RU2682254C1 - Radio absorbing element manufacturing method - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: present invention relates to the radio absorbing element manufacturing method, which can be used during the anechoic chambers and shielded rooms equipping. Method comprises forming the radio-absorbing element outer layer liner placement into the metal mold, polyether with thermally expanded graphite and polyisocyanate with carbon fibre mixtures preparation, the said mixtures mixing to obtain the reaction mixture, filling the mold with the liner with the obtained reaction mixture, next hermetically closing the metal mold, after the time required for the radio absorbing material formation, opening the metal mold, removing the liner with the radio-absorbing material therefrom, and painting the radio-absorbing element surface with paint with ensuring the outer layer dielectric constant value from 1.01 to 1.1 in the working frequencies range.

EFFECT: invention enables the possibility of the radio absorbing element development with improved radio-technical and strength characteristics, with simultaneous increase in manufacturability and preserving the environmental friendliness of its manufacturing.

4 cl, 1 dwg, 2 tbl, 3 ex

Description

The invention relates to the field of antenna technology, namely, to absorbers of electromagnetic waves, and can be used to equip anechoic chambers and shielded rooms.

A known method of manufacturing a radio-absorbing element of a pyramidal shape from a self-extinguishing polyurethane foam by casting an ingot and then cutting it to a predetermined shape (see http://el-kor.ru/bezehovye-kamery-i-ekrankamery-radiopogloshchayushchie-materialy/frankonia-epp- 32-piramidalnyy, 2017).

The disadvantage of this method is the insufficient strength of the resulting radar absorbing element, due to the low strength of the polyurethane foam, leading to the destruction of the radar absorbing element during its transportation and operation, which ultimately affects the stability of its radio technical characteristics.

A known method of manufacturing a radar absorbing element, including the formation (by pressing) of its inner part from a mixture containing polyester, polyisocyanate and carbon fiber, and subsequent application to its surface of an outer layer of polyurethane (see RU 2410777, IPC G21F 1/12, publ. 27.01 .2011).

The disadvantages of the known method of manufacturing a radar absorbing element are its low manufacturability, insufficient strength of the resulting radar absorbing element and its poor radio technical characteristics due to a sharp jump in the dielectric constant at the interface of the radar absorbing element with air associated with the use of polyurethane as the material of the outer layer.

A known method of manufacturing a radar absorbing element is adopted as the closest analogue to the claimed method of manufacturing a radar absorbing element.

The technical problem solved by the present invention is the creation of a method of manufacturing a radar absorbing element, devoid of these disadvantages.

The result is a technical result, which consists in the possibility of creating a radio-absorbing element with improved radio and

strength characteristics while improving manufacturability and maintaining the environmental friendliness of its manufacture.

The specified technical result is achieved by implementing a method of manufacturing a radar absorbing element, in which a micro-corrugated cardboard insert is placed in the metal form, forming the outer layer of the radar absorbing element, mixtures of polyester with thermally expanded graphite and polyisocyanate with carbon fiber are prepared, the above-mentioned mixtures are mixed to obtain a reaction mixture including a mixture of polyester and polyisocyanate used in the manufacture of polyurethane foam, fill the form with a liner obtained the reaction mixture, hermetically close the metal form, after the time required for the formation of the radar absorbing material, open the metal form, remove the liner with the radar absorbing material from it and paint the surface of the radar absorbing element with paint, ensuring the dielectric constant of the outer layer from 1.01 to 1, 1 in the operating frequency range.

According to a particular embodiment, a radar absorbing element is made having a main part in the form of a regular tetrahedral pyramid and a base in the form of a rectangular parallelepiped, one of the faces of which coincides with the base of a regular tetrahedral pyramid, and the height is from 17% to 25% of the height of the main part.

According to a preferred embodiment, a water-based paint is used, the composition of which includes flame retardant in an amount of 25 wt. %

According to another private variant of implementation for the formation of radar absorbing material using a mixture comprising a mixture of polyester and polyisocyanate in an amount of 86.0-88.0 wt. %, thermally expanded graphite in an amount of 8.0-10.0 wt. % and carbon fiber - the rest.

In FIG. 1 presents a photo of a radar absorbing element obtained by the claimed method, in section.

The claimed method is implemented as follows.

In the prepared metal form having an inner surface repeating the outer side surface of the radar absorbing element, a micro-corrugated cardboard insert is placed to form the outer layer of the radar absorbing element.

Mixtures of polyisocyanate with carbon fiber and polyester with thermally expanded graphite are preliminarily separately prepared.

Then mix the above mixture to obtain a reaction mixture, which, in particular, may be a mixture comprising a mixture of polyester and polyisocyanate in the amount of 86.0-88.0 wt. % (for example, used in the production of polyurethane foam, available under the trade name "Uremix-402"), thermally expanded graphite in the amount of 8.0-10.0 wt. % and carbon fiber - the rest.

After that, the reaction mixture is filled with a metal form with an insert placed in it (in an amount equal to about one tenth of the volume of the metal form with an insert placed in it).

Then tightly close the mold and, after the time required for the formation of the radar absorbing material (in accordance with a typical technological process), open the mold and remove the liner with the radar absorbing material from it.

The specified material is a polyurethane foam with thermally expanded graphite and carbon fiber distributed over its volume, which occupies the entire space of a hermetically sealed form with an insert.

The formation of polyurethane foam in a limited volume of the metal form, creating increased pressure inside the sealed form, allows for a gradient distribution of thermally expanded graphite and carbon fiber over the volume of the radar absorbing element with a concentration increasing from the surface (limited by the liner) to the inside of the radar absorbing material (see Fig. 1) .

After removing the liner with the radar absorbing material, the surface of the radar absorbing element is painted with paint to ensure the dielectric constant of the outer layer in the operating frequency range from 1.01 to 1.1.

In particular, they use water-based paint, which includes fire retardant in an amount of 25 wt. % Such paint easily penetrates into the microcorrugated board and reduces its combustibility.

The manufacture of a radar absorbing element by the claimed method allows to reduce the difference in dielectric constant along the path of the electromagnetic wave, which, in turn, allows to reduce the reflection from the radar absorbing element and thereby improve its radio technical characteristics.

The use of carbon fiber in the reaction mixture improves the reflective characteristics of the radar absorbing element, and the use of thermally expanded graphite improves its fire retardant properties.

The use of a micro-corrugated cardboard insert per se allows avoiding contact of the mixture with the surface of the metal mold and, thereby, simplifying the process of removing the radio-absorbing element from the mold and eliminating the need to clean the mold before making the next radio-absorbing element.

At the same time, the use of the insert allows one to produce a radar absorbing element having an external dielectric layer (which acts as an insert) in one technological step, and thereby simplify and speed up the manufacturing process of the radar absorbing element while maintaining its environmental friendliness.

In the tables below, Tables 1 and 2 show the weight and size characteristics of the radio-absorbing elements made by the claimed method, and the radio-technical characteristics of the radio-absorbing structures made of them.

Claims (4)

1. A method of manufacturing a radar absorbing element, including the formation of its inner part from a mixture containing polyester, polyisocyanate and carbon fiber, and an outer layer of dielectric material, characterized in that the insert is made of microcorrugated cardboard, forming the outer layer of the radar absorbing element, in a metal form, prepare mixtures of polyester with thermally expanded graphite and polyisocyanate with carbon fiber, mix the above mixtures to obtain a reaction mixture comprising a mixture of polyester of caviar and polyisocyanate used in the production of polyurethane foam, fill the mold with the liner obtained by the reaction mixture, tightly close the metal mold, after the time required for the formation of the radar absorbing material, open the metal mold, remove the liner with the radar absorbing material and paint the surface of the radar absorbing element with paint with providing the dielectric constant of the outer layer from 1.01 to 1.1 in the operating frequency range. 2. The method according to p. 1, characterized in that a radar absorbing element is made having a main part in the form of a regular tetrahedral pyramid and a base in the form of a rectangular parallelepiped, one of the faces of which coincides with the base of a regular tetrahedral pyramid, and the height is from 17 to 25% of the height of the main part. 3. The method according to p. 1 or p. 2, characterized in that they use water-based paint, which includes flame retardant in an amount of 25 wt.%. 4. The method according to p. 1 or p. 2, characterized in that for the formation of radar absorbing material using a reaction mixture comprising a mixture of polyester and polyisocyanate in an amount of 86.0-88.0 wt.%, Thermally expanded graphite in an amount of 8, 0-10.0 wt.% And carbon fiber - the rest.

Images