BG145Y1 - Masking coating - Google Patents

Abstract

The coating is designed for reducing the visibility and facilities for the identification of targets situated on terrains covered by snow or other, snowless, terrains, in using radar, spectrozonal or other equipment. It simultaneously secures protection in the visible, UV and radar zone to merger of the level or the surrounding background and in the nearby IR zone when using coating for snow-less terrains. It includes a supporting electroconductive tissue, impregnated on both sides by gradient layers of radioabsorbing composition, a second supporting tissue on which a base white and fixing white layer are applied on one of the sides isolating the two basic structures - the white and the radioabsorbing, a layer of polyethylene and a one-side applied layer of camouflaging paints with spectral reflective characteristics in the visible and nearby IR zone, suitable for snow-less surrounding terrains. In one of the alternatives of the coating, the layer of camouflaging paints indicated as the last one can be applied on both sides. (11) 146

Description

I. TECHNICAL FIELD

The utility model refers to a camouflage coating designed to reduce the visibility and the ability to identify mobile and stationary objects located on snow-covered or seasonal vegetation using radar, spectrosol and other techniques. For this purpose, the coating must provide attenuation of the radar signal and reduce the effective reflecting surface to the level of the radar background formed by the natural and terrain formations. The spectral reflectance characteristics and the Richter coefficient of luminance of the coating must be such that in the visible and near infrared areas, the three- or four-color scattered coating completely deforms the contours of the object and significantly reduces the maximum distance for detection and identification.

II. PREVIOUS LEVEL

OF TECHNIQUE.

Known coverings for snowy terrains and terrains covered with typical seasonal vegetation / 1-4 /. According to (1), the masking coating is a film of polar polymer-dimethylpolysiloxane containing fillers based on titanium salts, silicates or silica, used alone or in combination. According to (2), the masking coating is formed by a white masking paint containing as pigments individually or in a mixture sulfates, carbonates, silicates and / or oxides of barium, calcium and / or magnesium, a polymer and a solvent, which is applied directly on the object or on the object a coating that is then applied to it. According to (3), the masking coating is a synthetic fabric coated with suitable pigments having the required spectral reflectance characteristics in the optical range. According to (4), the masking coating is made of a suitable fabric coated with several layers of white pigments attached to a layer of polyvinyl chloride containing thin stainless steel or graphite fibers. The attenuation of the radar signal with the coating thus obtained is 6 dB.

III. THE ESSENCE OF THE USEFUL MODEL

The patent masking cover comprises electrically conductive or non-electrically conductive carrier fabric coated bilaterally with two sequentially applied absorbent layers, with a layer of masking paints applied on the underside of the coated carrier fabric and a second non-woven fabric made of non-woven fabric on the upper side. with two layers containing white pigments, the first white layer being the base and the second fixing, the carrier fabric and non-woven polyester textile fabric being isolated from each other a plastic film and are fixed to one another by mechanical stitching. The electrically conductive carrier fabric consists of continuous polyester filaments for a base with a relative linear density of 76 dtex / 2 at a base density of 310 pcs. filaments / 10 cm and electrically conductive polyacrylic staple yarns having a relative linear density of 250 dtex / 1 with a weft density of 248 pieces / 10 cm having a specific volume resistance of 10-10 ³ Q.cm obtained by specific treatment according to (5). The non-conductive carrier fabric consists of polyester continuous filaments for a base with a relative linear density of 76 dtex / 2 at a base density of 310 pcs. threads / 10 cm and polyacrylic staple yarns with a relative linear density of 250 dtex / 1 with a woven density of 248 threads / 10 cm. The first radio absorbent layer contains / in parts by weight: natural magnetite from 75 to 125, activated carbon from 50 to 100, electrically conductive carbon black from 50 to 100, butadiene acrylonitrile rubber with a low content of bonded acrylonitrile from 15 to 25, butadiene acrylonitrile rubber the content of bound acrylonitrile from 45 to 35, the emulsion polyvinyl chloride from 30 to 50, the dantimony trioxide from 10 to 20, the chloroparaffin from 5 to 15, sulfur 1 to 3, zinc diethyldithiocarbamate from 0.5 to 5 and mercaptobenzothiazole 0.1 to 1. The second radio absorbent layer contains / in wt / natural magnetite from 125 to 175, and charcoal from 25 to 75, and the other components are the same as in the first radio absorption layer. The second non-woven polyester textile fabric has a mass of 20 to 50 g / m ² and a reflection of ultraviolet light at 300 ps at not less than 45%. The base layer of white pigments contains (in parts by weight): 60% polyvinyl acetate aqueous dispersion - 5 100 and calcium carbonate from 250 to 350. The fixative layer of white pigments contains (in parts by weight): 20% gasoline solution of butyl rubber 100 and magnesium oxide 150 to 250. The thickness of the insulating film is 0.03 to 0.05 mm. In another embodiment of the masking coating, instead of a second non-woven polyester textile fabric, one-sidedly coated with two layers of white pigments, on an electrically conductive carrier fabric coated bilaterally with two sequentially applied radio-absorbing layers, a third layer of masking layer is applied, carrier fabric uses garlanded polyvinyl chloride film. In this way, a two-face masking coating is obtained, reducing the possibilities for identifying objects with radar, spectroscopic and other techniques adapted for use in different seasons.

The patented camouflage cover has the advantage that it provides a masking effect on snow terrains in the UV and radar area to blend with the level of the surrounding background, while the crucified backside also enables protection in unpowered terrains and provides use in various seasons, effect in the visible and near infrared. The second variant of the coating makes it possible to achieve complex seasonal masking.

IV. EXAMPLES

Example 1: A masking coating was constructed having the structure shown in FIG. 1 by performing the following operations:

FIG. 1 Cross section of the masking coating according to example 1.

Prepare 18% rubber solutions with the following compositions (in w / w):

- for layer N2: natural magnetite 100, activated carbon 75, conductive carbon black 75, butadiene acrylonitrile rubber with 18% content of bonded acrylonitrile 18, butadiene acrylonitrile rubber with 40% content of bonded acrylonitrile 42, emulsion polyvinylchloride, trivinyl chloride, trichlorophenylchloride sulfur 1.5, zinc diethyldithiocarbamate 0.7 and mercaptobenzothiazole 0.3.

-for layer N3: natural magnetite-150, activated carbon 50 / all other components are the same as for layer 2 /.

The resulting compositions were sequentially applied by coating on electrically conductive fabric 1 with a specific volume resistance of 100 α.αη at 150 ° C, using a coating unit.

On the one side of the structure thus obtained, a layer N4 of masking paints is provided by spraying, providing protection in the visible and near infrared area, and on the other side is placed a polyethylene film 5 with a thickness of 0.03 mm, as well as a layer 8 of non-woven polyester textile. with a mass of 30 g / m ² , after which all the layers are fixed to each other by sewing. The non-woven polyester textile 8 is coated with a base white layer 6 of the following composition (in wt / wt): 60% polyvinyl acetate aqueous dispersion 100 and calcium carbonate 300. After drying, the fixing layer is applied to it. 7 with the following composition: 24% butyl rubber-100 gasoline and magnesium oxide-200 gasoline solution.

Example 2. A masking coating was constructed having the structure shown in Figure 2 by performing the following operations:

Figure 2. Cross-section of the masking coating according to Example 2

In the manner described in Example 1, a radio absorbent structure containing layers 1, 2 and 3 is obtained and then applied on both sides by spraying a layer N4 of masking paints, providing protection in the visible and near infrared region instead of layers 5, 6, 7 and 8. The variant of the camouflage covering, suitable for seasonal camouflage in snowy terrains, is obtained.

Example 3. In the manner described in Example 1, a masking coating was prepared by coating with two radio-absorbent layers a non-conductive carrier fabric containing polyester continuous filaments with a base with a relative linear density of 76 dtex / 2 at a base density of 310 pcs. threads / 10 cm and polyacrylic staple yarns with a relative linear density of 250 dtex / 1 with weft density

248 pieces / 10 cm.

Example 4. In the manner described in Example 2, a masking coating was prepared using a non-electrically conductive support fabric containing polyester continuous filaments for a base with a relative linear density of 76 dtex / 2 at a base density of 310 pcs. threads / 10 cm and polyacrylic staple yarns with a relative linear density of 250 dtex / 1 with a weft density of 248 pcs. threads / 10 cm.

Example 5. In the manner described in Example 2, a masking coating was prepared using a garlanded polyvinyl chloride foil as the support base.

Table 1 shows the attenuation of the radar signal using masking coatings according to the examples described above:

*

Sample Decay, dB According to Example 1 -16 According to Example 2 -19 According to Example 3 -15 According to Example 4 -12 According to Example 5 -12

Claims

Claims (11)

Claims CLAIMS 1. A masking coating comprising electrically conductive or non-conductive carrier fabric coated bilaterally with two sequentially applied absorbent layers, with a layer of masking paints applied on the underside of the coated carrier fabric and a fixed fabric on the upper side. made of non-woven polyester textile coated on one side with two layers containing white pigments, the first white layer being the base and the second fixing, the carrier fabric and non-woven polyester textile fabric being isolated is of each other with polyethylene film and are fixed to each other by mechanical sewing. The masking coating according to claim 1, characterized in that the electrically conductive carrier fabric consists of polyester continuous filaments for a base with a relative linear density of 76 dtex / 2 at a basic density of 310 pcs. threads / 10 cm and of conductive polyacrylic staple yarns with a relative linear density of 250 dtex / 1 with a weft density of 248 pcs. filaments / 10 cm having a specific volume resistance of 10-10 ³ Ω.αη. The masking coating according to claim 1, characterized in that the non-conductive carrier fabric consists of continuous continuous polyester filaments of a base with a relative linear density of 76 dtex / 2 5 at a basic density of 310 pcs. threads / 10 cm and polyacrylic staple yarns with a relative linear density of 250 dtex / 1 with a wicker density of 248 pcs. threads / 10 cm. The masking coating according to claim 1, characterized in that the first radio absorbing layer contains (in parts by weight): natural magnetite from 75 to 125, activated carbon from 50 to 100, electrically conductive carbon black from 50 to 100, butadiene acrylonitrile rubber with low content of bonded acrylonitrile from 15 to 25, butadiene acrylonitrile rubber with high content of bonded acrylonitrile from 45 to 35, emulsion polyvinyl chloride from 30 to 50, dantimony trioxide from 10 to 20, chloroparaffin from 5 to 15, sulfur 1-3, zinc dicarbamate 0.5-5 and mercaptobenzothiazole 0.1-1. The masking coating according to claim 1, characterized in that the second radio absorbent layer contains (in parts by weight) natural magnetite from 125 to 175, activated carbon from 25 to 75 and the other components are the same as in the first radio absorbent layer . The masking coating according to claim 1, characterized in that the second non-woven polyester textile fabric has a mass of 20 to 50 g / m ² and a reflection of ultraviolet light at 300 ps at not less than 45%. 7. Masking coating according to claim 1, characterized in that the base layer of white pigments contains (in parts by weight): 60% polyvinyl acetate aqueous dispersion-100 and calcium carbonate from 250 to 350. The masking coating according to claim 1, characterized in that the white pigment fixation layer contains (in parts by weight): a 20% gasoline solution of butyl rubber 100 and magnesium oxide from 150 to 250. The masking coating according to claim 1, characterized in that the thickness of the polyethylene film is 0.03-0.05 mm. The masking coating according to claim 1, characterized in that instead of a second non-woven polyester textile fabric, an electrically conductive carrier fabric is used, coated bilaterally with two sequentially applied absorbent layers, on which a bilayer of masking paints is applied bilaterally. The masking coating according to claim 1, characterized in that garlanded polyvinyl chloride film is used instead of carrier fabric.