RU172418U1 - EMC device - Google Patents

Abstract

The utility model relates to electrical engineering and can be used to create radar absorbing devices designed to equip multifunctional anechoic chambers, shielding rooms used to tune antennas, and protect personnel from radiation from microwave sources. The device consists of tubular elements 1, both end parts of each of which are beveled at an angle to its longitudinal axis. All tubular elements 1 are connected to each other, for example, by gluing along the side surfaces or reinforcing in the cells of the mesh base. The tapered sides of the tubular elements form two outer surfaces, one of which is facing the incident electromagnetic wave. The principle of operation of the device is based on the absorption and multiple reflection of electromagnetic waves from the internal and external surfaces of the tubular elements. An incident electromagnetic wave travels from the vertices of the bevels of tubular elements facing it to the opposite tip of their bevels with a minimum reflection, which guarantees a high degree of protection against electromagnetic effects. 1 ill.

Description

The utility model relates to electrical engineering and can be used to create radar absorbing devices designed to equip multifunctional anechoic chambers and shielding rooms designed to tune antennas, as well as to protect staff from radiation from microwave sources.

Known volumetric radar absorbing device (DE 1294511, H01Q 17/00, 1969), made of tubular elements that are oriented parallel to the direction of incident radiation and are located at a distance less than 1/5 of the maximum wavelength of electromagnetic radiation. An electrically conductive coating is applied to the outer surface of the elements, the surface resistance of which decreases in the direction of radiation propagation. A disadvantage of the known device is the high level of reflection coefficient in the long wavelength part of the wavelength range due to insufficient coordination with free space.

Closest to the utility model is a protective radar absorbing device (RU 2122264 C1, H01Q 17/00, 1998), consisting of tubular elements made of thin-layer resistive material, one of the end parts of which having a bevel shaped profile facing the incident wave, while others are mounted on a substrate. The device has good agreement with the workspace, but a low degree of protection efficiency, which is explained by the significant reflection of the electromagnetic wave from the bases of the tubular elements.

The technical result that can be achieved in the implementation of the utility model is to increase the degree of effectiveness of protection against electromagnetic interference.

The technical result is achieved due to the fact that in the device of protection against electromagnetic effects, consisting of tubular elements connected to each other, the end parts of which, having a bevel at an angle to the longitudinal axis, form two external relief surfaces of the device, one of which is facing the incident electromagnetic wave, while each of the tubular elements is made of a thin layer of resistive material.

The drawing shows the design of the device against electromagnetic interference.

The device consists of tubular elements 1, both end parts of each of which are beveled at an angle to its longitudinal axis. All tubular elements 1 are connected to each other, for example, by gluing along the side surfaces or reinforcing in the cells of the mesh base. The beveled end parts of the tubular elements form two external embossed surfaces of the device, one of which is facing the incident electromagnetic wave.

The basis for attaching the elements 1 can be made in the form of a mesh made, for example, of viscose-dacron threads. The fastening of the tubular elements 1 to the mesh base can be done by gluing or spot fixing.

Blanks for tubular elements can be made of thin resistive material, for example, electrically conductive paper, ETB-3, a film containing an impedance layer. The film may be made of a polymeric or polyamide material, for example, lavsan, on which a thin metallized layer is applied, for example, of a ferromagnetic alloy.

The device operates as follows.

The principle of operation of the device is based on the absorption and multiple reflection of electromagnetic waves from the internal and external surfaces of the tubular elements. When electromagnetic radiation hits a bulk radio-absorbing structure, currents are induced in the resistive walls of the tubular elements 1, and the incident electromagnetic energy is converted into thermal energy with a low reflection coefficient. Simultaneously with the absorption of energy, re-reflection and diffuse scattering of electromagnetic waves occurs. The presence of bevels at both ends of the tubular elements ensures a decrease in the reflection coefficient of the incident wave, passing from the vertices of the bevels facing it to the opposite edge of the bevel, at which its reflection is minimized.

Thus, the implementation of the utility model in the form of tubular elements connected to each other, the beveled ends of which form the outer surfaces of the protective shield, can significantly reduce the reflection of incident electromagnetic waves and increase the degree of protection efficiency.

By changing the shape and size of the tubular elements, it is possible to adapt to different frequency ranges of electromagnetic radiation.

The device is used in the form of curtains and hanging screens that can be mounted on any surface.

High protection efficiency makes this protective tool the most preferable when solving the problems of protecting various types of objects from electromagnetic radiation and equipment premises for tuning antennas.

Claims (1)

The device of protection against electromagnetic interference, consisting of tubular elements connected to each other, the end parts of which are oblique at an angle to the longitudinal axis, form two external relief surfaces of the device, one of which is facing the incident electromagnetic wave, each of which is made of tubular elements from thin-layer resistive material.

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