RU101310U1 - ELECTROMAGNETIC PROTECTION MEANS - Google Patents

Abstract

 1. A means of protection against electromagnetic radiation, containing a flexible base consisting of several sections connected to each other, made of electromagnetic materials with different reflection coefficients, ranging from - 40 to -5 dB. ! 2. The means of protection against electromagnetic radiation according to claim 1, characterized in that each of the sections is made in the form of a grid, in the horizontal and vertical rows of each cell of which a corresponding number of flexible tapes made of a material completely reflecting electromagnetic waves are woven. ! 3. The means of protection against electromagnetic radiation according to claim 1, characterized in that each of the sections is made of fabric, in both directions of weaving of the threads of which a corresponding number of threads having electromagnetic properties is introduced, which are made in the form of microwires in glass insulation.

Description

The utility model relates to means of masking objects and can be used as a protective mask-overlap, hiding the object located below it from surveillance systems for radar detection.

A device for radar masking of objects, made in the form of a completely covering the protected object mask-overlap, which is a flexible electrically insulating film coated with an electrically conductive layer in the form of a grid. The grid consists of sections of a radio-opaque conductive film (1).

Closest to the utility model is an overlapping mask made in the form of a mesh base, in each cell of which there is an air loop formed by a tape made of a film with a surface impedance layer (2).

A disadvantage of the known devices (1) and (2) is the low efficiency of protection against electromagnetic radiation and, therefore, a high degree of detection of the object by surveillance systems of radar recognition with high resolution. With an increase in the resolution of modern radar stations, the visibility of the mask-overlap increases against the background of reflections from the ground, which has a rough surface, against which the pieces of the protective coating become more pronounced. This is because the known protective equipment is made of a material with a practically unchanged reflection coefficient in a given wavelength range over the entire surface of the mask, while the signal reflected from the ground has a variable value.

The technical result that can be achieved using the utility model is to increase the efficiency of object protection from detection by modern radar recognition surveillance systems.

The technical result is achieved due to the fact that the means of protection against electromagnetic radiation contains a flexible base consisting of several sections connected to each other made of electromagnetic materials with different reflection coefficients, ranging from -40 to -5dB. Each of the sections can be made in the form of a grid, in the horizontal and vertical rows of each cell of which a corresponding number of flexible tapes are made, made of a material completely reflecting electromagnetic waves. Each of the sections can also be made of fabric, in both directions of weaving of the threads of which a corresponding number of threads having electromagnetic properties is introduced, which are made in the form of microwires in glass insulation.

Figure 1 shows the design of protective equipment.

Figure 2 presents an embodiment of one of the sections of the base of the protective equipment.

The device (Figure 1) contains a flexible base 1, consisting of several sections 2 connected to each other, made of electromagnetic materials with different reflection coefficients, ranging from -40 to -5 dB.

Figure 2 presents one of the embodiments of the protective coating (mask - overlap). Each of the mask sections is a grid 3, in the horizontal and vertical rows of cells of which a corresponding number of flexible tapes 4 are made, made of a material completely reflecting electromagnetic waves.

The tapes are made of a film with an impedance layer, which can be made of a polymeric material, for example, lavsan, on which a thin metallized layer is applied, for example, of a ferromagnetic alloy. The layer is applied by vacuum metallization. Mesh 3 can be made of any synthetic or natural threads.

The basis of the coating may be a fabric consisting of several sections, into the weaving of which additional threads are introduced, made in the form of microwires in glass insulation.

The choice of base material is determined by the operating conditions of the protective coating and must satisfy, in particular, the requirements for strength, flexibility, moisture resistance.

The change in the reflection coefficients of the base sections is achieved by introducing into them a different amount of material with conductive properties per unit area, for example, by including in the structure a different number of microwires or flexible tapes with electromagnetic properties.

The base portions can be joined in any known manner, for example, by gluing, stitching, spot fixing.

The device operates as follows.

Improving the effectiveness of protection is achieved by maximizing the reflective properties of the coating to the properties of the underlying earth's surface, taking into account its reflectivity in the framework of the facet model (see the Radar Handbook edited by M. Skalnik vol. 1 “Fundamentals of Radar” M. Sov. Radio, 1975, p. 271-276). According to the facet model of radar reflections, the uneven ground surface is a combination of a large number of sites (facets) of various sizes that form the reflected radar signal. For maximum confluence with the background of the earth, the masking coating should also be a similar structure (in the form of sections that have different reflection coefficients).

An object protected from electromagnetic interference is placed under a removable protective coating. Electromagnetic waves incident from free space fall on the absorbing elements of the coating areas, diffusely scattering in their entire volume. Due to the difference in the reflection coefficients of surface areas, the entire mask-overlap will not be perceived by radar detection as one object, and the reflection will have a diffuse character, indistinguishable from reflection from the background of the earth.

It was experimentally established that the mask of this structure works best when the reflection coefficients of its sections differ from -40 to 5dB, while the working range of electromagnetic wavelengths emitted by modern radars is almost completely covered.

By changing the size of the plots and the range of variation of their reflection coefficients, it is possible to adapt to different frequency ranges of electromagnetic radiation.

Thus, by dividing the surface of the protective coating into many areas with different reflection coefficients, the protection efficiency of the object is increased, which makes the object practically invisible against the earth's surface for modern high-resolution radar detection devices.

The utility model can be used in military technology as a protective mask-overlap, hiding the object located beneath it from surveillance systems for radar detection.

Sources of information taken into account when compiling the description:

RU 2214026 C1 H01Q 17/00, 2000

RU 2313869 C1 H01Q 17/00, 2006

Claims (3)

1. A means of protection against electromagnetic radiation, containing a flexible base consisting of several sections connected to each other, made of electromagnetic materials with different reflection coefficients, ranging from - 40 to -5 dB. 2. The means of protection against electromagnetic radiation according to claim 1, characterized in that each of the sections is made in the form of a grid, in the horizontal and vertical rows of each cell of which a corresponding number of flexible tapes made of a material completely reflecting electromagnetic waves are woven. 3. The means of protection against electromagnetic radiation according to claim 1, characterized in that each of the sections is made of fabric, in both directions of weaving of the threads of which a corresponding number of threads having electromagnetic properties is introduced, which are made in the form of microwires in glass insulation.