WO2021173042A1

WO2021173042A1 - Fragment-proof shielding canvas

Info

Publication number: WO2021173042A1
Application number: PCT/RU2021/050044
Authority: WO
Inventors: Ирина Анатольевна ЗАДОРОЖНАЯ; Артем Анатольевич ЗАДОРОЖНЫЙ
Original assignee: Ирина Анатольевна ЗАДОРОЖНАЯ; Артем Анатольевич ЗАДОРОЖНЫЙ
Priority date: 2020-02-24
Filing date: 2021-02-23
Publication date: 2021-09-02

Abstract

The invention relates to the field of multi-layered bulletproof materials made of ballistic fabric with shielding properties, and can be used in the production of means for mass protection. The present fragment-proof shielding canvas comprises netting which is capable of holding back the maximum amount of fragments and preventing the initiation of a radio-controlled explosive device. The netting is configured according to the Faraday cage principle based on maximum effective shielding of electromagnetic radiation in the range from 20 MHz to 6 GHz. Furthermore, the fibres of the netting are made of aramid fibre metallised with heavy-metal ions.

Description

Anti-splinter shielding cloth

The invention relates to the field of laminated bullet-resistant materials made of ballistic fabric with shielding properties, and can be used in the manufacture of mass protection.

The mass of the material in which metallized aramid fibers are used is significantly lower, since one layer is both anti-spall and shielding.

The prior art knows materials shielding against electromagnetic interference, for example: Aaronia X-Dream - a fabric shielding against electromagnetic interference (100 dB) [http: //el-kor.rn/bezehovye-kamery-i- ekrankamery-ekranimyushchie-materialy / aaronia-x-dream-tkan-ekranimyushchaya-ot-elektromagnitnyh-pomeh-100-db]. This fabric has a frequency range of shielded signals 1 MHz - 30 GHz, shielding efficiency - 70 dB; 99.999999% at 20 GHz. The material of the fabric is a mixture of copper and nickel, the backing is polyester. The type of shielded signals is HF and LF electric fields. Available in sizes from 1 m ² to 50 m ² . Wireless signals of standards practically do not penetrate through such fabric: GSM and / or DECT, and / or BLUETOOTH, and / or WLAN and other electromagnetic signals in the range from 1 MHz to 30 GHz.

The closest to the claimed technical solution is the PROTECTIVE STRUCTURE OF ANTI-SHRINKER COVER WITH NON-WOVEN MATERIAL (RF Patent 2 237 846, published: 10.10.2004 Bul. N ° 28), containing layers of woven and two outer layers of non-woven ballistic-resistant materials connected by sewing stitches two mutually perpendicular directions, while each of the layers of non-woven material is made composite, divided into parts by single layers of woven material, parts of each layer are interconnected by sewing stitches in two mutually perpendicular directions, the distance between the lines is 0.25 ... 0.5 distance between lines connecting the entire protective structure, while the surface density of the nonwoven material is 35 ... 55% of the surface density of the composite outer layers and 5 ... 20% of the surface density of the entire protective structure.

The disadvantage of this solution can be attributed to the multilayer structure and the inability to screen the frequencies of a possible explosive device (hereinafter - VU), controlled by radio.

The technical problem of the present invention lies in the need to create a durable and lightweight anti-splinter cloth, at the same time, capable of shielding the frequencies of a possible WA.

The technical result consists in providing the possibility of isolating explosive or suspicious objects by preventing the initialization of an explosive device located in them, the detonator of which is controlled by a radio channel.

The anti-splinter fabric is made of aramid fibers, the most durable material available.

It is known that the frequency range from 20 MHz to 6000 MHz is most often used for remote initiation of a VU. The screening efficiency S c, which depends on the frequency, material, thickness and linear dimensions of the screening mesh cell, can, for example, be determined by the following formula:

S_c = / 2s [ln (27rr / s)], (1) where r is the radius of the mesh wire, s is the mesh step, l is the radiation wavelength.

Example. To calculate the shielding grid for 900 MHz radiation, the shielding grid was calculated. Center frequency f = 900 MHz. Mesh wire diameter d = 1.5 mm. Permissible seepage loss p = 1%. The maximum cell size of the screening mesh is L = 4.6 mm. The signal loss due to leakage through the grid was -0.04 dB. The novelty of the claimed invention is that the grid, which allows maximum retention of fragments and does not allow the initiation of a radio-controlled explosive device, made with the expectation of the most effective shielding of electromagnetic radiation (hereinafter - EMP) in the range from 20 MHz to 6 GHz (for example, using the expression (1 ), performed on the principle of a Faraday cage of aramid fibers metallized with heavy metals.The process of metallization of aramid fibers can be carried out according to one of the known methods, for example, according to RF patent 2144965.

The most suitable metal for shielding is copper. The first stage of metallization in this case is pre-pickling - contacting aramid fibers with a pre-treatment acid (this can be aqueous nitric acid, or chlorofluorosulfonic acid in an organic liquid that does not react with acids). This process is carried out at a temperature of 20 to 40 ^° C and at a time of 5 to 60 seconds, depending on the acid concentration of the pretreatment (within 75-95%), if the fibers are in contact for more than 120 seconds in certain cases, then they are destroyed. The purpose of the first stage is to create some structural changes and microcracks on the fiber surface to facilitate further better adhesion of the metal to the fiber.

After pickling, the fibers are washed either with water to reduce the concentration of acid on the fiber, or with a base or basic sodium bicarbonate salt to neutralize the acid and remove it from the fiber. Then, desirably, but not necessarily, the fibers are dried to better remove excess moisture or acid, then a salt with a palladium and tin cation as a catalyst is added to an aqueous solution of copper, and the acid-etched and washed fibers are immersed in it and mixed to ensure surface activity fibers to interact with copper. Then, the fibers are removed from this solution, and, if necessary, immersed in an accelerator bath with diluted mineral acid to saturate the fiber surface with minerals.

Next, the metallization stage begins directly, for this, the fibers are placed or passed through a metallization bath, in which there are copper ions in a mixture with formaldehyde (catalyst), the copper concentration in these cases is diverse, but the more preferable copper concentration is 1-5 g / l, the fibers in the bath is moderately stirred for 10-20 minutes for active metallization, if the speed suddenly decreases, then formaldehyde, a pH-correcting alkaline solution and a solution with copper ions are added to the bath. All this is carried out at various temperatures from 10 to 60 ^° C, but more preferably 20-40 ^° C, after which the metallized fibers are removed from the bath.

In the case of metallization with silver, the method is carried out under similar conditions, only after etching is the washing of a solution of tin chloride and hydrochloric acid used, and a mixture of silver nitrate and ammonia is used in the metallization stage.

Similarly, metallization is carried out with nickel, and with cobalt, and with other metals.

Claims

Formula

1. An anti-splinter shielding fabric containing a mesh made with the ability to keep the fragments as much as possible and prevent the initiation of a radio-controlled explosive device, characterized in that the mesh is made according to the Faraday cage principle based on the greatest effective screening of electromagnetic radiation in the range from 20 MHz to 6 GHz; in addition, the mesh fibers are made of aramid fiber metallized with heavy metal ions.

2. An anti-fragmentation shielding fabric, characterized in that the shielding efficiency can be calculated by the formula, where S c, depending on the frequency, material, thickness and linear dimensions of the shielding mesh cell, can be determined by the following formula S_c = / 2s [ln (27rr / s)], where r is the radius of the mesh wire, s is the mesh step, l is the radiation wavelength.

3. Anti-splinter shielding fabric, characterized in that the aramid fibers are preliminarily prepared by etching in acid at a temperature of 20 to 40 ^° C and at a time from 5 to 60 seconds, depending on the concentration of the acid; then washed and metallized in a water-salt solution in the presence of a catalyst to reduce the concentration of acid on the fiber, then dried to remove excess moisture or acid, provide the surface activity of the fibers for interaction with copper, for which a salt with palladium and tin cation is added to the aqueous solution of copper as a catalyst and immerse the acid-etched and washed fibers therein and mix; then saturate the surface of the fiber with minerals, for which the fibers are immersed in an accelerator bath with dilute mineral acid; and the metallization is carried out directly, for which the fibers are placed or passed through a metallization bath in which copper ions are mixed with a catalyst formaldehyde, with the preferred concentration copper 1-5 g / l, stirred for 10-20 minutes for active metallization, at temperatures from 10 to 60 ^° C, after which the metallized fibers are removed from the bath, characterized in that a mesh is made from metallized fibers according to the Faraday cage principle from calculation of the greatest effective shielding of electromagnetic radiation in the range from 20 MHz to 6 GHz; in addition, the fibers of the mesh are made of aramid fiber metallized with heavy metal ions.