RU75509U1 - PROTECTIVE COVERING - Google Patents

Abstract

The utility model relates to radio electronics and can be used in the development and operation of devices designed to localize electromagnetic radiation of devices, to protect against an increased level of electromagnetic radiation of electronic equipment, information carriers and biological objects. Technical essence: the protective coating contains at least two layers 1 and 2 superimposed on each other, each of which has a relief surface in the form of alternating protrusions and depressions. In the depressions of each previous, for example, the first layer 1, the protrusions of the subsequent layer 2 are placed with a gap. The air gap between the surfaces of the reliefs of the layers creates the effect of a thermos, in which thermal energy does not go outside, which protects the object from infrared radiation. Additionally, this effect is enhanced by a metal layer deposited on the film, which almost completely reflects the radiant thermal energy coming from the protected object. The wedge-shaped shape of the depressions and protrusions also increases the efficiency of protecting the object from detection in the infrared wavelength range, because heat is absorbed from the base of the relief, and dissipated from its side faces. Along with the processes of absorption of electromagnetic waves due to magnetic and dielectric losses in the impedance layer of the film, there are processes of multiple reflection of incident waves from the reliefs of the outer surface of the coating. The transition to a new frequency range is achieved by changing the geometry of the relief of the outer surface. The technical result is an increase in the effectiveness of protection. 1 s.p. f-ly.

Description

The utility model relates to radio electronics and can be used in the development and operation of technical means designed to localize electromagnetic radiation of devices, to protect against an increased level of electromagnetic radiation of electronic equipment, information carriers and biological objects.

Known means of protection (1), made in the form of a flexible base with resistive properties, which has a relief surface. The relief surface is formed by volumetric, randomly located cells of an additional layer bonded to a flexible base made in the form of a mesh. A disadvantage of the known solution is the lack of protection against infrared radiation, which is explained by the properties of the mesh base, which transmits infrared rays from heated bodies.

Closest to this utility model is a protective coating designed to reduce reverse radar reflection (2). Known protective coating contains one absorbing electromagnetic waves layer with a relief surface in the form of uniformly alternating protrusions and depressions. A disadvantage of the known solution (2) is the low efficiency of protection against electromagnetic and infrared (IR) radiation.

The technical result that can be achieved using the utility model is to increase the efficiency of protection against electromagnetic and infrared radiation.

The technical result is achieved by the fact that in the protective coating containing the first layer, the relief surface of which is made in the form of alternating protrusions and depressions (2), one or more additional layers are superimposed on the first layer, the relief surfaces of which are made in the form of alternating protrusions and depressions, moreover the protrusions of each subsequent layer are placed with a gap in the hollows of the previous layer, while all layers are made of thin material with resistive properties capable of maintaining its shape. The layers may have a folded structure, configured to change the geometry of the protrusions and depressions.

The drawing shows a cross section of a two-layer protective coating.

The coating contains at least two layers superimposed on each other, each of which has a relief surface in the form of alternating protrusions and depressions (reliefs). In the troughs of each previous, for example, the first layer 1, the protrusions of the subsequent, for example, the second layer 2 are placed with a gap.

In order for the protrusions of each subsequent superimposed layer, for example, 2, to be located in the depressions of the previous (first) layer, it is necessary that the steps of the reliefs of their surfaces are the same.

To improve the manufacturability of the manufacture, the coating layers are made in the form of a folded structure (with a wedge-shaped shape of the relief) made with the possibility of changing the geometry of the relief (protrusions and depressions), for example, the distance between the protrusions or depressions

Layers can be bonded to each other using spot fixing, for example, firmware.

It is possible to provide an incomplete fit of the layers by introducing an air gap between the reliefs located in each other by choosing the shape of the reliefs or by introducing fixing elements, for example, flagella or balls, made of dense non-metallic heat-insulating material (expanded polystyrene) into the hollows of each layer.

The layers are made of a thin material capable of maintaining its shape with resistive properties, for example, a flexible film connected to the base with a surface impedance layer.

The film containing the impedance layer 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.

The basis for the placement of the film can be made of any synthetic or natural materials that can retain their shape.

The connection of the film with the base can be carried out by bonding over the entire surface, pressing or using spot fixing. The relief surface of the film, duplicated by the base, is made using molding.

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

Coating works as follows.

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, diffusely scattering in their entire volume. Moreover, along with the processes of absorption of electromagnetic waves due to magnetic and

dielectric losses in the impedance layer of the film, there are processes of multiple reflection of incident waves from the reliefs of the outer surface of the coating, accompanied by absorption of wave energy. With an arbitrary direction of the incident waves, their scattering is maximum. This is due to the fact that waves are gradually absorbed in the relief elements of the surface, for example, in which the areas of surfaces normal to the incident wave are minimized.

The air gap between the surfaces of the reliefs of the layers creates the effect of a thermos, in which thermal energy does not go outside, which protects the object from infrared radiation. Additionally, this effect is enhanced by a metal layer deposited on the film, which almost completely reflects the radiant thermal energy coming from the protected object -

The wedge-shaped shape of the depressions and protrusions, forming a folded surface structure, increases the efficiency of protecting the object from detection using means operating in the infrared wavelength range, because heat is absorbed from the base of the relief, and is dissipated from its lateral faces and, therefore, from a larger area.

The changing geometry of the gap between the relief surfaces, for example, narrowing due to the wedge-shaped shape of the reliefs, enhances the repeated re-reflection of the incident electromagnetic wave and increases its attenuation, which reduces the reflection coefficient and, of course, increases the efficiency of protection against electromagnetic radiation.

The transition to a new frequency range is achieved by changing the geometry and shape of the surface reliefs of the layers, and in the case of their folded structure, by stretching or compression.

High efficiency of protection makes this coating the most preferable for solving the problems of electromagnetic compatibility, protection of various types of objects from electromagnetic radiation, equipment of anechoic chambers.

Sources of information taken into account when compiling the description:

RU 2155420 C1, H01Q 17/00, 2000

RU 2214026 C2, H01Q 17/00, 1999

Claims (2)

1. A protective device containing a first layer, the relief surface of which is made in the form of alternating protrusions and depressions, characterized in that one or more additional layers are superimposed on the first layer, the relief surfaces of which are made in the form of alternating protrusions and depressions, the protrusions of each subsequent layer placed with a gap in the hollows of the previous layer, while all layers are made of thin material capable of maintaining its shape with resistive properties. 2. The protective device according to claim 1, characterized in that the layers have a folded structure made with the possibility of changing the geometry of the protrusions and depressions.