RU233803U1 - Wide-range protective camouflage coating - Google Patents

Abstract

The utility model relates to camouflage means, namely to multilayer camouflage coatings for concealing various objects in the ultraviolet, visible and infrared ranges of electromagnetic waves. The technical result of the utility model is to increase the protective and camouflage efficiency of the coating in a wide range of electromagnetic waves. The coating comprises an upper layer 1, a heat-reflecting layer 2, a heat-insulating layer 3 and a lower layer 4. Layer 1 is made of fabric with an infrared remission property. The heat-reflecting layer 2 is made of fabric with a metallized surface facing layer 3. The heat-insulating layer 3 is made in the form of a mesh frame of intersecting composite rods 5. The lower layer 4 is made of fiberglass with a one-sided or two-sided graphite coating in the form of a film, tape or mesh. It is possible to make a graphite coating in the form of a graphite additive to the composition based on polytetrafluoroethylene. The intersections of the rods 5 are fastened by three-dimensional nodal elements 6 made of polymer material. The dimensions of the elements 6 protrude beyond the mesh frame of layer 3 so that the elements 6 serve as fixators of the position of the mesh frame between layers 2 and 4. Adjacent layers are fastened through separating layers 7-9 of foamed polyethylene. 7 s.p. f-ly, 4 fig.

Description

Field of technology

The utility model relates to camouflage means, namely to multilayer camouflage coatings for concealing various objects (people, weapons, equipment) in the ultraviolet, visible and infrared ranges of electromagnetic waves.

State of the art

A camouflage coating is known, consisting of a flexible film and an insulating material with an electrically conductive metallized layer applied to it [RU145802, published 20.09.2014]. The disadvantage of this analogue is flammability. When covering an object with a high temperature, the camouflage coating loses its properties.

The closest in terms of the number of common features with the declared device (its prototype) is a multi-layer camouflage coating containing an upper, heat-reflecting, heat-insulating and lower layer, fastened with a strong thread to prevent mutual displacement [RU2802406, published 08/28/2023].

The heat-reflecting layer of the prototype is made of foil-coated thermal film, and the heat-insulating layer is made of glass fiber. The outer layers (upper and lower) are made of waterproof tarpaulin material, which can have different camouflage colors for visual camouflage on different types of terrain.

The disadvantages of the prototype, the elimination of which is the task of the claimed utility model, are as follows:

the top layer of tarpaulin with camouflage coloring in the visible range of the electromagnetic spectrum can unmask the object when observed in the infrared range (near IR range);

low strength and easy damage of thin foil thermal film do not allow maintaining the integrity of the heat-reflecting layer under mechanical impacts and bending;

The uneven thickness of the heat-insulating layer made of glass fibres, which occurs when the coating comes into contact with the protected object, makes it possible to detect its thermal signature when observed in the IR range.

The unevenness and variability of heat reflection and thermal insulation under mechanical influences and upon contact with the protected object reduces the masking efficiency in the IR range of electromagnetic waves, which is only partially compensated in the prototype by increasing the number of layers, complicating the design of the coating.

Another significant drawback of the prototype is the lack of protection of the object from ultraviolet radiation (in the range of 0.1-0.4 microns).

Disclosure of the essence of the utility model

The technical result of the utility model is an increase in the protective and masking efficiency of the coating in a wide range of electromagnetic waves (from 0.1 µm to 14 µm).

The subject of the utility model is a camouflage coating containing an upper layer, a heat-reflecting layer, a heat-insulating layer and a lower layer, fastened with a strong thread to prevent mutual displacement, characterized in that the upper layer is made of fabric with infrared remission, the heat-reflecting layer is made of fiberglass with a metallized surface facing the heat-insulating layer, which is made in the form of a mesh frame of intersecting composite rods fastened with three-dimensional nodal elements made of a polymer material, and the lower layer is made of fiberglass with a graphite coating.

The utility model has developments that consist in the fact that:

the bottom layer is made of fiberglass with a one-sided or two-sided graphite coating;

the graphite coating of the bottom layer is made in the form of a film, tape or mesh;

the graphite coating is made in the form of a graphite additive to a composition based on polytetrafluoroethylene;

the mesh frame is made from interlacing composite rods;

the mesh frame is made in the form of a set of shifted meshes, fastened with polymer ties;

at least two adjacent layers are bonded through a separating layer of foamed polyethylene.

Implementation of a utility model taking into account its developments

Fig. 1 shows the layered structure of the coating. Fig. 2, 3 and 4 illustrate the implementation of the heat-insulating layer.

The coating comprises a top layer 1, a heat-reflecting layer 2, a heat-insulating layer 3 and a bottom layer 4, fastened with a strong thread (not shown in the figures).

Layer 1 is made of fabric with a camouflage pattern, the spots of which differ in the intensity of reflection of the color components of the visible spectrum of the electromagnetic wave range. In this case, the fabric of layer 1 is made with the property of infrared remission (IR remission), providing camouflage spotting in the infrared regions of the electromagnetic spectrum (0.76 - 14) µm, used in night vision devices (infrared cameras).

Heat-reflecting layer 2 is made of glass fabric with a surface metallized with aluminum, chrome, nickel or other metal with high heat-reflecting capacity. Metallization of the glass fabric surface can be done either by gluing foil (glass foil-fabric) or by spraying. Layer 2 faces the metallized surface downwards - to layer 3 and the masked object.

The heat-insulating layer 3 is made in the form of a mesh frame of intersecting rods 5 made of a polymer composite - fiberglass, basalt fiberglass or carbon fiber. The intersections of the rods 5 are fastened with volumetric nodal elements 6 made of a polymer material with low thermal conductivity. Polypropylene, polyurethane, polyethylene, polyamide or a polymer material based on bitumen can be used as the polymer material of the elements 6. The elements 6 can be manufactured by casting in the form of a cylinder, ball or polyhedron. The dimensions of the elements 6 protruding beyond the mesh frame are two to three times greater than the total thickness of the two rods 5 so that the elements 6 serve as fixators of the position of the mesh frame between layers 2 and 4. The grids of layer 3 can be made with interlacing of the rods 5.

The lower layer 4 adjoins the heat-emitting masked object, separates its heated surface from the heat-insulating layer 3 and, fastened with a strong thread to layer 1, forms the claimed multilayer coating. Layer 4 is made of fiberglass with a graphite coating in the form of a film, tape or mesh. The graphite coating can be applied to the fiberglass of the lower layer on one or both sides. The graphite coating can be made in the form of a graphite additive based on polytetrafluoroethylene.

To enhance the effect of suppressing infrared radiation emanating from the heated protected object, additional heat-insulating layers made, for example, of foamed polyethylene can be placed between two adjacent main layers 1-4. The maximum number of such layers is three. In Fig. 1 they are designated 7, 8 and 9.

Additional heat-insulating layers 8 and 9 made of foamed polyethylene, laid on both sides of the mesh frame of layer 3, also soften the mechanical impact of elements 6 on layers 2 and 4.

The structure of the claimed coating is illustrated by the following examples.

Example 1

Top layer 1 - polyamide fabric of the brand "Cordon Prime" with a camouflage pattern "Digital" and polyurethane coating. The fabric has IR remission in the near IR range.

Heat-reflecting layer 2 – glass-foil fabric grade SF 160-50.

The heat-insulating layer 3 (frame Fig. 3) is made in the form of two identical grids with square cells. The cell size is 50x50 mm. The grids of the frame are shifted relative to each other by 25 mm and are connected to each other by cross-winding. The longitudinal and transverse rods 5 of a round cross-section with a diameter of 2 mm are made of fiberglass. The elements 6 are spherical in shape, with a diameter of 10 mm. The material of the elements 6 is polystyrene.

Bottom layer 4 - fiberglass fabric TERMITE PTFE-1-430AS[110]black of medium density, coated on one side with a composition based on polytetrafluoroethylene with a graphite additive. The coating is made in the form of a tape, is resistant to ultraviolet radiation, increases the thermal insulation properties of the fabric, its strength and chemical resistance.

Layers 7 and 8 - foamed polyethylene.

Example 2

Top layer 1 - 1000D Cordura fabric with IR remission in the "Multicam" color scheme.

Heat-reflecting layer 2 - metallized glass fabric type 1032/9682, produced by the Interglas company [www.interglas.ru].

The heat-insulating layer 3 (frame Fig. 4) is made of three grids with square cells, connected by polypropylene ties. Rods 5 of circular cross-section with diameters of 5 mm, 2 mm are made of fiberglass and 2.5 mm of basalt plastic. The cell size is 150x150 mm, 100x100 mm and 50x50 mm. The shape of elements 6 is shown in Fig. 2. Elements 6 protrude beyond the grids by 25 mm.

Bottom layer 4 - fiberglass with graphite coating ProSil-620-GN2025 in the form of a film or mesh. It is produced on textured fiberglass with a double-sided coating of graphite emulsion. The graphite coating makes the fabric resistant to ultraviolet radiation, as well as to high temperatures and abrasion.

Layers 7 and 8 - foamed polyethylene.

The conducted full-scale tests confirmed that the above-described coating, containing an upper layer, a heat-reflecting layer, a heat-insulating layer and a lower layer, fastened with a strong thread, in which the upper layer is made of fabric with IR remission, the heat-reflecting layer is made of fiberglass with a metallized surface facing the heat-insulating layer, which is made in the form of a mesh frame of intersecting composite rods fastened with three-dimensional nodal elements made of a polymer material, and the lower layer is made of fiberglass with a graphite coating, has high camouflage efficiency in a wide range of electromagnetic waves (0.1 μm-14 μm).

Claims (8)

1. A camouflage coating comprising an upper layer, a heat-reflecting layer, a heat-insulating layer and a lower layer, fastened with a strong thread to prevent mutual displacement, characterized in that the upper layer is made of fabric with infrared remission, the heat-reflecting layer is made of fiberglass with a metallized surface facing the heat-insulating layer, which is made in the form of a mesh frame of intersecting composite rods fastened with three-dimensional nodal elements made of a polymer material, and the lower layer is made of fiberglass with a graphite coating. 2. A camouflage coating according to item 1, in which the lower layer is made of fiberglass with a one-sided graphite coating. 3. A camouflage coating according to item 1, in which the lower layer is made of fiberglass with a double-sided graphite coating. 4. A camouflage coating according to item 1, in which the graphite coating of the fiberglass of the lower layer is made in the form of a film, tape or mesh. 5. A camouflage coating according to item 1, in which the graphite coating is made in the form of a graphite additive to a composition based on polytetrafluoroethylene. 6. A camouflage coating according to claim 1, in which the mesh frame is made with an interweaving of intersecting composite rods. 7. A camouflage coating according to item 1, in which the mesh frame is made in the form of a set of offset meshes fastened with polymer ties. 8. A camouflage coating according to claim 1, wherein at least two adjacent layers are bonded through a separating layer of foamed polyethylene.