RU2381601C1 - Multilayer electromagnetic screen - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: device relates to shielding from electromagnetic radiation and can be used for protecting manufacturing and residential premises from low frequency electromagnetic fields induced by electrical equipment. Flat screening layers (1, 2) placed outside the screen are made from sheet magnetically soft isotropic steel with relative initial permeability not less than 2×10³, and the bulk screening layer (3) placed in between is made in form of a rectangular steel grid whose cells are formed by guides 4 and short jumpers 5 which function as below-cutoff waveguides with respect to the fundamental harmonic of the frequency of the screened field. When screening industrial frequency fields, thickness of steel sheets from which the flat screening layers are made is not less than 1 mm, the diagonal of the window of the grid of the bulk layer is not greater than 300 mm, and the depth of the cells and thickness of the edges of the grid lie in the range of 80-300 mm and 40-160 mm respectively. Grid guides of the bulk layer are directed along and towards the dominant vector of the geomagnetic field. If there are weld joints 6 in flat layers 1 and 2 they should be parallel each other and perpendicular to the guides 4 of the grid of the bulk layer 3.

EFFECT: more efficient protection from effect of elliptically polarised magnetic field induced by three-phase electrical equipment.

10 cl, 1 dwg

Description

The invention relates to the field of shielding from electromagnetic radiation and can be applied, in particular, to protect against low-frequency electromagnetic fields induced by electrical equipment.

State of the art

Multilayer electromagnetic screens are known in which layers of a metal sheet, the thickness of which is less than the penetration depth of an electromagnetic wave, alternate with layers of a dielectric, screens in which a ferromagnetic layer absorbing an electromagnetic wave is placed between thin metal layers, as well as screens in which one of layers is made in the form of a metal mesh having predetermined dimensions and ohmic resistance [RU 2168879, RU 58840 U1, RU 2277729].

A disadvantage of the known multilayer screens is the ineffectiveness of protection against the effects of low-frequency electromagnetic fields induced by electrical equipment, and especially from elliptically polarized magnetic fields induced, for example, by three-phase electrical equipment.

Disclosure of invention

The problem solved by the invention is to increase the efficiency of protecting industrial and residential premises from exposure to magnetic fields and especially from an elliptically polarized magnetic field induced by three-phase electrical equipment.

The subject of the invention is a multilayer electromagnetic screen comprising two externally arranged flat shielding layers, each of which is made of soft magnetic sheet isotropic steel with a relative initial magnetic permeability of at least 2 × 10 ³ , and at least one bulk shielding layer placed between them in the form of a rectangular steel grating made with the possibility of its cells functioning as transcendental waveguides with respect to the fundamental frequency harmonic of the screened field.

This set of features provides a solution to the problem and obtaining the specified technical result.

The invention has developments characterizing particular cases of its implementation and consisting in the fact that:

- the thickness of the sheet steel from which the flat shielding layers are made is not less than 1 mm, the diagonal of the grating window of the bulk layer is not more than 300 mm, and the cell depth and the thickness of the grating ribs are between 80 ÷ 300 mm and 40 ÷ 160 mm, respectively;

- the lattice of the bulk layer is formed by guides and jumpers perpendicular to them;

- guides and jumpers are made of rectangular pipes;

- each of the flat shielding layers is made of sheets welded overlap, while the longitudinal welds of the flat shielding layers are parallel to each other and perpendicular to the guides of the lattice of the bulk layer;

- the guides are longitudinally magnetized in one direction, and the jumpers in alternating directions;

- guide lattices of the bulk layer are oriented by the magnetization vector along and towards the prevailing component of the geomagnetic field vector;

- contains a second bulk shielding layer separated from the first by an additionally introduced flat shielding layer;

- contains at least one dielectric layer placed between the bulk and flat shielding layers;

- the thickness of the dielectric layer lies in the range 0.5 ÷ 4.0 mm

The development of the invention clarifies the design of the screen for special applications and reveals the possibility of further improving the effectiveness of shielding.

The drawing shows a three-layer screen design (for clarity, disassembled).

The implementation of the invention in view of its development

The drawing shows flat shielding layers 1 and 2, placed outside the screen, and a bulk shielding layer 3, located between layers 1 and 2. Layers 1 and 2 are made of sheet soft magnetic isotropic steel with a high initial magnetic permeability (not less than 2 × 10 ³ ) . Layer 3 is made in the form of a rectangular steel grating, the cells of which are formed by guides 4 and short jumpers 5. The grating of layer 3 is made with the possibility of its cells functioning as transcendent waveguides with respect to the fundamental frequency harmonic of the screened field. In particular, for shielding a magnetic field of industrial frequency (50 or 60 Hz), the thickness of the sheet steel from which the flat shielding layers are made must be at least 1 mm, the diagonal D of the cell window must be no more than 300 mm, and the cell depth L and thickness M ribs should lie between 80 ÷ 300 mm and 40 ÷ 160 mm, respectively.

The drawing shows the directions of the magnetization vectors J _H and J _{P of} the guides and jumpers of the lattice of layer 3 and the predominant component H of the _{GMF of the} vector of the geomagnetic field, as well as the vector H of the _IS field of the radiation source.

The guides 4 and the jumpers 5 of the bulk lattice are made of magnetized sections of rectangular pipes: the guides 4 are longitudinally magnetized in one direction, and the jumpers 5 in alternating directions. In this case, the guides 4 are oriented by the magnetization vector J _H along and towards the prevailing component H of the _GMF of the geomagnetic field vector.

In cases where flat shielding layers 1 and 2 are made of overlap welded sheets, longitudinal (i.e. directed along the long side of the steel sheet) welds 6 of layers 1 and 2 should be parallel to each other and perpendicular to the guides 4 of the grating of the bulk layer 3.

The screen may comprise a second bulk shielding layer separated from the first by an additionally introduced flat layer. Between adjacent bulk and flat shielding layers can be placed a dielectric layer, the thickness of which lies in the range of 0.5 ÷ 4.0 mm

The proposed screen is used, as a rule, to protect industrial or residential premises from magnetic fields induced by closely located electrical equipment, such as transformer substation equipment located in the same building.

The screen is constructed and operates as follows.

The screen can be placed on the floor, ceiling or on the walls in the premises of the sources of the dangerous field, as well as on the floor and walls in the adjacent protected premises. For the manufacture of flat screen layers, sheets of soft isotropic steel are used, for example, a steel sheet according to TU 14-1-4592-89 (initial relative magnetic permeability 2 × 10 ³ ), and for the manufacture of guides and bulkheads of bulk layers, pieces of rectangular pipes, for example according to GOST 13663-86 (the thickness of the edges of the lattice will be 40 mm, and the depth of the cells 80 mm). The window size of the cell can be selected depending on the magnitude of the required design value of the attenuation, for example, 200 × 200 mm (diagonal 282 mm).

Pipes, from the segments of which the guides 4 and jumpers 5 are made, have longitudinal production magnetization. The required directions of magnetization of the guides 4 and jumpers 5 are provided by orienting the corresponding segments of the longitudinally magnetized pipes. A compass or magnetometer can be used to determine the direction of magnetization of pipe sections. The direction of the prevailing component of the geomagnetic field can be determined by the geographical coordinates of the room and its location relative to the cardinal points.

Magnetic fields created by electrical equipment of alternating current of industrial frequency, representing a biological hazard to humans and affecting the electromagnetic compatibility of technical equipment, are generally elliptically polarized, i.e. have a linear component (a magnetic field induced by an alternating current in a fixed direction) and a rotating component induced by two or more alternating currents that are spatially shifted and phase-shifted.

The necessary degree of suppression of the linear component of the magnetic field, whose vector is located in a limited range of angles with respect to the plane of the screen, in many practical cases can be achieved by two flat layers 1, 2 and in the absence of a bulk layer. The effective suppression of a rotating magnetic field vector, the direction of which with respect to the steel surface of the screen is continuously changing in time, is a more difficult task.

Placed between the flat shielding layers 1 and 2, a three-dimensional shielding layer 3 in the form of a rectangular steel grating, configured to operate its cells as transcendental waveguides with respect to the fundamental frequency harmonic of the screened field, suppresses a continuously rotating magnetic field vector at those angles of incidence on the screen surface when a pair of flat layers 1 and 2 stops working.

As a result, the proposed screen provides high shielding efficiency for both linear and rotating components of an elliptically polarized magnetic field of industrial frequency.

The development of the invention clarifies the design of the screen when it is used to protect against a field of industrial frequency, as well as the preferred orientation of the screen relative to the natural geomagnetic field, which avoids the magnetic saturation of steel, which contributes to the effectiveness of the screening of the rotating and linear components of the field.

To weaken the magnetizing effect of the natural geomagnetic field, the guiding elements of the bulk layer lattice are oriented by the magnetization vector (arising from the initial magnetization of the pipes from which layer 3 is made) along and towards the prevailing component of the geomagnetic field vector. Moreover, if flat shielding layers are made, for example, of two rolled steel sheets overlapped by longitudinal sides, then the welds of the rolled sheets of flat shielding layers are perpendicular to the guides and, therefore, perpendicular to the prevailing component of the geomagnetic field vector. Welds increase the resistance of the magnetic circuit for the geomagnetic field and thereby prevent the magnetic saturation of the steel sheet in the flat layers of the screen.

To further increase the efficiency of shielding, additional volumetric and flat layers can be introduced into the device. To reduce the galvanic coupling between adjacent (bulk and flat) shielding layers, they can be separated by a dielectric layer.

Claims (10)

1. A multilayer electromagnetic screen containing two externally arranged flat shielding layers, each of which is made of soft magnetic sheet isotropic steel with a relative initial magnetic permeability of at least 2 × 10 ³ , and at least one bulk shielding layer placed between them in the form a rectangular steel grating made with the possibility of its cells functioning as transcendental waveguides with respect to the fundamental frequency harmonic of the screened field. 2. The screen according to claim 1, characterized in that the thickness of the sheet steel of which the flat shielding layers are made is not less than 1 mm, the diagonal of the window of the grating of the volume layer is not more than 300 mm, and the depth of the cells and the thickness of the ribs of the grating of the volume layer are within 80 ÷ 300 and 40 ÷ 160 mm, respectively. 3. The screen according to claim 1, characterized in that the lattice of the bulk layer is formed by guides and jumpers perpendicular to them. 4. The screen according to claim 3, characterized in that the guides and jumpers are made of rectangular pipes. 5. The screen according to claim 3, characterized in that each of the flat shielding layers is made of overlap welded sheets, while the longitudinal welds of the flat shielding layers are parallel to each other and perpendicular to the guides of the grating of the bulk layer. 6. The screen according to claim 3, characterized in that the guides are longitudinally magnetized in one direction, and the jumpers in alternating directions. 7. The screen according to claim 6, characterized in that the guiding lattices of the bulk layer are oriented by the magnetization vector along and towards the prevailing component of the vector of the geomagnetic field. 8. The screen according to claim 1, characterized in that it contains a second volumetric shielding layer separated from the first by an additionally introduced flat shielding layer. 9. The screen according to claim 1, characterized in that it contains at least one dielectric layer located between the bulk and flat shielding layers. 10. The screen of claim 8, characterized in that the thickness of the dielectric layer lies in the range of 0.5 ÷ 4.0 mm