RU160149U1 - MAGNETIC FIELD SENSOR - Google Patents

Abstract

The magnetic field sensor, which is a three-axis receiving antenna, consisting of mutually orthogonally located first, second and third inductors, the ends of which are equipped with taps for connection with an indicator device, characterized in that the first, second and third inductors are made of printed conductors on the first, the second and third boards of fiberglass, respectively, having the same thickness, and on the first board, the conductors for the first, second and third are made by printed conductors th induction coils, as well as the first circular hole with a diameter L, around which the first inductor is placed in the form of four equal segments of a circle with a diameter L> L with a center coinciding with the center of the first circular hole with a diameter L in this board, and cutouts along the thickness of the boards in two planes perpendicular to each other, passing between a circular hole with a diameter L and the boundaries of the corresponding segments of a circle with a diameter L with the possibility of inserting the second and third boards, and the second round is made in the second board a hole with a diameter L, around which a second inductor is placed in the form of two equal segments of a circle with a diameter L = L> L with a center coinciding with the center of the second round hole of a diameter L in this board, cutouts along the thickness of the boards passing through the boundaries of circle segments with a diameter L with the possibility inserts a third board into them, in which a third circular hole with a diameter L is made, around which a third inductor is placed in the form of a circle with a diameter L = L = L> L with a center coinciding with the center of the third round hole bore diameter L in this

Description

The utility model relates to the technique of radio measurements and can be used as a sensor when measuring the intensity of the magnetic component of the electromagnetic radiation of the radio frequency range from electrical installations and antennas in assessing the degree of biological hazard of electromagnetic radiation.

Various sensors are known that are used in magnetic field meters, in particular, using the Hall effect, using magnetoresistors, magnetodiodes and magnetotransistors, as well as sensors using a change in the magnetic permeability of the core of the coil (flux probe), superconducting quantum interference sensors (SQUID) and magnetoelectric sensors, sensors operating on the classical induction method.

A known magnetic field sensor [RU 2300827, C2, H01L 43/08, 06/10/2007], consisting of magnetoresistive strips having easy magnetization axes and combined into two branches of the bridge circuit, as well as from the stripes of two film ring-shaped magnetic circuits located in the plane, transverse slit gaps of each of which are magnetoresistive strips of the corresponding branch of the bridge circuit, while the magnetic system is magnetically connected to the magnetic cores, consisting of one common and / or several separate micromagnets creating Zorach magnetic cores, magnetic field intensity vector are perpendicular to the axes of easy magnetization.

The disadvantage of the sensor is the insufficient measurement range of magnetic fields.

Also known is a magnetic field sensor [RU 43654, U1, G01R 33/038, 01/27/2005] containing a thin magnetic film with an exciting and measuring windings, in which the axis of the exciting winding is parallel to the axis of easy magnetization of a thin magnetic film, and the axis of the measuring winding is parallel to the axis difficult magnetization of a thin magnetic film, and a permanent magnet that creates a constant bias field equal to the anisotropy field of the thin magnetic film, while the permanent magnet is mounted on a rotary device, providing installation of ION magnetizing field with respect to the axis of easy magnetization of the magnetic thin film at an angle at which the predetermined measurement accuracy.

The disadvantage of this device is its relatively large complexity.

The closest in technical essence to the proposed one is an electromagnetic field sensor, designed for measuring the characteristics of electromagnetic fields emitted by devices with power supply, used in the meter of electric and magnetic fields P3-70 / 1 [Magnetic field meter, No. in the State Register 43290-09, Scientific-Production Enterprise “Cyclone-Test”, http://www.ciklon.ru, 2015], which is a magnetic antenna of the radio frequency range, in which a frame made up of two is used as a frame molded plastic parts area in which grooves are arranged orthogonal coils, the ends of which are provided with taps for connection to a display device, wherein, the coils are coated with a protective material from damage.

This device is closest in technical essence and the number of common features to the claimed utility model, which is why it is accepted as the closest analogue.

The disadvantage of this device is the relatively high complexity, due to the fact that its design is composed of two molded plastic parts of a sphere, in the orthogonal grooves of which are placed inductors, ensuring the identical characteristics of which during production presents technological difficulties.

The problem that is solved in a utility model is to create a simple and lightweight sensor that can be used in portable measuring instruments.

The technical result that is provided by the implementation of the utility model is to simplify the device.

The problem is solved, and the required technical result is achieved by the fact that, in the magnetic field sensor, which is a three-coordinate receiving antenna, consisting of mutually orthogonally located first, second and third inductors, the ends of which are equipped with taps for connection with an indicator device, according to a utility model , the first, second and third inductors are made of printed conductors on the first, second and third boards of fiberglass, respectively, having the same thickness well, wherein, in a first board made printed conductors taps for the first, second and third inductors and the first circular hole diameter L, around which is located the first inductor in the form of four equal segments circle diameter L _1> L with the center coinciding with the center of the first circular hole of diameter L in this board, and cutouts along the thickness of the boards in two planes perpendicular to each other, passing between a circular hole with a diameter L and the boundaries of the corresponding diameter segments of the circle ohm L ₁ with the possibility of inserting the second and third boards, moreover, in the second board there is a second circular hole with a diameter L, around which a second inductor is placed in the form of two equal segments of a circle with a diameter of L ₂ = L ₁ > L with a center coinciding with the center of the second a circular hole of diameter L in this board, cutouts along the thickness of the boards passing through the boundaries of segments of a circle with a diameter of L ₂ with the possibility of inserting a third board into them, in which a third circular hole with a diameter of L is made, around which a third coil is placed and inductances in the form of a circle with a diameter of L ₃ = L ₁ = L ₂ > L with a center coinciding with the center of the third round hole of diameter L in this board, while the second board is made round with two opposite boundary recesses at the edges, providing installation in the first circuit board, the third circuit board is made round with four restrictive recesses evenly spaced along the edges and providing installation in the second and first circuit boards, elements are installed at the points where the circuit boards touch each other, ensuring their rigid connection, and sectors of the first and second coils are interconnected through openings in the circuit boards which are mounted in the recesses between these sectors.

As shown below, the essence of the proposed utility model is based on the fact that it is more practical and cheaper to manufacture the sensor in the form of a design in which three orthogonally located coils are made by printed conductors on fiberglass boards, the special shape of which allows them to be connected perpendicular to each other, to ensure continuity turns, a single geometric center of all coils and mounting boards with each other. In this case, it is not necessary to wind the inductors and perform operations to insulate the conductor and cover the coils with protective material from damage. An additional advantage of the proposed design is its low weight, which is important when developing a portable measuring device with a similar sensor.

The drawing shows:

in FIG. 1 is a general view of a magnetic field sensor;

in FIG. 2 - magnetic field sensor, top view;

in FIG. 3 - magnetic field sensor, front view;

in FIG. 4 - the first board of the magnetic field sensor;

in FIG. 5 - the second board of the magnetic field sensor;

in FIG. 6 - the third board of the magnetic field sensor.

The magnetic field sensor is a three-axis receiving antenna, consisting of mutually orthogonally located first 1, second 2 and third 3 inductors, the ends of which are equipped with taps 4 for connection with an indicator device.

A feature of the proposed magnetic field sensor is that the first 1, second 2 and third 3 inductors are made of printed conductors in the form of circles on the first 5, second 6 and third 7 boards of fiberglass, respectively, having the same thickness.

In the magnetic field sensor on the first circuit board 5, conductors 4 for the first 1, second 2, and third 3 inductors are made by printed conductors, as well as a first circular hole 8 of diameter L, around which the first inductor 1 is placed in the form of four equal segments 9 of a circle of diameter L ₁ > L with the center coinciding with the center of the first round hole 8 of diameter L in the first board 1, and cutouts 10 along the thickness of the boards in two planes perpendicular to each other, passing between the first round hole 8 of diameter L and the boundaries, respectively splicing segments 9 of a circle with a diameter of L ₁ with the ability to insert a second 6 and third 7 boards.

In the second board 6 of the magnetic field sensor, a second circular hole 11 of diameter L is made, around which a second inductor 2 is placed in the form of two equal segments 12 of a circle of diameter L ₂ = L ₁ > L with a center coinciding with the center of the second round hole 11 of diameter L in a second circuit board 6 and the recesses over the thickness of boards passing through the circle segments 12, 13 border the diameter L ₂ to be inserted therein a third board 7, which holds the third circular hole 14 of diameter L, around which is placed a third coil inductance 3 vnosti diameter L ₃ = L ₁ = L _2> L with the center coinciding with the center of the third circular hole 14 of diameter L in the third board 7.

In addition, in the magnetic field sensor, the second board 6 is made round with two opposite restrictive recesses 15 at the edges, providing installation in the first board 5, the third board 7 is made round with four restrictive recesses 16, evenly spaced along the edges and providing installation in the second 6 and the first 5 boards, at the points where the boards touch each other, elements 17 are installed that provide their rigid connection, and neighboring sectors in the first 1 and second 2 inductors are connected to each other through holes 18 in the square Atach, which are installed in the cutouts between these sectors.

The magnetic field sensor is manufactured and operates as follows.

The manufacturing process of the device consists of a once performed operation of wiring boards, then manufacturing boards in the required quantity and assembly of the device. To protect against external influences, the device can be installed in a protective housing.

The first board 5 is the basis for the design of the magnetic field sensor. Four equal segments of a circle 9 of diameter L ₁ > L are applied on it with a center coinciding with the center of the first round hole 8 of diameter L in the first circuit board 1, forming the first inductance coil 1, as well as the taps 4 for the first 1, second 2, and printed conductors third 3 inductors.

In the first board 5, cutouts 10 are made along the thickness of the boards in two planes perpendicular to each other, passing between the first circular hole 8 of diameter L and the boundaries of the corresponding segments 9 of a circle of diameter L ₁ with the possibility of inserting a second 6 and third 7 boards. The length and width of the cutouts correspond to the dimensions of the other two boards, which allows you to insert these boards into them. Two other circuit boards also have inductors made by printed conductors. On the second board 6 - in the form of two segments, on the third board 7 - in the form of a full circle. The first 5 and second 6 boards have cutouts, and the second 6 and third 7 boards have restrictive recesses 15, 16, respectively. This allows the third board 7 to be inserted into the second board 6 perpendicular to each other to the restrictive recesses and then both boards are inserted perpendicularly to the first board 5 also to the restrictive recesses.

In places where the boards touch each other, elements 17 are installed that provide their rigid connection, for example, in the form of metallized pads intended for soldering.

Adjacent sectors in the first 1 and second 2 inductors are connected by a thin wire to each other through holes 18 in the boards, which are installed in the cutouts between these sectors.

The magnetic field sensor operates as follows.

In the first 1, second 2 and third 3 inductors under the influence of an alternating magnetic field induced EMF. The EMF level is directly proportional to the frequency and level of magnetic induction. To determine the characteristics of magnetic fields, a measuring device is used, which is connected to the taps 4 made by printed conductors for the first 1, second 2, and third 3 inductors.

Thus, since it is more practical and cheaper to manufacture the sensor in the form of a design in which three orthogonally located coils are made by printed conductors on fiberglass boards, the special shape of which allows them to be connected perpendicular to each other, to ensure continuity of turns, a single geometric center of all coils and mounting boards with each other, regarding the closest technical solution. This allows you to achieve the desired technical result, which consists in simplifying the device.

Claims (1)

The magnetic field sensor, which is a three-axis receiving antenna, consisting of mutually orthogonally located first, second and third inductors, the ends of which are equipped with taps for connection with an indicator device, characterized in that the first, second and third inductors are made of printed conductors on the first, the second and third boards of fiberglass, respectively, having the same thickness, and on the first board, the conductors for the first, second and third are made by printed conductors second inductors, and the first circular hole diameter L, around which is located the first inductor in the form of four equal segments circle diameter L _1> L with the center coinciding with the center of the first circular hole diameter L in this circuit board, and recesses thickness boards two planes perpendicular to each other, extending between the circular hole diameter L and the boundaries of the respective segments circumferentially diameter L ₁ to be inserted the second and third circuit boards, said second torsion performed in the second board cular hole diameter L, around which is placed the second inductor in the form of two equal segments circle diameter L ₂ = L _1> L with the center coinciding with the center of the second circular hole diameter L in this circuit board, the recesses thickness boards passing through the boundary circle segments diameter L ₂ with the possibility of inserting a third board into them, in which a third circular hole of diameter L is made, around which a third inductor is placed in the form of a circle with a diameter of L ₃ = L ₁ = L ₂ > L with a center coinciding with the center of the third a circular hole of diameter L in this circuit board, wherein the second circuit board is made round with two opposite boundary recesses at the edges providing installation in the first circuit board, the third circuit board is made round with four restrictive recesses uniformly spaced along the edges and providing installation in the second and first circuit boards, in places where the boards touch each other, elements are installed that ensure their rigid connection, and neighboring sectors of the first and second inductors are interconnected through holes in the boards ah, which are installed in the cutouts between these sectors.

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