RU2798354C1 - Multilayer camouflage material, method for manufacturing a raincoat from multilayer camouflage material, camouflage raincoat, camouflage bandana, camouflage gloves - Google Patents

Abstract

FIELD: clothing.

SUBSTANCE: multilayer camouflage material for the manufacture of clothing, hats. The multilayer camouflage material includes an outer camouflage layer, a barrier layer and an inner camouflage layer, while the outer camouflage layer is made of an outer camouflage fabric and a mineral fabric that are permanently interconnected, which is provided with a rubber coating on the side of the camouflage fabric, the barrier layer is made of an integrally interconnected IR-reflective film, foamed polyethylene film and electrically insulating fiberglass, and the inner camouflage layer is made of integrally interconnected mineral fabric and camouflage fabric, while the multilayer camouflage material is equipped with a reflective layer placed between the barrier layer and the inner camouflage layer, made of one-piece interconnected IR-reflective film, polyethylene foam film, IR-reflective film and polyethylene foam strips, with air gaps between all layers.

EFFECT: providing reliable masking of a biological object in the daytime and at night.

6 cl, 5 dwg

Description

The invention relates to materials that can be used in the manufacture of clothing, hats and other garments intended for the following masking: in the visual spectrum, acoustics (for example, from sonar), electromagnetic spectrum (for example, from radar), thermal field ( for example, from a thermal imager), and providing masking of a biological object in the daytime and at night.

A multilayer infrared-hiding film material is known from the technical field, which contains a first layer of a GST phase change alloy (Ge2Sb2Te5), a Mo nanofilm, a second layer of a GST phase change alloy and a reflective layer of a Mo film, wherein the Mo nanofilm layer is located between the first layer. GST phase change alloy and a second layer of GST phase change alloy, and the Mo thin film reflective layer is located on one side away from the Mo nano thin film layer, (see CN 113885103, CL G02B 1/00, publ. 4.01. 2022). The infrared stealth material described in the patent refers to complex expensive products that cannot be used on a large scale - for example, for the manufacture of protective clothing.

A material is known that reflects infrared radiation, containing a textile base, metallized and microporous membrane layers, and polyester textile material with water-repellent impregnation is used as a textile base, the metallized layer is represented by titanium nitride, and the microporous membrane layer is made of thermoplastic polyurethane resin and is placed between the textile base and a metallized layer, while titanium nitride is deposited on a microporous membrane layer at the atomic-molecular level in an amount of 1-2 g/m ² , while the textile base contains a camouflage pattern (see patent for invention RU No. 2403328, class D03D 11/ 00, published in 2009). This material provides a high level of camouflage protection in the daytime, however, a continuous metallized layer included in the structure of the material, taking on thermal radiation, gradually accumulates (accumulates) it, after which its heat transfer to the environment begins, i.e. camouflage at night, especially in the cold season, is limited.

Known camouflage material in the infrared range, containing an outer layer, close in spectral reflection characteristics to the background surface, and an inner layer of a material with low thermal conductivity, in which the outer layer is made of fibrous cellulose acetate material, known as the Petryanov cellulose acetate (FPA) filter, with the inclusion of nanoparticles nickel, and PYROGEL®XT, which is low-permeable to the IR part of the radiation spectrum, was chosen as the inner layer, while an intermediate layer of water-saturated high-molecular gel is placed between these layers, which can evaporate into the surrounding space (see patent for invention RU No. 2560007, F41H 3/02, published in 2015).

The described material reduces the temperature of the outer surface of the multilayer material by reducing its thermal conductivity and blocking the infrared radiation of the biological object. However, the design of the material does not provide for the possibility of heat removal from the underwear space, which worsens the protective characteristics of the material in the mid-IR range. One of the disadvantages of this material is the high cost of the layers used and their insufficiently high efficiency.

Known multilayer low-emissivity material containing a textile base, an internal heat-reflecting layer, characterized in that the material additionally contains on the outer surface of the textile base or a low-e coating with a metal-dielectric structure Al ₂ O ₃ (55 nm) - Cu (10 nm) - Al ₂ O ₃ (55 nm), transparent in the visible and near infrared frequency ranges of electromagnetic radiation, or a low-emissivity coating, which is used as an electrically conductive semiconductor, such as indium oxide doped with tin with a thickness of 600 nm (see patent for invention RU No. 2676574, D03D 11 /00, published in 2019). Such a material has a higher level of air permeability and ventilation of the underwear space than those described above, while reducing operational reliability due to the fact that the outer low-e coating wears out quickly and loses its properties. At the same time, the use of an IR-reflecting layer on the outer surface of the material does not make it possible to make the material double-sided.

A plaid dressing gown is known, which includes a panel made of dense fabric, for example, fleece, polyester, with accessories fixed to it in the form of locks, zippers and buttons, which makes it possible to form a surface covering the human body with heat preservation in the volume formed by this surface, in which the panel is made of two layers of different fabrics located one above the other, one layer of dense fabric, for example, fleece, polyester, with fittings fixed to it in the form of locks, zippers and buttons, and the second layer of fabric made of invisible threads, invisible on a white and blue background, known and used in surgery, attached along the periphery to a layer of dense tissue with fittings fixed to it in the form of locks, zippers, buttons, allowing, together with both layers of different tissues located one above the other, to form a surface covering the human body with heat preservation in the formed by this surface of two layers of fabric in volume, while using such a plaid bathrobe with the upper outer surface of the layer of fabric made of invisible threads, the plaid bathrobe on the outside contains areas covered with an invisible thread, the plaid bathrobe is equipped with a hood (see Fig. patent for invention RU No. 2492778, class. A41D 15/00, publ. in 2012). Such a product is intended, first of all, to retain heat, and in one of the manufacturing options it can become, according to the author of the patent, invisible. The use of various novelties to obtain the property of "invisibility" in the manufacture of layers of a plaid-cloak may have an insignificant effect, but it is not possible to make such a product completely invisible to the thermal imager for the above reasons.

The closest analogue to the claimed invention is a two-sided multilayer camouflage material containing a textile base with camouflage coloring, metallized and microporous layers, and cotton or cotton-lavsan material with a cotton fiber content of at least 60% is used as a textile base, the metallized layer has a porous structure, is placed in the material for 1/2-2/3 of its thickness and is represented by a polymer composite mixture, including aluminum powder, while on the side of the metallized layer it contains a laminated layer of a microporous structure, based on a film-forming aqueous solution of an acrylic polymer, either with the addition of a pigment dye, or without it (see patent for invention RU No. 2490379, class D03D 11/00, published in 2011). Such material helps to increase the degree of camouflage protection of the object in the daytime and at night due to the restructuring of the multilayer material and its two-sided functionality. However, the main disadvantage of such products - the accumulation of thermal radiation from the material from the object, in this case, the human body, is only partially solved in the above-described product.

Technical problem: low duration of preservation of the camouflage properties of materials in the IR range, consisting of inexpensive component layers, as well as the high complexity and cost of materials based on the properties of expensive science-intensive products, with low operational ability.

The present invention is aimed at solving the technical problem of improving operational properties and reliability in extreme conditions in the presence of both low and high temperatures, ensuring a normal microclimate inside the product, expanding the operating temperature range and increasing the duration of preservation of the camouflage properties of materials in the IR range.

The solution of the stated technical problem is achieved due to the fact that the multilayer camouflage material includes an outer camouflage layer made of an outer camouflage fabric and mineral fabric that are integrally interconnected, which is provided with a rubber coating on the side of the camouflage fabric, a barrier layer made of integrally interconnected IC - reflective film, polyethylene foam film and electrically insulating glass cloth, a reflective layer made of integrally bonded IR reflective film, polyethylene foam film, IR reflective film and polyethylene foam strips, and an internal camouflage layer made of integrally bonded mineral fabric and camouflage fabric between each other, and between all layers air gaps are made. And as a mineral tissue, basalt tissue is used.

And also due to the fact that in the method of manufacturing a raincoat from a multilayer camouflage material, including cutting a multilayer camouflage material into two floors, a back, sleeves, pockets and a hood, followed by connecting the cutting parts to each other, in the manufacture of a raincoat, a multilayer camouflage material is used, made of an outer camouflage layer consisting of an outer camouflage fabric and a mineral fabric integrally connected to each other, which is provided with a rubber coating on the side of the camouflage fabric; made of an integrally interconnected IR reflective film, a film of polyethylene foam, an IR reflective film and foamed polyethylene strips, and an internal camouflage layer made of an integrally interconnected mineral fabric and a camouflage fabric, while between all layers there are air gaps, and cutting is carried out in such a way that the strips of polyethylene foam of the reflective layer are located vertically.

And also due to the fact that the full camouflage equipment consists of:

- a camouflage raincoat, including two floors, a back, sleeves, pockets, a hood and fasteners, made of a multilayer camouflage material, in which the multilayer camouflage material is made of an outer camouflage layer, consisting of an outer camouflage fabric and a mineral fabric that are inseparably interconnected side of the camouflage fabric is provided with a rubber coating, a barrier layer consisting of an integrally interconnected IR reflective film, a film of polyethylene foam and electrically insulating glass cloth, a reflective layer made of an integrally interconnected IR reflective film, a film of foamed polyethylene, an IR- reflective film and strips of foamed polyethylene, and an internal camouflage layer made of inseparably interconnected mineral fabric and camouflage fabric, while between all layers there are air gaps, and strips of foamed polyethylene of the reflective layer are located vertically, and the pockets are made overhead and located on the outer surface of the outer camouflage layer;

- a camouflage bandana made of a multilayer camouflage material, characterized in that the multilayer camouflage material is made of an outer camouflage layer consisting of an outer camouflage fabric and a mineral fabric integrally connected to each other, which is provided with a rubber coating on the side of the camouflage fabric, a barrier layer consisting of integrally bonded IR reflective film, polyethylene foam film and electrically insulating glass cloth, a reflective layer made of integrally bonded IR reflective film, polyethylene foam film, IR reflective film and polyethylene foam strips, and an internal camouflage layer made of inseparably interconnected mineral fabric and camouflage fabric, while between all layers there are air layers, and strips of foamed polyethylene of the reflective layer are located vertically, while the bandana is equipped with a slit for the eyes and an elongated apron located in its lower front zone;

- camouflage gloves made of a multilayer camouflage material, characterized in that the multilayer camouflage material is made of an outer camouflage layer consisting of an outer camouflage fabric and a mineral fabric integrally connected to each other, which is provided with a rubber coating on the side of the camouflage fabric, a barrier layer consisting of integrally bonded IR reflective film, polyethylene foam film and electrically insulating glass cloth, a reflective layer made of integrally bonded IR reflective film, polyethylene foam film, IR reflective film and polyethylene foam strips, and an internal camouflage layer , made of mineral fabric and camouflage fabric, which are integrally interconnected, while between all layers there are air layers, and the gloves are provided with horizontal slots in the middle zone from the inside.

The invention is illustrated by drawings.

In FIG. 1 schematically shows layers of multilayer camouflage material. In FIG. 2 is a schematic representation of a camouflage raincoat. In FIG. 3 is a schematic representation of a camouflage bandana. In FIG. 4 schematically shows a camouflage glove in an unbuttoned form. In FIG. 5 is a schematic representation of a buttoned camouflage glove.

The multilayer camouflage material has a two-sided structure and is designed for the following masking: in the visual spectrum, in acoustics (for example, from a sonar), the electromagnetic spectrum (for example, from a radar), a thermal field (for example, from a thermal imager) and provides long-term masking of a biological object in the daytime and night time. Such material is easy to manufacture and operate and is aimed at solving various problems. Multilayer camouflage material contains several main layers and a number of additional, increasing the effectiveness of its protective properties (see Fig. 1). The outer camouflage layer I includes an outer camouflage fabric 1 and a mineral fabric 2 that are integrally connected to each other, which has a rubber coating 3 on the side of the fabric 1. These elements can be sewn, glued or soldered together until a tight connection is formed.

Camouflage fabric 1 is a fabric of a special color that allows you to "break" the silhouette of an object (object or person) covered with it, and make it less noticeable or distort its shape and movement. It has durability, high hygienic qualities, water resistance, windproof properties, resistance to external influences (UV radiation, high temperatures, salt water, chemical weapons, etc.). For operation in different conditions, you can use materials such as:

- polyester or nylon (fabric is durable, not blown and retains heat, resistant to chemicals);

- fabric resistant to tearing due to the presence of polyester threads passing through the cotton base and forming a kind of reinforced lattice;

- fabric woven in such a way that the inside is cotton, and the front part consists of polyester fibers, while clothes using it remain soft and pleasant to the body inside, absorb sweat, dry quickly, repel dirt and water;

- for winter types of camouflage, polyester fiber is used, woven in such a way that air chambers remain inside it, such a fabric can be finished with water-repellent impregnation on top;

- membrane fabric with a masking pattern on top, it protects well from cold, wind and rain.

Mineral fabric 2, preferably made of basalt cloth, has the following properties: high adhesion of the coating, fire resistance, non-flammability, excellent tensile strength, maintains integrity at temperatures up to 982 degrees, exhibits resistance to electromagnetic radiation and, in combination with other layers, the ability to some time to withstand a thermal shock of several thousand degrees, as well as aggressive chemical exposure. The rubber coating 3 applied to the outer side of the fabric 2 provides moisture protection and enhances all the properties of the outer layer. Such a fabric 2 (especially basalt) has a high thermal conductivity, is able to take on the ambient temperature, evenly distributing it over the entire surface of the material. The outer camouflage layer I, which includes an outer camouflage fabric 1 and a mineral fabric 2 with a rubber coating 3 that are integrally connected to each other, is an effective means of camouflage with respect to the surrounding space.

The barrier layer II, consisting of an IR reflective film 4, a polyethylene foam film 5 and an electrically insulating glass cloth 6 firmly interconnected, is a protective layer that performs several functions. The IR reflective film 4 can be made of foil or polymeric materials with metallized sputtering. It is preferable that metallized lavsan film be used as the IR reflective film 4, in the manufacture of which manufacturers apply aluminum, copper or steel coatings as the main material. For these purposes, it is also customary to use titanium or its nitride. All substances are characterized by optimal adhesion properties and perfectly tolerate temperature changes. In addition, they are resistant to wear and mechanical damage. The metallized lavsan film reflects radiant energy and creates protection from the IR range. It is made on the basis of polymer types of raw materials, presented in a huge variety. The main materials are different types of raw materials, the most common are the following options:

Polypropylene;

PVC;

Polyethylene terephthalate;

UHMWPE;

Polyamide;

Polystyrene;

Polycarbonate.

The foamed polyethylene film 5 is a polyethylene that undergoes foaming with hydrocarbons during the manufacturing process. The result is an elastic elastic web having a closed-pore cell structure. The material is resistant to low temperatures. Even at ambient temperatures below 60 degrees Celsius, polyethylene foam retains such important characteristics as strength and elasticity. The level of thermal conductivity of polyethylene is very low and is at the level of 0.038-0.039 W / m * K, i.e. has a high level of thermal insulation. The composition of PE does not include any components that can harm the human body. In addition, even during combustion, the material does not emit toxic components. Foamed polyethylene has a high level of wear resistance. For a camouflage material, it is important that it protects the outer layer I from heating from the human body and from displaying the silhouette in the IR range. At the same time, it is a good protection against rain, snow, frost.

Electrical insulating glass fabric 6 refers to silica materials. It has chemical and biological inertness, high strength, exceeding that of steel wire, durability, moisture resistance, lack of mechanical wear and corrosion, dimensional stability during operation, heat resistance, wide operating temperature range (from -200 to +600 C), low thermal conductivity. It is a completely non-combustible material, its melting point ranges from 1200 to 1400°C. The properties of the electrically insulating glass cloth 6 make it possible to improve the functions of the IR reflective film 4, the polyethylene foam film 5, because has dielectric properties and hides the silhouette of the object from devices of different ranges.

The reflective layer III, consisting of firmly interconnected IR reflective film 7, polyethylene foam film 8, IR reflective film 9 and polyethylene foam strips 10, located longitudinally on the material, performs not only a reflective function, but also performs a redistribution function heat generated by an object - in particular the human body. The air between the polyethylene foam strips 10 is not only a coolant, but also removes the generated heat beyond the boundaries of the product made of multilayer camouflage material.

The inner camouflage layer IV includes mineral fabric 11 and camouflage fabric 12 that are integrally interconnected. Mineral fabric 11, preferably made of basalt fabric, has the above properties and is the first barrier in the release of heat by the human body, absorbing and redistributing it over the entire surface of the fabric 11. Since the multi-layer camouflage material has a two-sided structure, the camouflage fabric 12 has a different pattern than the outwardly located camouflage fabric 1 in case of need for quick camouflage in other weather and climatic conditions. Camouflage fabric 12 well removes all body fumes, so the clothes under it always remain dry and the person does not freeze. After the fabrics 1 and 12 are made, a background of the desired shade is applied to it, and after this spot. When determining the composition of dyes, reflection indicators are taken into account. For each area, the geometric structure of spots, their shades and saturation are individual and are calculated by specialists.

An important property of the multilayer camouflage material is the presence of air gaps 13, 14 and 15 between layers I, II, III and IV. They are not only heat-insulating elements of the material, but also a means of heat removal outside the material due to the openness of the air cavities. All four layers I, II, III and IV with air spaces 13, 14 and 15 between them are interconnected in such a way as to preserve the air gaps as much as possible and ensure their communication with the outside air. In fact, each layer I, II, III and IV also consists of several densely interconnected layers described above, having a specific purpose and performing separate functions, which together make it possible to obtain a synergistic effect with a super-total result. For example, the introduction of a non-combustible electrically insulating fabric 6 with dielectric properties into the barrier layer II increases the effect of both the IR reflective film 4 and the foamed polyethylene film 5. This improves the IR reflective effect of the barrier layer II and its heat, moisture, and cold protection. The reflective layer III, consisting of the IR-reflective film 7, the polyethylene foam film 8, the IR-reflective film 9, and the polyethylene foam strips 10 firmly bonded together, also performs various functions to obtain a super-cumulative effect. The connection of the mineral fabric 2, preferably made of basalt fabric, with the camouflage fabric 1 of the outer layer I, as well as the mineral fabric 11 with the camouflage fabric 12 of the inner layer IV, is not only an initial barrier to heat generation in the IR range, but also protects the object from due to the ability to withstand thermal shock of several thousand degrees for some time, as well as aggressive chemical exposure. Moreover, the fulfillment of this function is also ensured when the cloak is turned inside out with the inner layer IV when the surrounding space changes and the need to use a different camouflage.

The connection of layers I, II, III and IV with each other can be carried out in different ways. The main requirement is the preservation of air gaps 13, 14 and 15 between layers I, II, III and IV. Bonding, soldering (preferably spot-on) and stitching can be used to join layers I, II, III and IV to form a multilayer camouflage material. For machine stitching, stitches of maximum length with minimum thread tension are used. The stitches should be spaced at least 30 centimeters apart. It is allowed to use longitudinal and transverse stitches in compliance with the requirements for maintaining air gaps in the areas of connection of layers I, II, III and IV with each other.

The method for manufacturing a raincoat from a multilayer camouflage material is based on the properties of the layers I, II, III and IV included in it, as well as the air layers 13, 14 and 15 between them and the interaction of the above layers with each other. The outer camouflage layer I includes an outer camouflage fabric 1 and a mineral (preferably basalt) fabric 2 that are integrally interconnected, which has a rubber coating 3 on the fabric 1 side. foamed polyethylene and electrically insulating glass cloth 6. The reflective layer III consists of firmly interconnected IR-reflective film 7, film 8 of foamed polyethylene, IR-reflective film 9 and strips 10 of foamed polyethylene. The inner camouflage layer IV includes a mineral (preferably basalt) fabric 11 and a camouflage fabric 12 that are integrally interconnected.

Schematically shown in Fig. 2 camouflage raincoat is designed for visual, acoustic, electromagnetic camouflage and protection from a thermal imager in the infrared range. For its manufacture, the above-described multilayer camouflage material is used, cutting out the details of the raincoat in such a way that the right and left floors 16 and 17, the back (not shown in the figure), sleeves 18, hood 19 and pockets 20 have strips 10 of foamed polyethylene, located longitudinally relative to cut elements. It is desirable that the ends of the strips 10 intended to remove heat from the zone of maximum heating remain open during the manufacture of the raincoat.

In the preferred variant of connecting the parts of the raincoat, the stitching was carried out only at the joints: 21 (floors 16 and 17 with a back), 22 (floors 16 and 17 with sleeves 18), 23 (floors 16 and 17 with patch pockets 20), 24 (connection with a hood 19), 25 (floor board 17). Bottom edges 26, 27, 28 are not stitched. In this case, the heat is most effectively removed through the air gaps 13, 14, 15 and the gaps between the longitudinally arranged strips 10 of foamed polyethylene.

Such a double-sided camouflage raincoat turns out to be quite compact and easily fits in a small backpack. In its manufacture, the most convenient fasteners (for example, Velcro) are used, types of fabrics and patterns applied to them are provided and calculated when used for external camouflage fabric 1 and internal camouflage fabric 12. changing external conditions without losing all the camouflage properties of the camouflage material.

To ensure complete protection of a person, in addition to a camouflage raincoat, it is advisable to use a camouflage bandana (see Fig. 3) and camouflage gloves (see Fig. 4 and 5). The camouflage bandana is made from the four-layer double-sided material described above, shown in FIG. 1, consisting of an outer camouflage layer I (outer camouflage fabric 1 and a mineral (preferably basalt) fabric 2, which has a rubber coating 3 on the side of the fabric 1), a barrier layer II (an IR reflective film 4 that are integrally interconnected) , polyethylene foam film 5 and electrically insulating glass cloth 6), reflective layer III (internally bonded IR reflective film 7, polyethylene foam film 8, IR reflective film 9 and polyethylene foam strips 10), internal camouflage layer IV ( integrally interconnected mineral (preferably basalt) fabric 11 and camouflage fabric 12). The bandana is provided with a slit 29 for the eyes, the edges 30 and 31 of which are closed and stitched (or tightly closed without air entering the material). It is important that the front bandana is provided with an elongated apron 32, while the material used to make the bandana is located in such a way that the strips 10 of polyethylene foam layer III are placed longitudinally, and the edges 33 of the apron 32 and the lower edge of the back of the bandana (not shown in the figure) are not stitched. This design of the bandana provides efficient heat removal from the human head through the air gaps 13, 14, 15, and especially in the gaps between the longitudinally arranged strips 10 of foamed polyethylene inside the raincoat.

Shown in FIG. 4 and 5, the camouflage gloves are also made from the above-described four-layer double-sided material shown in FIG. 1, consisting of an outer camouflage layer I (outer camouflage fabric 1 and a mineral (preferably basalt) fabric 2, which has a rubber coating 3 on the side of the fabric 1), a barrier layer II (an IR reflective film 4 that are integrally interconnected) , polyethylene foam film 5 and electrically insulating glass cloth 6), reflective layer III (internally bonded IR reflective film 7, polyethylene foam film 8, IR reflective film 9 and polyethylene foam strips 10), internal camouflage layer IV ( integrally interconnected mineral (preferably basalt) fabric 11 and camouflage fabric 12). The gloves are provided with horizontal slits 34 in the middle area on the inside, designed to quickly remove the fingers if necessary, while the hand remains protected and disguised. The gloves have straps 35 with Velcro 36 (or other quick-release elements) in the upper area. If necessary, the tapes are tightened around the wrist and secured with Velcro 36. In addition, it is important that the pockets 20 and their slots are made in such a way that the gloves can fit freely in the pockets 20.

All of the above details of human equipment successfully fulfill the main task - protection from a thermal imager, which consists in shielding the generated heat, as well as from devices with other research ranges (for example, acoustic and electromagnetic), while overheating of the human body is excluded, because. The design of the multi-layer camouflage material ensures the redistribution of the heat generated by the human body over all layers and efficient heat removal to the outside between all layers, allowing it to merge with the ambient temperature. Provides short-term protection against thermal shock of several thousand degrees, as well as against aggressive chemical attack. More effective is heat, moisture, cold protection. Visual protection is provided by properly selected camouflage and double-sided material. All equipment is compact, lightweight and fits easily in a small backpack.

Thus, the technical result achieved using the claimed invention is to increase the operational properties and reliability of equipment in extreme conditions in the presence of both low and high temperatures, to ensure a normal microclimate inside the product, to expand the operating temperature range and to increase the duration of preservation of the camouflage properties of materials. in the IR range.

Claims (6)

1. A multilayer camouflage material, including an outer camouflage layer, a barrier layer and an inner camouflage layer, characterized in that the outer camouflage layer is made of external camouflage fabric and mineral fabric that are integrally connected to each other, which is provided with a rubber coating on the side of the camouflage fabric, the barrier layer is made from integrally interconnected IR-reflective film, polyethylene foam film and electrically insulating fiberglass, and the inner camouflage layer is made from integrally interconnected mineral tissue and camouflage tissue, while the multilayer camouflage material is provided with a reflective layer located between the barrier layer and the inner camouflage layer made of integrally interconnected IR-reflective film, foamed polyethylene film, IR-reflective film and foamed polyethylene strips, with air gaps between all layers. 2. Material according to claim 1, characterized in that basalt tissue is used as a mineral tissue. 3. A method for manufacturing a raincoat from a multilayer camouflage material, including cutting a multilayer camouflage material into two floors, a back, sleeves, pockets and a hood, followed by connecting the cutting parts to each other, characterized in that in the manufacture of a raincoat, a multilayer camouflage material is used, made from an outer camouflage a layer consisting of an external camouflage fabric and a mineral fabric integrally connected to each other, which is provided with a rubber coating on the side of the camouflage fabric; from integrally interconnected IR-reflective film, polyethylene foam film, IR-reflective film and foamed polyethylene strips, and an internal camouflage layer made of integrally interconnected mineral fabric and camouflage fabric, while air gaps are made between all layers , and cutting is carried out in such a way that the strips of polyethylene foam of the reflective layer are located vertically. 4. A camouflage raincoat, including two floors, a back, sleeves, pockets, a hood and fasteners, made of a multilayer camouflage material, characterized in that the multilayer camouflage material is made of an outer camouflage layer, consisting of an outer camouflage fabric and a mineral fabric that are integrally interconnected , which is equipped with a rubber coating on the side of the camouflage fabric, a barrier layer consisting of an integrally interconnected IR reflective film, a film of polyethylene foam and electrically insulating glass cloth, a reflective layer made of an integrally interconnected IR reflective film, a film of foamed polyethylene , IR-reflective film and strips of foamed polyethylene, and an internal camouflage layer made of inseparably interconnected mineral fabric and camouflage fabric, while air gaps are made between all layers, and strips of foamed polyethylene of the reflective layer are located vertically, and the pockets are made overhead and located on the outer surface of the outer camouflage layer. 5. A camouflage bandana made of a multilayer camouflage material, characterized in that the multilayer camouflage material is made of an outer camouflage layer consisting of an outer camouflage fabric and a mineral fabric integrally connected to each other, which is provided with a rubber coating on the side of the camouflage fabric, a barrier layer consisting from integrally interconnected IR reflective film, polyethylene foam film and electrically insulating glass fabric, a reflective layer made from integrally interconnected IR reflective film, polyethylene foam film, IR reflective film and polyethylene foam strips, and internal camouflage a layer made of inseparably interconnected mineral fabric and camouflage fabric, while air layers are made between all layers, and strips of polyethylene foam of the reflective layer are located vertically, while the bandana is equipped with a slit for the eyes and an elongated apron located in its lower front zone . 6. A camouflage glove made of a multilayer camouflage material, characterized in that the multilayer camouflage material is made of an outer camouflage layer, consisting of an outer camouflage fabric and a mineral fabric integrally connected to each other, which is provided with a rubber coating on the side of the camouflage fabric, a barrier layer consisting from integrally interconnected IR reflective film, polyethylene foam film and electrically insulating glass fabric, a reflective layer made from integrally interconnected IR reflective film, polyethylene foam film, IR reflective film and polyethylene foam strips, and internal camouflage a layer made of inseparably interconnected mineral fabric and camouflage fabric, while between all layers there are air layers, and the glove is equipped with horizontal slots in the middle zone from the inside.

Images