RU2647482C1 - Method for protecting metallic ferromagnetic object from magnetometric detection - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: method for protecting a metallic ferromagnetic object from magnetometric detection, that comprises transferring the ferromagnetic material, from which the protected object is made into an alternating periodic magnetized state, includes mounting the elements of the magnetic system on the object surface on permanent magnets with alternating magnetization directions with a magnetic flux closing through the object body, that the intensity of the magnetic field produced by the elements of the magnetic system provides the magnetization of the structure material is, at least, 2-3 times higher than the value of the magnetization that arises in the material of the object from the action of an external magnetic field. The total magnetic moment of the installed magnetic system on permanent magnets is minimal for a given object design. The integral magnetic moment of the ferromagnetic object in the external magnetic field with the installed magnetic system is, at least, 3 times lower than the integral magnetic moment of the object without the installed magnetic system, regardless of the direction of the external magnetic field application. The external magnetic field is a geomagnetic field.

EFFECT: expanding the arsenal of technical means to protect the object from magnetometric detection by transferring the ferromagnetic material into a piecewise-continuous alternating periodic magnetized state.

4 cl, 7 dwg

Description

The invention relates to the field of counteraction to means of magnetometric detection of ferromagnetic objects and can be used to protect ships, cars and other technical objects.

To protect metallic ferromagnetic objects from magnetometric detection, all known technical solutions are reduced either to demagnetization of a magnetized object, or to the creation of a compensation field of the opposite sign.

A known method of the demagnetization of a vessel, based on the electromagnetic processing of the hull in a compensated magnetic field of the Earth by means of an alternating magnetic field created by the working winding when moving the ship through it or when moving the working winding along the longitudinal axis of the vessel, while in the process of electromagnetic processing the movement of the ship through the working winding or moving the working winding along the longitudinal axis of the vessel is carried out at a distance not exceeding the length of the vessel, before moving the intensity of the alternating magnetic field smoothly increases from zero to maximum intensity, during the process of moving the intensity of the alternating magnetic field is kept maximum and unchanged, and after completion of the movement, the intensity of the alternating magnetic field is gradually reduced to zero intensity. During the electromagnetic processing time, the Earth's magnetic field is compensated in a volume exceeding the basic dimensions of the vessel, and an alternating magnetic field is created in the working winding, the size of which in the direction of movement does not exceed half the length of the vessel's hull.

The method reduces the complexity of demagnetization of vessels with a ferromagnetic hull and the cost of technological equipment that provides the process of demagnetization (Patent RU 2583257 MPK B63G 9/06, H01F 13/00, published 05/10/2016).

A known method of protecting ships from non-contact magnetic mines, implemented by the demagnetizing device of the vessel by creating a compensation field of the opposite sign. The method consists in the fact that the signals from magnetometric sensors mounted on the hull of the vessel enter the automatic current regulator in the windings of the demagnetizing device, which generates a control signal proportional to the average value of the magnetization of the hull. The specified signal controls an adjustable source of electrical power compensation sectionalized windings of the demagnetizing device, resulting in continuous compensation of the external static magnetic field of the vessel with high accuracy. The technical result is an increase of not less than 1.5 times the accuracy of the compensation of the external static magnetic field of the vessel (Patent RU 2381139, IPC B63G 9/06, published 02/10/2010).

The technical problem to which the invention is directed is to expand the arsenal of technical means that protect the object from magnetometric detection by transferring ferromagnetic material to a piecewise-continuous alternating periodically magnetized state.

The solution of the technical problem posed is achieved by a method of protecting a metallic ferromagnetic object from magnetometric detection by converting the ferromagnetic material from which the protected object is made into an alternating periodic magnetized state, including the installation of permanent magnet elements on the surface of the object with alternating directions of magnetization with an object that closes through the body of the object magnetic flux so that the magnetic field generated elements of the magnetic system, provides the magnetization value of the material of the structure is at least 2-3 times higher than the value of the magnetization that arises in the material of the object from the action of an external magnetic field, while the total magnetic moment of the installed permanent magnet magnetic system is minimal for a given object design, and the integral magnetic moment of a ferromagnetic object in an external magnetic field with an installed magnetic system is at least 3 times lower than the integral magnetic moment object without installing the magnetic system, regardless of the application direction of the external magnetic field. An external magnetic field is a geomagnetic field. An external magnetic field represents the field created by the electrical network of an object. An external magnetic field is a field created by the magnetostrictive magnetization of parts of an object arising from mechanical loads during operation.

The invention solves the problem of reducing the integral magnetic moment of metallic ferromagnetic objects (structures) and is not intended to demagnetize the body of the object. The claimed method acts on the ferromagnetic material of the casing in such a way as to minimize its magnetic susceptibility to the effects of the Earth's magnetic fields, airborne sources, magnetic fields arising in the material during movement and mechanical loads.

The invention consists in periodically magnetizing an object of soft magnetic material (steel) using permanent magnets to reduce its integral magnetic moment and make it difficult to detect by magnetometric methods.

The invention is illustrated by drawings, where

in FIG. 1 schematically shows the distribution of the magnetic field lines in the transverse plane under the influence of the earth field,

in FIG. 2 - conditional distribution of magnetic field lines in the transverse plane with permanent magnets installed in alternating order,

Fig. 3 shows a diagram of an experiment for magnetizing a steel cube with a compensating magnetic field applied perpendicular to the direction of magnetization, where 1 is the source of the external magnetic field, 2 and 3 are sources of the perpendicular applied magnetic field, 4 is the object of the experiment,

in FIG. 4 is a diagram of an experiment to study the effect of permanent magnets installed on the inner surface of a ferromagnetic object on the value of the integral magnetic moment of a given object in external magnetic fields, where 5 is the measuring coil of the Helmholtz coil, 6 is the magnetizing coil of the Helmholtz coil, 7 is a ferromagnetic object, 8 is a microwebermeter F-192, 9 - a constant current source,

in FIG. 5 presents the object of study, where 10 is a cylindrical steel case, 11 are removable steel covers, 12 are permanent magnets,

in FIG. 6 is a graph of the experimental dependence of the integral magnetic moment of the object of study on the external magnetizing field directed along the axis of rotation of the object,

in FIG. 7 is a graph of the experimental dependence of the integral magnetic moment of the object of study on the external magnetizing field directed perpendicular to the axis of rotation of the object.

Schematically, the magnetization process of a massive ferromagnetic object is shown in FIG. 1. In the case when the object is magnetized along the largest linear dimension by the Earth’s field, then the north pole is concentrated at one end and the south pole at the other. The distribution of the lines of force around the object is barrel-shaped.

The object acquires a large magnetic moment. The perturbation of the geomagnetic field is recorded at distances exceeding the size of the object itself.

When permanent magnets are installed along the object’s body with an alternating direction of magnetization (Fig. 2), taking into account that magnetization is a vector quantity, the integral of the magnetic moment over the body volume tends to zero.

The lines of force of the magnetic field are pressed against the surface of the housing. In this case, magnetic field perturbations will be recorded only at distances comparable to the sizes of sections with different magnetizations, which is thousandths of the linear dimensions of the object itself. At considerable distances, of the order of 0.1-1 from the linear dimensions, the intrinsic magnetic field of the object also tends to zero. In addition, if the magnetization level of each local region is close to saturation values, then the magnetic susceptibility of the material tends to zero. Accordingly, neither the geomagnetic field, nor other external sources with a field level lower than that provided by the installed magnets, can not have any tangible effect on the magnetization of the body. The magnetization of the housing by an alternating field will thereby make it quasi-magnetic. Moreover, the direction of the external field with this arrangement of permanent magnets does not matter.

In FIG. 3 is a diagram of an experiment illustrating the claimed effect of weak susceptibility to an external magnetic field from source 1. The effect of a compensating magnetic field created along the X axis by permanent magnets 2 and 3, applied directly to sample 4, on the possibility of magnetizing a sample of steel 10864 GOST 11036- is studied. 75 by an external magnetic field from the source along the Y axis for two different values of the intensity of the external magnetic field N. Different values of the strength of the external magnetic field were achieved by measuring Vary the distance to the source of the external magnetic field. The experiment was carried out for two distance values equal to 102 and 72 mm, which corresponded to the strength of the external magnetic field along the Y axis 160 and 290 E.

The measured value of the magnetic field strength in the center of the gap between magnets 2 and 3 in the absence of an external magnetic field source and an object is 2660 Oe.

The results were monitored by measuring with the help of a TPU millilitaslameter (registered in the State Register of Measuring Instruments under No. 28134-04) the values of the magnetic induction vector component along the Y axis on the upper face of the sample at the center of the surface.

The measured value of the induction at the control point on the surface of the sample is composed of an external magnetic field and a component of the magnetization of the sample in an external field. So, with an external magnetic field strength of 160 Oe, the increment of the magnetic induction value at the control point was 25–16 = 9 mT (56%), and for an external magnetic field strength of 290 Oe, the increment of the magnetic induction at the control point was 47–29 = 18 mT (62%).

When a magnetic field of 2660 Oe was applied to the sample in the direction transverse to the external field, the magnetic induction component of the sample magnetization disappeared, moreover, for both considered values of the external field strength. The sample was not magnetized in the direction of the external field. The magnetic moment of the sample in the direction of the external field became equal to zero.

An example implementation of the invention is illustrated by an experiment conducted on a measuring installation (Fig. 4). The installation is a Helmholtz coil with an average radius of 200 mm, having on one frame both magnetizing windings 6, connected to a direct current source 9 and creating an external magnetic field (60 turns of copper wire), and measuring windings 5 (100 turns of copper wire) connected to the F-192 microwebermeter 8. The magnetizing and measuring windings are coaxial. During measurements, the object of study 7 was located in the center of the Helmholtz coil. The measurements were carried out both with a parallel position of the axis of rotation of the object of the geometric axis of the coil, and with perpendicular.

The object of study (Fig. 5) is made of steel 3 GOST 1050-88 and is a cylindrical body 10 with an external diameter of 48 mm and a wall thickness of 2 mm, at both ends of which are attached removable flat covers 11 with a thickness of 2 mm.

A geomagnetic field of 0.4 Oe directed along the axis of an object made of steel 3, which has geometrical parameters close to real (diameter 8 m, length 120 m, wall thickness 14 mm), without installed magnets can magnetize the cylinder walls to the values of induction in them 0.02 T (calculated value). To achieve the same value of the magnetization of the walls of our object, the latter was magnetized in a permanent electromagnet. Monitoring of the achieved level of constant magnetization was carried out using a measuring device by measuring the value of the magnetic moment of the object, which should correspond to the achieved level of magnetization and is equal to 12 A * m ² for our object (calculated value).

To reduce the magnetic moment of the object, permanent magnets 12 were installed on the inner surface of the cylinder, having a standard size D 5 × 3, made of rare-earth material KS-25DC190 in the amount of 60 pieces (12 pieces around the circumference, 5 pieces in a row along the wall), providing in the cylinder wall periodic alternating magnetic field with a calculated level of induction of 0.06 T.

As can be seen from the measurement results, the installation of permanent magnets on the inner surface of the object allowed both in the case of an external magnetic field applied along the axis of rotation of the object (Fig. 6) and in the case of an external magnetic field applied perpendicular to the axis of rotation of the object (Fig. 7) the magnetic moment of the object is more than 5 times. Moreover, in order to achieve the value of the magnetic moment of an object in a geomagnetic field without installed magnets, it is necessary to apply an external field with a strength of more than 10 times the level of the geomagnetic field.

Thus, the claimed combination of features provides protection of a metallic ferromagnetic object from magnetometric detection by translating the ferromagnetic material from which the protected object is made into an alternating periodically magnetized state.

Claims (4)

1. A method of protecting a metallic ferromagnetic object from magnetometric detection by translating the ferromagnetic material from which the protected object is made into an alternating periodic magnetized state, including installing on the surface of the object elements of a permanent magnet system with alternating directions of magnetization with magnetic flux closing through the object’s body so that the magnetic field generated by the elements of the magnetic system provides us the agglomeration of the material of the structure is at least 2–3 times higher than the value of the magnetization arising in the material of the object from the action of an external magnetic field, while the total magnetic moment of the installed permanent magnet magnetic system is minimal for the given structure of the object, and the integral magnetic moment of the ferromagnetic object in an external magnetic field with an installed magnetic system at least 3 times lower than the integral magnetic moment of an object without an installed magnetic system, it is independent about from the direction of application of the external magnetic field. 2. The method of claim 1, wherein the external magnetic field is a geomagnetic field. 3. The method according to claim 1, in which the external magnetic field represents a field created by the electrical network of the object. 4. The method according to claim 1, in which the external magnetic field is a field created by the magnetostrictive magnetization of the sections of the object arising from mechanical loads during operation.

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