modules can be round, rectangular or of another shape. 13. A method according to claim 8, characterized in that the length of the coil base may be greater than the length of the coil. 14. A method of organizing an antenna of a borehole resistivity meter for a telemetry system, including the use of a housing, which is used as a housing of a borehole resistivity meter for a telemetry system, at least one pair of antenna modules that are made operating in phase, forming a total magnetic moment and are installed on opposite sides of the housing on one and in the same area of the housing, characterized in that the antenna module is made in the form of a coil, the wire of which is wound on its base, the latter is made of a material with high magnetic permeability, the type of material with high magnetic permeability is chosen to match the frequencies of electromagnetic waves used in the antenna module , the base of the coil is made of at least one part in the form of a rod completely surrounding the body, the shape of which is chosen to match the shape of the cross-section of the body at the location of the antenna modules. 15. The method according to claim 14, characterized in that the length of the coil is chosen to allow at least one pair of antenna modules, which can be both transmitting and receiving, to be placed around the housing at the location of the antenna modules. 16. The method according to claim 14, characterized in that the antenna modules are attached to the housing so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, and is at an angle to the housing axis. 17. The method according to claim 14, characterized in that the dimensions of the cross-section of the antenna module are selected to match the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module. 18. The method according to claim 14, characterized in that the cross-section of the housing at the location of the antenna modules can be round, rectangular or of another shape. 19. Antenna of a borehole resistivity meter for a telemetry system, including a case, which is used as a case of a borehole resistivity meter for a telemetry system, at least one pair of antenna modules, which are made operating in phase, forming a total magnetic moment and installed on opposite sides of the case, on one and the same the same section of the housing, characterized in that the antenna module is made in the form of a coil, the wire of which is wound on its base, the latter is made of a diamagnetic material from at least one part in the form of a rod, the shape of which is consistent with the shape of the section of the housing at the location of the antenna modules. 20. Antenna according to claim 19, characterized in that the length of the antenna module allows at least one pair of antenna modules, which can be both transmitting and receiving, to be placed around the body at the location of the antenna modules. 21. Antenna according to claim 19, characterized in that the antenna modules are attached to the housing so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, is at an angle to the housing axis. 22. Antenna according to claim 19, characterized in that the dimensions of the cross-section of the antenna module are matched with the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module. 23. Antenna according to claim 19, characterized in that the cross-section of the housing in the area where the antenna modules are located can be round, rectangular or of another shape. 24. Antenna according to claim 19, characterized in that the cross-section of the base of the coil can be round, rectangular or of any other shape. 25. Antenna according to claim 19, characterized in that the length of the base of the coil may be greater than the length of the coil. 26. Antenna of a borehole resistivity meter for a telemetry system, including a case, which is used as a case of a downhole resistivity meter for a telemetry system, at least one pair of antenna modules, which are made operating in phase, forming a total magnetic moment and are installed on opposite sides of the case, on one and the same the same section of the case, characterized in that the antenna module is made in the form of a coil, the wire of which is wound on its base, the latter is made of a material with high magnetic permeability, the type of material with high magnetic permeability is chosen to match the frequencies of electromagnetic waves used in the antenna module, the base the coil is made of at least one part in the form of a rod, the shape of which is coordinated with the shape of the cross-section of the body at the location of the antenna modules. 27. Antenna according to claim 26, characterized in that the length of the antenna module allows at least one pair of antenna modules, which can be both transmitting and receiving, to be placed around the body at the location of the antenna modules. 28. Antenna according to claim 26, characterized in that the antenna modules are attached to the housing so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, is at an angle to the housing axis. 29. Antenna according to claim 26, characterized in that the dimensions of the cross-section of the antenna module are matched with the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module. 30. Antenna according to claim. 26, characterized in that the cross-section of the housing at the location of the antenna modules can be round, rectangular or of any other shape. 31. Antenna according to claim. 26, characterized in that the length of the base of the coil may be greater than the length of the coil. 32. Antenna of a borehole resistivity meter for a telemetry system, including a housing, which is used as a housing of a borehole resistivity meter for a telemetry system, at least one pair of antenna modules that are made operating in phase, forming a total magnetic moment and are installed on opposite sides of the housing, on one and the same the same section of the case, characterized in that the antenna module is made in the form of a coil, the wire of which is wound on its base, the latter is made of a material with high magnetic permeability, the type of material with high magnetic permeability is chosen to match the frequencies of electromagnetic waves used in the antenna module, the base the coil is made of at least one part in the form of a rod completely surrounding the body, the shape of which is consistent with the shape of the body section at the site where the modules antenna is located. 33. Antenna according to claim 32, characterized in that the length of the coil allows at least one pair of antenna modules, which can be both transmitting and receiving, to be placed around the body at the location of the antenna modules. 34. Antenna according to claim 32, characterized in that the antenna modules are attached to the housing so that the total magnetic moment of at least one pair of antenna modules is directed parallel to the housing axis, orthogonal to the housing axis, is at an angle to the housing axis. 35. Antenna according to claim 32, characterized in that the dimensions of the cross-section of the antenna module are matched to the maximum dimensions of the space in the structure of the borehole resistivity meter intended for installing the antenna module. 36. Antenna according to claim 32, characterized in that the cross-section of the housing in the area where the antenna modules are located can be round, rectangular or of another shape.

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