RU2298802C2 - Transformer - Google Patents

Abstract

FIELD: the invention refers to the means of electromagnetic detection of objects in the ground different on electro conductivity and magnetic penetrability from rocks.

SUBSTANCE: the inductive transformer has a magnetic core with a winding out of electro conductive material and a matching amplifier. The magnetic core is fulfilled in the shape of a tube formed by parallel to each other magnetic rods isolated between themselves. The transverse calibers of the rods are several times smaller then the transverse dimensions of the tube. The tube is provided with a casing. The transformer may have three magnetic cores in the shape of tubes provided with casings. The casings are connected in such a way that their axles are mutually orthogonal and rigidly fastened for forming a tripod.

EFFECT: reduces the threshold of sensitiveness, increases accuracy of measuring.

17 cl, 5 dwg

Description

The invention relates to electromagnetic detection and can be used to detect objects in the earth that differ in electrical conductivity and magnetic permeability from the host rocks. The invention is used in geophysics to search for hydrocarbon deposits, deposits of metal ores, sources of fresh and thermal waters, diamond tubes and other minerals. It relates to devices designed for pulsed and frequency soundings with natural and artificial magnetic and electrical excitations of the electromagnetic field.

The invention is known "A method of measuring the characteristics of a magnetic field and a device for its implementation", patent RU No. 2074402 from 1995.03.07, publ. 1997.02.27, IPC G01V 3/08, G01R 33/24, containing three separate permanent core magnets, the position of the magnets on their axes is fixed using vertically and horizontally arranged elements. Using the invention, vertical and horizontal components of a constant magnetic field can be measured. The position of the magnets on their axes is fixed using vertically and horizontally arranged elements. However, the device is not intended to measure electromagnetic induction.

The invention is known "Induction Converter for a device for detecting hidden objects", patent RU No. 2085971 from 1995.03.17, publ. 1997.01.10, IPC G01V 3/08, in which a set of tubular elements isolated from each other is used in an annular frame. The invention works on the principle of a parametric measurement method, i.e. contour parameters are measured that change near conductive objects. The invention allows to increase the natural resonant frequency of a single-turn induction converter without reducing its size, which allows to increase the initial generation frequency of a tunable measuring generator. However, the proposed technical solution works on a different measurement principle. The dimensions of the frame in the analog are too large. Only the vertical component is measured.

The invention is known "Wound core of a transformer, method and device for its manufacture." Patent RU No. 2241271 from 2000.04.27, publ. 2004.11.27, IPC H01F 3/04, H01F 27/25, H01F 41/02, H01F 30/12, containing a core of magnetic tapes that has a cylindrical shape in the form of a multilayer structure, each layer is formed from a certain number of magnetic tapes with natural air gaps. The invention solves the problem of optimal redistribution of the flux of magnetic induction in the layers of a cylindrical toroidal core, the height of which is greater than the width of the tape. However, the device is not intended to measure electromagnetic induction.

Closest to the proposed technical solution is the invention "Small-sized induction converter", Patent RU No. 2073257 from 1993.08.23, publ. 1997.02.10, MPK6 G01R 33/02, containing an air multi-turn receiving loop with an inductive filter and preamplifier and resistance for high-frequency and pulsed currents, which reduces the overall level of interference at the output of the meter, made in the form of a ring ferromagnetic core with parallel windings. Such converters have high sensitivity, but are limited to a relatively narrow band of transmission frequencies and can measure only one vertical component of the magnetic field. In addition, they have a large mass.

All induction converters are based on measuring the time derivative of the flux of magnetic induction passing through a measuring circuit formed by one or many turns of an electric wire. The most significant parameters of the primary magnetic field transducer in geoelectrical exploration are the level of intrinsic noise, referred to the effective area U _w / S _eff [V / m ² ], which characterizes the real sensitivity of the induction transducer. In addition, important characteristics of the induction converter are the passband, conversion error, as well as the simplicity and speed of installation of the converter, its mass. The larger the effective area of the measuring circuit (the product of the area of the circuit by the number of turns), the greater the sensitivity of the receiving circuit. And the larger the number of turns of the receiving circuit, the narrower the bandwidth of transmission. An ideal converter is a loop induction converter. But in such converters, the mass is very large. So, a loop of 200 × 200 m from a wire with a copper cross section of 6 mm ^{2 is} characterized by a noise of about 10 ^-16 V / m ² at a natural resonance frequency of 80 kHz. However, the mass of the wire exceeds 60 kg. The layout of the loop is too laborious, and with it you can measure only the vertical component of the magnetic field. In practice, a 6 × 6 m multi-turn loop is used to measure pulsed magnetic fields. In such a loop, the effective area and bandwidth of the frequencies are sharply reduced. And also in such converters, the mass is very large (25 kg). They also have the ability to measure only one (vertical) component of the magnetic field.

The quality of the primary converters can be significantly improved through the use of magnetic cores. The parameters of these transducers depend on the material and construction of the magnetic cores.

The proposed technical solution provides the measurement of both the vertical component and the two horizontal components of the magnetic field at low values of noise normalized to the effective area at a high frequency of intrinsic resonance, which provides a wider bandwidth of transmission frequencies, increasing stability and accuracy of measurement.

The technical result of the proposed invention is to significantly reduce the sensitivity threshold and increase the measurement accuracy of the induction converter.

In the present invention realize the maximum effective area and wide working bandwidth of the transmission frequencies with a minimum ratio of noise to effective area, the minimum level of own processes and the minimum mass of the Converter. In addition, it is possible to use magnetic cores with a relative magnetic permeability of up to 1.5 · 10 ⁶ in the absence of distortion in the constant magnetic field of the Earth.

The problem is solved as follows.

An induction converter, for example, of a pulsed magnetic field, contains a magnetic core (1) with a winding of electrically conductive material (2) and a matching amplifier (3). The proposed solution is characterized in that the induction transducer is equipped with at least one magnetic core (1) with a winding of electrically conductive material (2), the magnetic core being made in the form of a tube ("d"), which is formed by parallel magnetic rods (4) isolated from each other, while the transverse dimensions ("a", "b") of the rods are at least several times smaller than the transverse dimensions of the pipe "d". Magnetic rods can be made, for example, from a film of a magnetic circuit. In the induction converter, the magnetic core with a winding can be equipped with a protective casing (5). As an embodiment of an induction converter, for example, a pulsed magnetic field, a converter is proposed comprising a magnetic core with a winding of electrically conductive material and a matching amplifier, which is equipped with three magnetic cores (see Figure 3), each of which is equipped with a winding of electrically conductive material and a matching amplifier . Moreover, each magnetic core is made in the form of a pipe, which is formed by parallel to each other magnetic rods isolated between each other, while the transverse dimensions of the rods are at least several times smaller than the transverse dimensions of the pipe (see Fig. 1b), the magnetic rods are made, for example, from a film of a magnetic circuit with a thickness of 2 to 50 micrometers, each tube is equipped with a protective casing (5), the casings are connected so that their axes are mutually orthogonal, while the casings are rigidly fastened or secured with company around the axis with the help of the frame (6) to form a tripod from them, providing a stable position of the induction converter on the surface of the earth or at the bottom of the reservoir. Magnetic rods are made, for example, of layers parallel to the transverse and longitudinal directions of the magnetic core film. The cores can be directly connected to each other (see Fig. 1b), and can be connected by means of a current-insulating frame (7) in the form of a pipe (see Fig. 1c). To increase the transverse dimensions of the magnetic core, the ends of the pipe formed from the rods (4) can be equipped with magnetic tips (8), the transverse dimensions of which are several times larger than the transverse dimensions of the cores (1). Each rod (4) can be equipped with an accelerometer (9) and / or a flux gate (10) to determine gravity and magnetic field along the axis of each magnetic core. Magnetic cores are provided, for example, in the central part with windings in the form of sectioned multi-turn receiving coils (2). The radial thickness "c" of the magnetic rods (4) is usually selected in the range from 0.001 diameter of the magnetic core to 0.5 diameter "d" of the magnetic core (1). The film thickness of the magnetic circuit is usually from 2 to 50 micrometers. As an insulator between the magnetic rods, both an air gap, which is less than or equal to ten times the width of the magnetic rod, and an insulator are used. The width "a" of the magnetic rod is usually equal to or less than 0.2 diameter "d" of the magnetic core (1). Magnetic cores can be equipped with calibration windings adjacent to them on both sides (11). Calibration windings (11) are connected to the winding (2) of each magnetic core during calibration. A generator of rectangular and exponential current pulses is simultaneously and / or alternately connected to the winding (2) of the magnetic core. The induction converter may be provided with a switching device (12) and / or a control device (13).

In the proposed induction converter, for example, a hollow cylinder made of a magnetic core with high magnetic permeability, the thin shell of which is divided into many parallel strips forming a cylinder, is the optimal core (1). The effective magnetic permeability (magnetic permeability of the mold) depends on the ratio of the length of the cylinder to its diameter. It is limited to the linear region of the hysteresis characteristic. Those. effective magnetic permeability is selected maximum, at which the strict linearity of the process of magnetic field conversion is still observed. Since the thickness of the shell assembled from the rods (4) is small, the mass of the core (1) is minimal. The eddy currents inside the shell are small due to the fact that it is dissected into many thin strips made of layers of the thinnest film of the magnetic circuit. Therefore, the level of intrinsic processes here is the lowest for magnetic core transducers.

The effective area is proportional to the product of the number of turns by the cylinder cross-sectional area and effective magnetic permeability. The ratio of the noise of the converter to the effective area of the converter depends on the mass of the winding and does not depend on the number of turns. The number of turns, ceteris paribus, to which the bandwidth passes, is selected so that the noise level of the winding (2) is comparable with the noise level of the amplifier (3).

The invention is illustrated by the following drawings.

On figa, b, c shows a magnetic core with coils of the receiving frame of the block of magnetic field converters. On figa - side view; on figb is a cross section of the core; on figv is a cross section of the core with the fixed rods on the frame.

Figure 2 shows a magnetic core with coils of the receiving frame of a block of magnetic field converters with magnetic tips.

Figure 3 shows an induction magnetic field transducer containing three magnetic cores, each of which is equipped with windings of electrically conductive material and a matching amplifier. Core casings are rigidly fastened.

Figure 4 shows a block diagram of an induction magnetic field converter, where: 2 - coils with a winding of electrically conductive material (receiving frame), 9 - accelerometer, 10 - ferrozod, 11 - calibration coils, 3 - matching amplifier, 12 - switching device , 13 - control device.

Figure 5 shows a perspective view of an induction magnetic field transducer containing three magnetic cores, each of which is equipped with windings of electrically conductive material and a matching amplifier. The induction converter has three mutually orthogonal axis of the cores, which are randomly oriented relative to the selected rectangular coordinate system - x, y, z.

The proposed induction converter of a pulsed magnetic field is implemented as follows.

The induction converter includes a magnetic core (1) with six sectioned 700-turn receiving coils (2), 50 turns in each section in the central part, and two 50-turn calibration coils (8) adjacent to them on both sides, as well as a preliminary an amplifier (3), a switching device (12) and a control device (13).

A magnetic core (1) with receiving coils (2) consists of rods (4) (see Fig. 1b, c), which is a pipe with a diameter of "d", formed by 14 adjacent rods (4), 5 × 5 × 1000 mm, glued from 140 layers (5 × 1000 mm) of a film (25 micrometers) of the GM503A magnetic circuit. The inner diameter of the plastic pipe (7) to which the rods are glued is 20 mm. The outer diameter of the core (4) is 35 mm. A cobalt alloy magnetic core has a maximum magnetic permeability of 1,500,000. Cobalt alloy magnetic core layers have an insulating film on their surface that is formed as a result of annealing.

The induction converter has the highest sensitivity (effective area) with minimal inherent processes. The effective area of the induction receiver with a cylindrical core is determined by the magnetic permeability of the form, which depends on the ratio of the length of the core (1) to its diameter. With an increase in this ratio (with a constant core diameter), the sensitivity of the receiver increases and, at the same time, the dependence on the magnetic permeability of the magnetic circuit. Usually, such a ratio of the length to the diameter of the core is chosen so that the sensitivity of the receiver does not depend on the magnetic permeability of the magnetic circuit, since the latter is subject to the influence of external temperature and mechanical influences. The smaller the ratio of the length of the core (1) to its diameter, the greater the stabilizing effect of demagnetization caused by the relative proximity of the poles of the core, and the smaller the effective area. In addition, the rectangular shape of the hysteresis characteristic of the magnetic circuit leads to the need to reduce the ratio of the length of the core to its diameter in order to obtain a linear dependence of the magnetic induction "B" on the field "N" in a wide range of changes in the intensity of the projection of the constant magnetic field of the Earth onto the axis of the transducer "c". In other words, independence of the measurement results from the orientation of the transducer in a constant magnetic field of the Earth is achieved.

Due to the high magnetic permeability of the core (1), it became possible to replace a continuous cylinder from a magnetic circuit with a pipe of individual rods (4) with a thickness of 5 mm without reducing the effective area of the receiver. Thus, high sensitivity and stability of the receiver are achieved with a relatively small mass of the magnetic circuit (about 2500 g). In order not to develop intense eddy currents in the cross sections of the pipe, it is built of separate rods, between which there are no galvanic contacts. Thin film layers oriented perpendicular to the pipe surface also impede eddy currents in the tubular core (1). The thin-film structure and small transverse dimensions of the rods (5 × 5 mm) significantly reduce the intensity of intrinsic processes directly in the rods (4).

The receiving coils (2) connected in series are connected to the non-inverting inputs of the measuring operational amplifier (3). At the input of the amplifier there is a switched symmetrical voltage divider and parallel to it a resistor Rcr with a resistance of about 180 kOhm, which introduces the receiving winding (2) into critical mode.

The sensitivity of the induction converter depends on its effective area and the intrinsic noise of the receiving winding (2) and amplifier (3). It is characterized by the ratio of noise power in watts (or V ² ), in the frequency band of 1 Hz, referred to the effective area in square meters. For a given mass of copper in the winding, the signal-to-noise ratio of induction receivers does not depend on the number of turns of the winding (2). In fact, with an increase in the number of turns, for example, 2 or 4 times, the resistance of the winding (2) will increase. The voltage of the useful signal will increase by 2 times and the voltage of the inherent noise of the receiving winding will increase by the same amount (2). However, with an increase in the number of turns, the working frequency band of the converter narrows.

The total noise of the amplifier (3) depends on the resistance of the receiving winding (2), the intrinsic noise of the matching amplifier (3) in voltage and current. They are minimal at low winding resistance (2).

In the used amplifier (3), the calculated total noise at the resistance of the receiving winding of 50 Ohms is close to 1 nV / Hz ^1/2 . The effective area of the receiver for the adopted parameters of the receiving coils (without an amplifier) is 1170 m ² . The rated noise of the converter (with an amplifier) normalized by the effective area does not exceed 10 ^-12 V / Hz ^1/2 m ² . Natural Resonance Frequency: 5300 Hz. With such a high frequency of natural resonance, an ideal linear amplitude-frequency characteristic and zero phase-frequency characteristic in the frequency band from 100 Hz and below are ensured.

Such a sensitivity of induction converters with a linear frequency response is realized only when multi-turn loops with a diameter of up to 5 m are used. Such loops have several times more mass and allow measuring only the vertical component of the magnetic field.

Magnetic tips (8) reduce the "magnetic grounding resistance" of the open magnetic circuit and thereby further increase the magnetic flux in the core (1).

Calibration with rectangular pulses provides control over the own processes in the transducer, calibration with an exponential signal allows you to control the transformation of a magnetic field that decays exponentially.

Typically, the magnetic field is transformed along the selected rectangular coordinate axes: vertical - z and two horizontal - xy. As a rule, one of the components of the magnetic field is anomalous and small in magnitude, and the other two are normal, much larger than the anomalous component. Since when measuring the anomalous component, an additional error in the transformation of the magnetic field arises due to orientation errors of the transducer axes, as a result of this, projections of large normal components to this axis are added to the anomalous component.

In the proposed device, three orthogonal components of the magnetic field are converted at the same angles to the studied (flat) area of the earth (see Figure 4). In this case, three components of a magnetic field that are close in magnitude and in signal / noise ratio are measured. The magnetic field vector is calculated from these three components, and the desired components are found as the projections of the magnetic field on the xyz axis. As a result, the errors in determining the anomalous component of the field are substantially reduced, and the signal-to-noise ratio for each of the measured components of the magnetic field is improved.

Usually the measurement is carried out along the selected rectangular coordinates xyz. For this, during the installation operation of three rigidly fixed induction converters, it is necessary to simultaneously achieve a stable position of the system of induction converters and accurate orientation of this system to the cardinal points. This is a difficult operation that takes a lot of time. In the proposed device, the installation task is only to achieve a stable position of the induction converter. No orientation required. This is achieved by the fact that along the axis of each of the three cores with windings, matching amplifiers and protective covers using accelerometers (9), projections of gravity on each axis are recorded. According to the readings of the accelerometers, the deviation of the induction converter from a horizontal position is determined. In addition, along the axis of each core with the help of a flux gate (10), projections of the Earth's constant magnetic field on the xyz axis of the induction transducer are recorded. According to the readings of the fluxgate and accelerometers, the azimuth of the transducer system is determined. These simple measurements replace the time-consuming operation of orienting the transducer system on the ground. Thus, the measurement of both the vertical component and the two horizontal components of the magnetic field is provided.

Thus, the induction converter has a greater real sensitivity compared to multi-turn loops with an air core (lower noise threshold of the converter), provides a wider operating frequency band (from 0.0001 Hz to 10 kHz) and provides higher measurement accuracy (reduction in intensity own processes). At the same time, the mass of the device is reduced, its compactness is ensured, the device does not require precise reference to terrain due to orthogonally installed cores, in which there is an indicator with rough characteristics for measuring gravity and the Earth's magnetic field.

Claims (17)

1. An induction magnetic field transducer comprising a magnetic core with a winding of electrically conductive material and a matching amplifier, characterized in that the induction transducer is equipped with at least one magnetic core with a winding of electrically conductive material, in which the magnetic core is made in the form of a pipe which is formed parallel to each other to each other with magnetic rods isolated between each other, while the transverse dimensions of the rods are at least several times smaller than the transverse dimensions of the pipe. 2. The induction converter according to claim 1, characterized in that the magnetic core with a winding is equipped with a protective casing. 3. The induction Converter according to claim 1, characterized in that the magnetic rods are made of parallel in the transverse and longitudinal directions of the layers of the film of the magnetic circuit. 4. The induction converter according to claim 1, characterized in that to increase the transverse dimensions of the magnetic core, the ends of the pipe are equipped with magnetic tips, the transverse dimensions of which are several times larger than the transverse dimensions of the cores. 5. An induction magnetic field transducer comprising a magnetic core with a winding of electrically conductive material and a matching amplifier, characterized in that the induction transducer is equipped with three magnetic cores, each of which is equipped with a winding of electrically conductive material and a matching amplifier, each magnetic core being made in the form of a pipe , which is formed by parallel to each other magnetic rods, isolated from each other, while the transverse dimensions of the rods, at least in a number of times smaller than the transverse dimensions of the tube, each tube is provided with a protective casing, casings are connected so that their axes are mutually orthogonal, wherein the housings are rigidly attached to form one of the tripod, which provides a stable position inductive transducer on the ground or water bottom. 6. The induction converter according to claim 5, characterized in that each rod is equipped with an accelerometer and / or a flux probe for determining gravity and magnetic field along the axis of each magnetic core. 7. The induction converter according to claim 5, characterized in that the magnetic cores are provided in the central part with windings in the form of sectioned multi-turn receiving coils. 8. The induction Converter according to claim 5, characterized in that the magnetic rods are made of parallel in the transverse and longitudinal directions of the layers of the film of the magnetic circuit. 9. The induction converter according to claim 8, characterized in that the radial thickness of the magnetic rods is selected in the range from 0.001 to 0.5 of the diameter of the magnetic core. 10. The induction converter according to claim 8, characterized in that the width of the magnetic rod is equal to or less than 0.2 diameter of the magnetic core. 11. The induction converter according to claim 8, characterized in that the film thickness of the magnetic circuit is from 2 to 50 microns. 12. The induction converter according to claim 5, characterized in that as an insulator between the magnetic rods use an air gap that is less than or equal to ten times the width of the magnetic rod. 13. The induction converter according to claim 5, characterized in that the magnetic cores are provided with calibration windings adjacent to them on both sides. 14. The induction converter according to item 13, wherein the calibration windings are connected to the winding of each magnetic core for the duration of the calibration. 15. The induction converter according to claim 14, characterized in that the generator of rectangular and exponential current pulses is simultaneously and / or alternately connected to the winding of the magnetic core. 16. The induction converter according to claim 5 or 13, characterized in that it is equipped with a switching device. 17. The induction converter according to clause 16, characterized in that it is equipped with a control device.

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