RU71051U1 - 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. The device contains a flexible base made of corrugated fabric with resistive properties. The height of the protrusions formed as a result of corrugation or the depth of the depressions, as well as the distance between them, is less than or comparable with the maximum wavelength of the working range. The corrugation of the fabric is carried out with the possibility of changing the shape of the protrusions and depressions, for example, by means of adjustable threads passed through the fabric. By changing the tension or length of the threads, you can tighten the entire corrugated sheet and change the distance between the protrusions or troughs to the required value corresponding to a given frequency range of electromagnetic radiation. The technical result is to increase the degree of protection, including from infrared radiation. Protection against infrared radiation is provided by new coating properties acquired as a result of the choice of its material and the modernization of the relief shape of its surface. 4 s.p. f-ly.

Description

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.

Known coating designed to reduce the radar visibility of the object (1). The known means of protection is made in the form of a flexible base with a screen mounted on its surface, reflecting electromagnetic waves. The screen is a metal mesh on which a layer of radar absorbing material is applied. A disadvantage of the known technical solution is the complexity of manufacture and significant weight of the coating.

The device closest to the utility model is a protective coating designed to reduce reverse radar reflection (2). The known means of protection is 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.

The technical result that can be achieved using the utility model is to increase the degree of protection against infrared radiation

The technical result is achieved due to the fact that in a protective coating containing a flexible base with resistive properties (2), the base made of fabric has a relief surface in the form of alternating protrusions and depressions formed as a result of corrugating the fabric, the height of the protrusions or the depth of the depressions , as well as the distance between the protrusions or depressions is (0.1-1) λ, where λ is the maximum wavelength of the working range. The base can be made of electrically conductive fabric or non-conductive fabric, on which two impedance layer applied or introduced

conductive threads. The corrugation of the fabric can be carried out with the possibility of changing the shape of the protrusions and depressions.

The device contains a flexible base made of fabric, which has resistive properties. The base has a relief surface in the form of alternating protrusions and depressions formed as a result of corrugation of the fabric. The height of the protrusions or the depth of the depressions, as well as the distance between the protrusions or depressions, is (0.1-1) λ, where λ is the maximum wavelength of the operating range.

The corrugation of the fabric can be performed by fixing the folds of fabric with each other using, for example, gluing.

The corrugation of the fabric can be carried out with the possibility of changing the shape of the protrusions and depressions, for example, by means of threads with adjustable interference that are passed through the fabric. By changing the tension or length of the threads, you can tighten the entire corrugated sheet and change the distance between the protrusions or troughs to the required value corresponding to a given frequency range of electromagnetic radiation.

The base can be made of non-conductive synthetic fabric (lavsan, kapron), on which a thin metallized (impedance) layer is applied on both sides, for example, of a ferromagnetic alloy. The metallized layer can be either magnetic or non-magnetic. The layer is applied by vacuum metallization.

The base may be made of a non-conductive fabric into which electrically conductive threads are inserted. The fabric can be any, including cotton. Threads can be made of microwire. The introduction of threads into the fabric is carried out by the usual weaving in the weaving industry.

The base can be made of electrically conductive fabric.

The resistive properties of the base are determined by the functional requirements for a protective coating, namely: its work as an absorber of electromagnetic energy or as a screen that contributes to the reflection of radio waves. For example, with a surface resistance of 50 to 1000 Ohms, the fabric can work as an absorber of electromagnetic energy, and with a surface resistance of 1 to 5 Ohms, it can act as a reflective screen.

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 device operates 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. In addition to the processes of absorption of electromagnetic waves due to magnetic and dielectric losses in the impedance layer, 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 minimized. This is due to the fact that the waves are gradually absorbed in the relief elements of the surface, in which the surface area normal to the incident wave is minimized.

The transition to a new frequency range is achieved by changing the geometry of the relief of the outer surface on the basis of the same type of fabric (by tightening the folds of the corrugated base).

Protection against infrared radiation is provided by new coating properties acquired as a result of the choice of its material and the modernization of the relief shape of its surface. Due to the fact that the corrugated fabric has an internal structure with small holes, and the entire product has a sufficiently large thickness, convective flows of air, which is a poor heat conductor, do not appear inside the coating. The consequence of this is that a relatively thick air gap reduces the transfer of heat from a heated object to a cold one, i.e. protects against infrared radiation (while maintaining all the radio technical properties).

The simplicity of manufacture and high protection efficiency make this coating the most preferable for solving the problems of electromagnetic compatibility, protection of various types of objects and staff from electromagnetic radiation.

Sources of information taken into account when compiling the description:

RU 2155420 C1, H01Q 17/00, 2000

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Claims (5)

1. A protective coating containing a flexible base with resistive properties, characterized in that the base made of fabric has a relief surface in the form of alternating protrusions and depressions formed as a result of corrugating the fabric, the height of the protrusions or the depth of the depressions, as well as the distance between the protrusions or troughs is (0.1-1) λ, where λ is the maximum wavelength of the working range. 2. The protective coating according to claim 1, characterized in that the base is made of electrically conductive fabric. 3. The protective coating according to claim 1, characterized in that the base is made of non-conductive fabric, on which an impedance layer is applied on both sides. 4. The protective coating according to claim 1, characterized in that the base is made of non-conductive fabric into which electrically conductive threads are inserted. 5. The protective coating according to claim 1, characterized in that the corrugation of the fabric is carried out with the possibility of changing the shape of the protrusions and depressions.