RU2359374C1 - Absorber of electromagnet waves - Google Patents

Abstract

FIELD: physics, radio.

SUBSTANCE: invention is related to the field of radio engineering, in particular, to absorbers of electromagnet waves, and may be used in equipment of anechoic chambers and screened premises. Absorber represents a hollow dielectric casing in the form of tetrahedral pyramid with socular base in the form of rectangular prism, with rounded ribs of pyramidal part filled with filler. Body is made of not easily combustible polymer, and filler used is represented by not easily combustible dry mixtures of highly stable components on the basis of cellulose materials and carbon fiber. Rounding of ribs in pyramidal part of absorber body provides for reduced coefficient of reflection in working range of electromagnet waves. Besides, absorber is light, high-quality and ecologically safe item with high operation life.

EFFECT: reduced reflection coefficient in working range of electromagnet waves.

3 cl, 1 dwg, 1 tbl

Description

The invention relates to the field of antenna technology and can be used to create absorbers of electromagnetic waves (SEW) used in equipping anechoic chambers (BEC) and shielded rooms.

When creating multifunctional universal BECs of high quality, as a rule, wide-range SEWs of a spike design are used, which have, basically, a pyramidal shape.

Known pyramidal absorbers of electromagnetic waves, made using flexible polyurethane foam with carbon filler (Mitsmakher M.Yu., Torganov VA, Anechoic chambers microwave. - M .: Radio and communications, 1982, p.90). Despite the small weight characteristics and low reflection coefficient in a wide range of electromagnetic waves, these absorbers have a number of significant drawbacks. The porous surface of the pyramidal elements of polyurethane foam is covered with dust over time, the polymer itself has a tendency to destruction during operation, which ultimately affects the stability of the radio characteristics. In addition, polyurethane foam is a combustible material with the release of toxic substances during combustion, which requires additional material costs for the installation of an automatic fire extinguishing system.

To eliminate some of the noted drawbacks, PEVs with hollow dielectric housings that are filled with absorbing components are used. In German patent No. 1253780 dated 05/08/1969, an embodiment of the manufacture of a pyramidal SEW is given, the casing of which is made of polystyrene plates glued together, and the internal cavity is filled with cubic cubes with linear dimensions in the range of 5-10 mm cut from absorbing foam. However, the difficulty of attaching these pyramids to the working surfaces of BEC, insufficient mechanical strength and combustibility of the initial foam polymers are serious disadvantages of this technical solution.

The closest set of features to the claimed technical solution is an absorber of electromagnetic waves for anechoic chambers containing a hollow dielectric body in the form of a tetrahedral pyramid with a basement in the form of a rectangular prism, in the inner cavity of which there is a non-combustible radar absorbing aggregate. This absorber, taken as a prototype, is made of foam asbestos containing 6-10% carbon fiber (USSR Patent No. 1755720 of 03.30.89).

The disadvantages of the prototype include very low strength characteristics, technological complexity and the great complexity of manufacturing both the initial foam asbestos material and the absorber itself, as well as the use of asbestos, which is a carcinogen, in the manufacture and operation of finished products. In addition, the low mechanical strength of the prototype bodies made of foam asbestos, which can be deformed even by insignificant mechanical influences, does not allow dust to be deposited during operation on the PEV bodies, which significantly worsens the environmental situation in the anechoic chamber.

The task was to develop a sewage system with high radio technical parameters, low weight and significantly increased strength characteristics while maintaining fireproof performance, simplifying manufacturing technology, reducing the range of initial components and the absence of harmful and carcinogenic materials in the manufacture and operation of the absorber in anechoic chambers.

The technical result is achieved by the fact that in the known absorber of electromagnetic waves for anechoic chambers and shielded rooms, containing a hollow dielectric casing, made in the form of a tetrahedral pyramid with a basement in the form of a rectangular prism, in the inner cavity of which is a radio-absorbing aggregate, the casing is made of flame-retardant polymer and has rounded edges of the pyramidal part with a radius of rounding equal to 1 / 20-1 / 40 of the height of the absorber.

The technical result is also achieved by the fact that the filler is a non-combustible homogeneous dry mixture of highly stable components based on cellulosic materials using carbon fiber with a length of at least 1/100 and not more than 1/10 of the height of the absorber, taken in an amount of 2-10% of the total mass placeholder. The technical result is also achieved by the fact that the aggregate can be structurally made two-layer and multi-layer.

The drawing shows a General view of the inventive sew, where 1 is a housing; 2 - a sealing cover; 3 - radar absorbing aggregate (mixture A); 4 - radar absorbing aggregate (mixture B); 5 - assembly unit for sewage to the working surfaces of the BEC.

In the manufacture of the body and cover of the sewage system, various polymeric refractory materials can be used, including polyethylene, polystyrene, polypropylene, etc. The term "refractory" is generally accepted. According to GOST 12.1.044-89, materials having certain fire resistance characteristics are classified as slow-burning.

The housing of the inventive absorber is made by casting of nonflammable polystyrene, for example, grade BASF ES 8550 and has an apex angle of 21 ± 2 °, and the wall thickness of the housing ranges from 1 to 1.5 mm, which provides, along with sufficient rigidity and durability of the product, its small weight characteristics. The sealing case cover is made of the same material as the case, has an inner rim height of 10-15 mm and enters the case quite tightly, providing a seal with a gap of less than 0.1 mm, which helps to protect the absorbent core from moisture. Additionally, to seal and prevent possible unauthorized separation of the cover from the housing, polymer glue is applied to the outer edge of the cover along the perimeter.

A distinctive feature of the proposed PEV case is the technical solution to give rounding to the rectangular edges of the pyramidal part of the body, allowing the electromagnetic wave to smoothly flow around the absorber without diffraction phenomena arising on the sharp edges of the pyramids. These roundings on the ribs are performed with a radius of 1 / 20-1 / 40 of the height of the SEW. With an increase in the radius of curvature of more than 1/20 of the part, the height of the edges of the base base decreases, which leads to an increase in the reflection coefficient in the short-wave section of the operating range. A decrease in the value of the radius of curvature of less than 1/40 of the height of the SEW reduces the effect of rounding the edges of the pyramidal part of the body and is not advisable.

The rounding of the ribs of the pyramidal part of the housing of the inventive absorber allows using any aggregates to reduce the reflection coefficient compared with the prototype or with the same values of the reflection coefficient to expand the frequency range of the absorbed electromagnetic waves. The table shows the comparative characteristics of the reflection coefficient for the prototype and the inventive absorber.

Table PEV option Power reflection coefficient, minus dB The ratio of the height of the SEW to the wavelength, h / λ 0.45 0.5 1,0 2.0 4.0 Prototype - twenty thirty 40 fifty The inventive sew twenty 23 34 43 <50

The table shows that the inventive absorber has a wider range of absorbed electromagnetic waves and a lower reflection coefficient at any frequency of the studied range.

At the same time, the claimed invention solved the problem of stabilizing in time the radio-technical and operational characteristics of the absorber. This is achieved through the use of a specially designed aggregate consisting of highly stable cellulosic materials and carbon fiber. As pulp materials, crushed and processed waste paper called “Ecowool” is used, which has a hygienic and fire report on the possibility of use in residential premises, the warranty period of which is at least 70 years. As the absorbing component, various carbon fibers of the UVZH-10, UVS-15, or Uglen type are used of the TsSHE or U-9 grades with a cut length from 1/100 to 1/10 of the height of the sewage system. Both components in predetermined proportions in a specially designed mixer are mixed, forming a dry fluffy homogeneous mixture with a density of the order of 20 kg / m ³ , with which pyramidal bodies are filled in a certain way. The use of a mixture with a low density, optimal length of cutting and the amount of carbon fiber, a unique technology of mixing the components and layer-by-layer filling of the bodies - all this provides a filler, on the basis of which it is possible to produce the highest quality PEW.

Additionally, to obtain a more reliable sealing of the internal volume of the housing, the entire mass of absorbent aggregate is divided into two unequal parts. The first, the bulk (mixture A), is poured into the pyramidal part of the body, the other (mixture B) is sealed in a plastic bag and located in the rectangular prism of the base of the body, densely filling its entire volume. The case of the absorber, as noted earlier, is closed by a lid and additionally sealed with polymer glue.

The use of highly stable materials and sealing of the aggregate provide a warranty period of operation of the inventive absorber of at least 20 years.

The use of dividing the bulk density of the filler into two or more parts, in particular on a mixture of A and B, makes it possible to further upgrade the pyramidal SEW, achieving a further decrease in the reflection coefficient and expansion and thereby the frequency range. This is achieved by the ability to place a filler in the upper part of the pyramidal element (at the top), which uses a carbon fiber of short length, for example 1/100, 1/50, 1/30 and other parts of the height of the sewage system, and a lower concentration, for example 2 ÷ 5%, and in the base place the aggregate, on the contrary, with longer carbon fibers, for example 1/20, 1/10 part of the height of the SEW, and in a larger amount, for example 5 ÷ 10% of the total mass of the aggregate. The number of layers, the length of the carbon fiber and its concentration in the layers can be determined by analytical calculation, achieving even smoother penetration of the electromagnetic wave into the absorber in order to obtain optimal radio technical characteristics.

The proposed technical solution relates to pyramidal SEWs, which even with a homogeneous filler, are well consistent with free space and have high radio technical characteristics due to the combination of a smoothly varying gradient of losses in height with diffusion properties of the surfaces of the faces of the pyramids, which provide repeated re-reflection of electromagnetic waves as they penetrate the absorbing structure. For these absorbers, the radio technical characteristics depend on the size and height of the pyramidal elements and are selected depending on the specified minimum and maximum wavelengths and the required reflection coefficient in this range. However, the possibility of dividing the bulk density of the filler into layers has the prospect of achieving the highest quality of this design of sew.

The claimed technical solution relates to high-quality, highly stable absorbers of electromagnetic waves, is fireproof, environmentally friendly material, which during operation does not emit harmful and toxic substances. The advantages of this absorber should also include low weight and the ability to remove dust from the surface of the pyramidal buildings, which improves the working conditions of maintenance personnel anechoic chambers and shielded rooms.

Technical and economic advantages of the proposed technical solution take place and are based on the following.

Firstly, due to the high radio engineering performance of the inventive SEW, the quality is increased and the cost price of the antenna equipment is reduced.

Secondly, due to the highly stable radio engineering and high strength characteristics, there is no need to replace and refit new sewage-free chambers and shielded rooms with new ones.

Thirdly, due to the small weight characteristics, the cost of erecting supporting and supporting building structures is reduced, and the technological processes of facing anechoic chambers and shielded rooms are simplified.

Fourthly, fireproof and environmental conditions for personnel in confined spaces equipped with the inventive sewage system are provided.

Claims (3)

1. An electromagnetic wave absorber for anechoic chambers and shielded rooms, containing a hollow dielectric casing, in the form of a tetrahedral pyramid with a basement in the form of a rectangular prism, in the inner cavity of which there is a radio-absorbing aggregate, characterized in that the casing is made of slow-burning polymer and has rounded edges pyramidal part with a radius of rounding equal to 1 / 20-1 / 40 of the height of the absorber. 2. The absorber according to claim 1, characterized in that the aggregate is a non-combustible homogeneous dry mixture of highly stable components based on finely chopped cellulosic materials and carbon fiber with a length of not less than 1/100 and not more than 1/10 of the height of the absorber, taken in an amount of 2- 10% of the total mass of aggregate. 3. The absorber according to claim 1 or 2, characterized in that the aggregate is structurally made two-layer or multi-layer.