RU2546470C1 - Camouflage net - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: camouflage net comprises a bearing net consisting of fibres located in transverse and longitudinal directions, arranged with free space from each other; metal-coated polymer bands that are electroconductive at least on one side; a layer which on both sides the shape of depressions and(or) protrusions distributed on its surface; a camouflage coloured layer, wherein the fibres of the bearing net are arranged to form cells, the polymer bands are in the form of a layer which repeats at both sides the shape of depressions and(or) protrusions distributed on its surface; the metal coating is reflective and is deposited on the surface of the polymer bands on at least one side; the camouflage coloured layer is deposited on the corresponding reflective coating, and the depressions and protrusions are in the form of structures with a pointed and/or rounded vertex, which enable reflection at both of their lateral surfaces of location radiation in at least one direction, different from the source of the location radiation, wherein the polymer bands are arranged in the transverse direction or longitudinal direction in corresponding series-arranged cells while allowing support thereof by corresponding sides of the cells.

EFFECT: high effectiveness of camouflage by using camouflage materials which employ the principle of protecting a camouflaged object based on change in characteristics of incident radiation.

28 cl, 11 dwg

Description

The present invention relates to the field of camouflage, and in particular to masking objects from surveillance devices, in particular to camouflage products for masking objects from surveillance devices, and can be used mainly in the manufacture of camouflage nets, wraps, garments hiding an object located beneath them, for example personnel, equipment, facilities, etc.

At present, the urgent task is to protect weapons and military equipment (IWT), military facilities, economic facilities, public administration systems and infrastructure, as well as civilians and military personnel from high-precision weapons (WTO) strikes, mainly air and sea based with all types of optoelectronic guidance. A comparative analysis of the current state and capabilities of domestic air defense systems and air attacks by a likely enemy allows us to conclude that even with high efficiency air defense systems, the probability of non-damage to covered objects can be provided only at the level of 0.4-0.8. The effectiveness of the use of WTO systems approaches the effectiveness of nuclear weapons, allows the enemy to solve the tasks while overcoming the air defense system even with a small amount of high-precision ammunition (VTB).

In such a situation and in connection with the permanent ever-increasing complexity of the systems for detecting, observing and targeting the WTO, camouflage and measures to mislead the enemy play an increasingly important role in modern warfare, ensuring the survival of important objects, which is clearly manifested in wars and conflicts in Syria, Libya, South Ossetia, Israel, Yugoslavia, Iraq and Afghanistan. At the same time, the increase in the probability of preserving the most important weapons and military equipment, military facilities, economic facilities, public administration systems, infrastructure, civilians and military personnel from WTO attacks directly depends on a decrease in the visibility and recognition of ground targets, which is possible, first of all, for counteraction account through the use of group and individual defense complexes.

Disguise and secrecy measures are used to mislead the enemy and create false ideas about the strength and equipment of the opposing forces and objects.

The use of camouflage staining, coatings and camouflage nets allows you to create a relatively effective system of masking and misleading the enemy. The measures taken noticeably reduce the likelihood of the enemy disabling human resources, important systems and objects.

These measures increase the survivability of individual military assets, which, as a result, provides an increase in the combat effectiveness of the armed forces, makes it possible to repel a surprise attack with fewer forces at a lower cost for defense engineering equipment and the creation of surveillance and warning systems (that is, equivalent to having more forces or more costs of defense engineering equipment and surveillance and warning means without the use of effective camouflage measures). So, for example, the survival in battle of a well-camouflaged tank is increased by 50%.

Scientific and technical programs in the field of creating modern means of reducing the visibility of developed countries are mainly aimed at developing technical means for comprehensively counteracting large-scale threats to the use of modern weapons systems (including high-energy) equipped with homing heads (GOS) as with equipment operating in various fields electromagnetic spectrum (including ultraviolet (UV), visible, infrared (IR) and radio frequency ranges), and with multispectral multimode bubbled sensors.

Until recently, camouflage products used to mask objects from surveillance equipment, adopted in developed countries and having a common goal of reducing the visibility of the surface of the protected object, are mainly intended to ensure their stealth in a narrow range of the electromagnetic spectrum, which makes the object vulnerable when using passive and active detection systems operating in different or multispectral ranges of the electromagnetic spectrum.

This is due to the fact that the effect of modern camouflage products for masking objects from observation means is based, as a rule, on the absorption of most of the power of the locating radiation. The residual power is reflected from the object in the form of a diffuse scattered signal, the characteristics of which are related both to the absorption coefficient and texture of the reflecting surface, and to the shape of the object. The disadvantages of these means of protection and masking are relatively low absorption coefficients, and their optimal efficiency occurs only for certain wavelengths. At the same time, the receiving equipment of the detection, recognition and guidance systems is focused on the reception and recognition of the diffuse-scattered signal reflected from the object, which has a spatio-temporal structure specified by the locating equipment.

The level of diffuse scattering of the signal reflected from the object depends on the roughness of the reflecting surface and the shape of the object. The energy level of the reflected signal depends on the absorption coefficients and on the number of reflections, which is possible with a given roughness. As a rule, when developing camouflage products for masking objects from observation devices, they tend to increase the absorption coefficient and provide a level of roughness that ensures uniform distribution of the reflected signal in space and does not create glare. In this situation, as a rule, the reflected beam is reflected from the surface once and its partial absorption occurs once. Moreover, depending on the materials used, they have the highest absorption coefficient for any one wavelength of incident radiation or for a very narrow wavelength range.

Practice shows that the continuous improvement of the receiving equipment does not allow the development of absorbing coatings that would provide effective defense of military equipment against modern multimedia detection, reconnaissance and guidance systems.

In addition, the vast majority of camouflage materials currently in service in a number of countries, although they have a common goal of camouflage the surface of objects and structures from observation, use the principle of protecting a masked object, based, as a rule, on weakening (obscuring) the contrast, including temperature and brightness of the masked object compared to the surrounding background, which does not ensure the secrecy of the object with a sufficiently high sensitivity of the homing heads (GOS) of modern multi-purpose war weapons, and only a small number of camouflage products to mask objects from surveillance tools use the principle of protecting a masked object, based on changing the characteristics of the incident (locating) radiation from the GOS of modern multi-purpose weapons.

However, the changes in the characteristics of the incident (locating) radiation provided by the well-known camouflage products for masking objects from observation means are ineffective due to the fact that the wavelength range of the locating radiation of the GOS of modern multi-purpose weapons is quite wide.

Therefore, the problem of manufacturing cheap camouflage products for camouflaging objects from surveillance equipment, based on changes in the characteristics of incident (locating) radiation from GOS of modern multipurpose weapons in a wide wavelength range of locating radiation, has now become quite acute.

A camouflage net is known that has a dense mesh structure on a poly-cotton basis with cross-weaving of more durable material - strips of nylon treated with polyurethane and with nylon-weaving having the colors of the terrain in which the fighting is carried out: green, black or brown for a temperate climate or jungle, white - for the Arctic or tan - for the desert, while the stripes are placed with the possibility of imparting similarities to the foliage of natural vegetation.

This camouflage network provides stealth in the visible and indistinguishable when photographing in the near infrared range against a background of living vegetation [1].

The disadvantages of the known camouflage network are as follows.

1. The well-known camouflage network does not allow masking in the near radio frequency range.

2. Low overall masking efficiency due to the high probability of detection and recognition of the masked object and, accordingly, the likelihood of its destruction.

3. The low efficiency of masking objects having a higher temperature compared to the environment, such as tools, motors, generators, etc.

The closest technical solution (prototype) is camouflage material for camouflaging military objects from surveillance in the near and far infrared, millimeter and centimeter radio wavelengths, containing electrically conductive from at least one side with a low surface resistance of 2 to 50 Ohms a supporting network base of interwoven threads located in the transverse and longitudinal directions, placed at free intervals relative to each other, in a binder, while on the follower threads The electrically conductive layer and the outer layer with the emission coefficient varying on its surface, masked color-bearing layers made of a binder with pigment additives transparent in the IR wavelength range, and a coating placed on one of the color layers are placed with irregular hemispherical and (or) conical indentations distributed over its surface and (or) protrusions of a hemispherical and (or) conical shape or in the form of ribs, with height and diameter Three recesses and (or) protrusions vary over the coating surface from 5 to 25 mm, and the electrically conductive part of the carrier network base in the free spaces between the threads is made of a binder with pigment additives from an electrically conductive material, for example, from a binder based on phenolic resin with pigment additives from graphite, black carbon or aluminum particles in an amount of 10-50% in a binder.

At least some of the threads can be made of metal, for example in the form of aluminum coated polymer narrow narrow ribbons with a width of 0.2-0.5 mm and a thickness of 6-20 microns, and the free gaps between the threads are one third or more of the thickness of the thread.

The outer layer with an emission coefficient varying over its surface is made of a synthetic open-cell foam coating of, for example, polyurethane polyolefin, polyvinyl chloride, polyester, polyacrylate, polystyrene, polyester, polyester with 5-50% pigment additives made of metal, such as copper particles, zinc steel or aluminum.

The binder of the colored layers can be made, for example, from the cyclized rubber, polyethylene or polypropylene with pigment additives, for example, ocher, lime, cobalt blue or chromium, iron or titanium oxides [2].

The disadvantages of the known camouflage network are as follows.

1. The known camouflage network does not allow masking in the visible wavelength range.

2. Low overall masking efficiency due to the high probability of detection and recognition of the masked object and, accordingly, the likelihood of its destruction.

3. High structural complexity and, as a result, increased weight and dimensions in height, lack of flexibility and mobility.

A new achievable technical result of the present invention is to increase the effectiveness of camouflage through the use of masking materials using the principle of protection of a masked object, based on a change in the characteristics of the incident (locating) radiation.

A new technical result is achieved in that in a camouflage network containing a carrier network of threads arranged in transverse and longitudinal directions, placed at free intervals relative to each other, electrically conductive polymer tapes with a metal coating on at least one side, a layer repeating on both sides the shape of the recesses and (or) protrusions distributed on its surface, the camouflage color-bearing layer, unlike the prototype, the threads of the carrier network base are placed with the formation of cells eek, polymer tapes are made in the form of a layer repeating on both sides the shape of the recesses and (or) protrusions distributed on its surface, the metal coating is reflective and applied to the surface of the polymer tapes from at least one side, a color-masking mask is applied to the corresponding a reflective coating, and the recesses and protrusions are made in the form of structures with a pointed or / and rounded top, providing reflection on their side surfaces of the locating radiation in at least one m direction other than the source of the locating radiation, while the polymer tape is placed in the transverse direction or in the longitudinal direction in the corresponding successively arranged cells with the possibility of their retention by the respective sides of the cells.

Polymer tapes can be made reinforced.

Polymer tapes can be made of a material that is transparent in the infrared wavelength range.

In the case of applying a camouflage color-bearing layer to the reflective coating on one corresponding side of the polymer tapes and performing structures with a pointed or / and rounded top in the form of recesses, a base mounted on the back of the corresponding peaks of pointed or / and rounded structures can be added to the camouflage network appropriate polymer tapes.

In the case of applying a camouflage color-bearing layer to the reflective coating on one corresponding side of the polymer tapes and performing designs with a pointed or / and rounded apex in the form of protrusions, a base mounted on the back side of the surface of the corresponding polymer tapes can be added to the camouflage network.

Structures with a pointed or rounded apex can be of the same type, with at least one side surface or part of at least part of the structures located at an angle to the base, different from the angle of inclination to the base of the rest of the side surface or the rest side surfaces.

The sizes of the heights and bases of structures with a pointed or rounded top can be made different on the surface of the respective polymer tapes.

Structures with a pointed or / and rounded apex can be distributed irregularly over the surface.

In the case of constructions with a pointed peak, at least part of the structures with a pointed peak can be made in the form of polyhedral pyramids or a conical shape.

In the case of constructions with a pointed peak in the form of polyhedral pyramids, at least one part of the pyramids can be made with the number of faces different from the number of faces of the remaining pyramids.

In the case of structures with a pointed peak in the form of polyhedral pyramids, at least part of the structures with a pointed peak can be made in the form of trihedral pyramids.

Designs with a rounded apex can be made in the form of a part of spheroids, and (or) ovals, and (or) ellipsoids, and (or) elliptical paraboloids, and (or) hyperboloids.

Designs in the form of protrusions can be made in the form of ribs.

In the case of the execution of polymer tapes with recesses and protrusions, polymer tapes can be made wavy.

A reflective coating can be made with a surface resistance of 2 to 50 ohms.

The reflective coating may be in the form of a metal highly reflective layer or a layer of particles with a highly reflective surface.

A reflective coating can be made with a reflection coefficient varying on the surface of the respective polymer tapes.

In the case of applying a reflective coating to the surface of the polymer tapes on one corresponding side, the polymer tapes can be made in the form of an additional camouflage color-bearing layer with a camouflage color different from the camouflage color of the camouflage color-bearing layer on the reflective coating.

In the case of applying camouflage color-bearing layers to reflective coatings on both sides of the polymer tapes, camouflage color-bearing layers can be made with different camouflage colors.

The camouflage color-bearing layer can be made of a polymer binder with pigment additives.

An additional camouflage color-bearing layer can be made of a polymer binder with pigment additives.

Pigment additives of the polymer binder of the camouflage color-bearing layer can be made of ocher, lime, carbon black, barium sulfide, cobalt blue or oxides of chromium, iron or titanium.

Pigment additives of a polymer binder of an additional masking color-bearing layer can be made of ocher, lime, carbon black, barium sulfide, cobalt blue or chromium, iron or titanium oxides.

The polymer binder of the camouflage color-bearing layer can be made transparent in the infrared wavelength range.

The polymer binder of the additional masking color-bearing layer can be made transparent in the infrared wavelength range.

The masking color-bearing layer can be additionally activated by a luminescent compound made in the form of a phosphor converting the absorbed radiation into radiation of another spectral region with a longer electromagnetic wavelength, or as an anti-Stokes phosphor converting the absorbed radiation into radiation of another spectral region with a smaller electromagnetic wavelength .

An additional masking color-bearing layer can be additionally activated by a luminescent compound made in the form of a phosphor that converts the absorbed radiation into radiation of another spectral region with a longer wavelength of electromagnetic radiation, or in the form of an anti-Stokes phosphor that converts the absorbed radiation into radiation of another spectral region with a smaller electromagnetic wavelength radiation.

Structures imitating resemblance to natural vegetation and placed on the corresponding working surface of polymer films with the possibility of imparting similarity of the surface of polymer films to natural vegetation can be added to the camouflage network.

Figure 1-11 presents the basic options for the implementation of the camouflage network.

The camouflage network contains a carrier network base 1 of the threads located in the transverse 2 and longitudinal 3 directions arranged with the formation of cells 4, placed in the transverse direction in the corresponding successive cells 4 with the possibility of their retention by the respective sides of the 5 cells 4 polymer tape 6, electrically conductive on one side in the form of a layer repeating the shape of the protrusions distributed over its surface in the form of ribs 7, successively deposited on the surface 8 of the polymer tapes 6, a reflective coating 9 in in the form of a metal highly reflective layer and a camouflage color-bearing layer 10 (Fig. 1).

The camouflage network contains a carrier network base 1 of the threads located in the transverse 2 and longitudinal 3 directions arranged with the formation of cells 4, placed in the longitudinal direction in the respective successive cells 4 with the possibility of their retention by the respective sides of the 5 cells 4 polymer tape 11, electrically conductive on both sides 11 in the form of a wavy layer with wavy protrusions 12 and recesses 13 distributed over its surface, successively applied to the corresponding floor surfaces 8, 14 measuring tape 11 reflective coatings 15 in the form of a layer of particles with a highly reflective surface and camouflage color-bearing layers 10, 16 with different camouflage colors, and the camouflage color-bearing layers 10, 16 can be activated by a luminescent compound made in the form of a phosphor 17 that converts the absorbed radiation in the radiation of another region of the spectrum with a longer wavelength of electromagnetic radiation (figure 2).

The camouflage network contains a supporting network base 1 of the threads located in the transverse 2 and longitudinal 3 directions arranged with the formation of cells 4, placed in the corresponding sequentially arranged cells 4 with the possibility of their retention by the respective sides of the 5 cells 4 polymer reinforced tapes 18 with successively applied to their surface 8 with a reflective coating 9, 15 and a camouflage color-bearing layer 10, while the reinforced polymer tapes 18 are made in the form of a layer repeating the shape of the distribution on both sides of recesses 13 along its surface in the form of one type of structures with pointed 19 and rounded 20 peaks, providing reflection on their side surfaces of the emitting radiation in at least one direction different from the source of the emitting radiation, and the masking color-bearing layer 10 may additionally be activated by a luminescent compound made in the form of anti-Stokes phosphor 21, which converts the absorbed radiation into radiation of another spectral region with a smaller wavelength of electromagnet total radiation (figure 3).

The camouflage network contains a carrier network base 1 of the threads located in the transverse 2 and longitudinal 3 directions, arranged with the formation of cells 4, placed in the corresponding sequentially arranged cells 4 with the possibility of their retention by the respective sides of the 5 cells 4 polymer tapes 6, 11, 18 with successively applied on the surface 8 of the polymer tapes 6, 11, 18 with a reflective coating 9, 15 and a camouflage color-bearing layer 10, while the polymer tapes 6, 11, 18 are made in the form of a layer repeating the shape of the distributor on both sides recesses 13 formed on its surface in the form of structures with a pointed 22 and 23 rounded peaks, the sizes of the heights and bases of which can be made different on the surface of the corresponding polymer tapes 6, 11, 18 and distributed irregularly on the surface 8 (Fig. 4).

The camouflage network contains a supporting network base 1 of the threads located in the transverse 2 and longitudinal 3 directions, arranged with the formation of cells 4, placed in the corresponding sequentially arranged cells 4 with the possibility of their retention by the respective sides of 5 cells 4 of polymer tapes 6, 11, 18 with successively applied on the surface 8, polymer tapes 6, 11, 18 with a reflective coating 9, 15 and a camouflage color-bearing layer 10, while the polymer tapes 6, 11, 18 are made in the form of a layer repeating the shape of the distributor on both sides cones 24 along its surface, one part 25 of the side surface of which is located at an angle to the base, different from the angle of inclination to the base of the rest of the side surface or other side surfaces (Fig. 5).

The camouflage network contains a carrier network base 1 of the threads located in the transverse 2 and longitudinal 3 directions, arranged with the formation of cells 4, placed in the corresponding sequentially arranged cells 4 with the possibility of their retention by the respective sides of the 5 cells 4 polymer tapes 6, 11, 18 with successively applied on the surface 8 of polymer tapes 6, 11, 18 with a reflective coating 9.15 and a camouflage color-bearing layer 10, while the polymer tapes 6, 11, 18 are made in the form of a layer repeating the shape of the distributor on both sides GOVERNMENTAL on its surface polyhedral pyramid, one of which can be performed with the number of faces 26, other than the number of faces other pyramid 27 (Figure 6).

The camouflage network contains a carrier network base 1 of the threads located in the transverse 2 and longitudinal 3 directions arranged with the formation of cells 4, placed in the corresponding sequentially arranged cells 4 with the possibility of their retention by the respective sides of 5 cells 4 polymer tapes 6, 11, 18 with successively applied on the surface 8 of the polymer tapes 6,11,18 with a reflective coating 9, 15 and a camouflage color-bearing layer 10, while the polymer tapes 6, 11, 18 are made in the form of a layer repeating the shape on both sides surface on its surface of trihedral pyramids 28 (Fig.7).

The camouflage network contains a carrier network base 1 of the threads located in the transverse 2 and longitudinal 3 directions, arranged with the formation of cells 4, placed in the corresponding sequentially arranged cells 4 with the possibility of their retention by the respective sides of the 5 cells 4 polymer tapes 6, 11, 18 with successively applied on the surface 8 of the polymer tapes 6, 11, 18 with a reflective coating 9, 15 and a masking color-bearing layer 10, while the polymer tapes 6, 11, 18 are made in the form of a layer repeating the shape of the distributor on both sides parts of spheroids (and (or) ovals, and (or) ellipsoids, and (or) elliptical paraboloids, and (or) hyperboloids) 29 (Fig. 8).

In the case of applying a masking color-bearing layer 10 on a reflective coating 9, 15 on one corresponding side of the polymer tapes 6, 11, 18 and performing structures with a pointed 22 or / and rounded 23 peak in the form of recesses 13, on the back side 30 of the corresponding peaks of pointed 22 or / and rounded 23 structures of the respective polymer tapes 6, 11, 18 can be strengthened base 31 (Fig.9).

In the case of applying a masking color-bearing layer 10 on a reflective coating 9, 15 on one corresponding side of the polymer ribbons 6, 11, 18, made in the form of a layer repeating the shape of the trihedral pyramids 28 distributed on its surface, on the back side 30 of the surface of the corresponding polymer ribbons 6, 11, 18 can be strengthened base 31 (figure 10).

In the case of applying a reflective coating 9 to the surface of the polymer tapes 6, 11, 18 on one corresponding side, the polymer tapes can be made in the form of an additional masking color-bearing layer 32 with a masking color different from the masking color of the masking color-bearing layer 10 on the reflecting coating 9, this additional masking color-bearing layer 32 can be activated by a luminescent compound made in the form of a phosphor 17, which converts the absorbed radiation into radiation of another region ktra with a longer wavelength of electromagnetic radiation, or in the form of an anti-Stokes phosphor 21, which converts the absorbed radiation into radiation of another spectral region with a smaller wavelength of electromagnetic radiation, and structures 33 imitating resemblance to can be placed on the working surface of polymer films 6, 11, 18 natural vegetation, with the possibility of imparting the similarity of the surface of the polymer films 6, 11, 18 with natural vegetation (Fig.11).

The masking network is made as follows.

The type of polymer material for polymer tapes 6, 11, 18 of the proposed masking network is selected depending on the tactical and technical tasks to protect the facility and operational requirements (for material thickness, weight, frost resistance, fire safety, wear resistance, etc.). Polymeric material for polymer tapes 6, 11, 18 of the proposed masking network, in which structural elements with pointed 22 and (or) rounded peaks 23 (in the form of pyramids, cones, ribs, parts of spheroids, and (or) ovals, and (or ) ellipsoids, and (or) elliptical paraboloids, and (or) hyperboloids, etc.) can be transparent in several working wavelength ranges of the electromagnetic spectrum of the proposed camouflage network or only in a certain, for example, infrared range. The transparency of the material of the polymer tapes 6, 11, 18 and the camouflage color-bearing layer 10, 16 in the infrared range ensures the interaction of the locating radiation directly with the reflective coating 9, 15.

As the material of polymer tapes 6, 11, 18, transparent in the infrared range of the electromagnetic radiation spectrum, for example, polyethylene, polyethylene-vinyl acetate copolymer, chlorine-substituted polypropylene and the like can be used. Polyethylene terephthalate, lavsan, polyvinyl chloride, mylar, polystyrene, polycarbonate or polymethyl methacrylate, etc. are also used as material for polymer tapes 6, 11, 18. These possible materials can be reinforced to obtain reinforced polymer tapes 18.

The advantage of performing polymer tapes 6, 11, 18 from those passed in the transverse direction or longitudinal direction through the corresponding sequentially located cells 4 of the carrier network base 1 of polymer tapes 6, 11, 18 is to reduce the consumption of material of polymer tapes 6, 11, 18 per unit surface area of the proposed camouflage net and reducing its size in height. As a result, increased flexibility, mobility and the ability to easily deploy and collapse the camouflage network, as well as the possibility of more efficient ventilation, which significantly increases the efficiency of its masking in the infrared range, are achieved.

In addition, the use of the proposed camouflage network provides masking of objects having a high temperature, due to the fact that infrared radiation, as well as radiation in the visible range, undergoes the following changes.

So, the use in the proposed camouflage network of a polymeric material in which structural elements with pointed 22 and (or) rounded peaks 23 (in the form of pyramids, cones, ribs, parts of spheroids, ellipsoids, etc.) are performed, allows to reduce the “transparency” of the camouflage network in the infrared range, as well as when laser ranging in the visible and infrared ranges of wavelengths, thereby reducing the likelihood of detecting equipment that has a higher temperature than the environment, while maintaining their masking properties in the daytime e time of day.

Data analysis shows that visual observation systems operate in the range of 0.4-0.7 microns. In this case, the detection mechanism is based on color contrast and brightness.

Passive systems operate in the infrared range of 0.8-0.14 microns of the electromagnetic spectrum, including the spectrum of solar radiation, low temperature and high temperature spectra. Homing systems like forward-looking infrared systems on airplanes, helicopters, GOS missiles such as air-to-ground, ground-to-air, etc. carried out on the existing temperature contrast between the object and its background.

Active systems of multipurpose weapons, as a rule, are based on the detection of returned incident radiation from the surface for detection, recognition, target designation and capture for automatic tracking. These systems are tuned and operate in both optical and infrared ranges from 0.4 to 10.6 microns.

Thus, to counteract these systems, it is necessary to transform radiation in the ranges from 0.4 to 10.6 μm.

The range of wavelengths that can be transformed with these films depends on the geometric dimensions of each unit cell (the cell size must be more than a quarter of the maximum wavelength of the locating radiation). The incident (locating) radiation undergoes the above changes if ¼λ of the incident radiation is smaller than the size of the base of structures with pointed 22 and (or) rounded peaks 23 (in the form of pyramids, cones, ribs, part of spheroids, ellipsoids, etc.). Otherwise, the surface of the material of the masking network appears to be smooth and even for the incident wave and transformation of the incident radiation does not occur.

The choice of the size of structures with pointed 22 and (or) rounded peaks 23 (in the form of pyramids, cones, ribs, parts of spheroids, and (or) ovals, and (or) ellipsoids, and (or) elliptic paraboloids, and (or) hyperboloids and etc.) is dictated not only by the wavelength of the incident (locating) radiation, but also by the technological complexity of their execution, as well as the minimum film thickness required for its sustainable long-term use on a particular masked object. Thus, the dimensions of the height and base of structures with pointed 22 and (or) rounded peaks 23 are also due to the fact that, with dimensions less than 2.0 μm, the geometric difficulties in the technology for producing cavities with such dimensions significantly increase due to the extremely small sizes of the resulting cavities. In addition, the proximity of such cavities with the wavelength of incident optical and other radiation reduces the quality of its effective re-reflection in different directions in accordance with the inclination of the side surfaces to the base of structures with pointed 22 and (or) rounded peaks 23. Dimensions of the height and base of structures with pointed 22 and (or) rounded peaks 23 to a greater extent due to the required operating range of the proposed camouflage network in the infrared (0.8-14 μm) to ensure its effective re the friction and locating radiation of the radio wavelength of the electromagnetic spectrum (from several mm to 10 m) in different directions in accordance with the inclination of the side surfaces to the base of the structures with pointed 22 and (or) rounded peaks 23 while ensuring compactness, lightness and high mobility of the masking network both when it is placed on a masked object, and in a folded state during storage and transportation. At the same time, the height of structures with pointed 22 and (or) rounded peaks 23 can reach several centimeters, based on the fact that, the larger the dimensions of the height and base of structures with pointed 22 and (or) rounded peaks 23, the larger the radiation range for longer radios waves of the electromagnetic spectrum can be provided with effective masking using the proposed camouflage network.

The coefficient of the diffuse component and the presence of interference depend on the quality of the embossing (flatness of the faces of the pyramids and the "radius" of the angles and vertices) and on the size of the free spaces between the structures with pointed 22 and (or) rounded peaks 23 (in the form of pyramids, cones, ribs, part of spheroids , ellipsoids, etc.).

The wavelength spectrum of the returned electromagnetic radiation depends on the presence in the material of polymer tapes 6, 11, 18 or in the camouflage color-bearing layer 10, 16 of phosphors 17, 22 that change the wavelength of the incident radiation. So, the use of phosphor additives 17, 21 provides not only the transformation of the incident (location) radiation on the masked object of a certain range of a certain region of the spectrum of electromagnetic radiation from, for example, GOS of modern weapon systems, but also a change in its wavelength, including converting it into radiation another range of the same or another region of the spectrum of electromagnetic radiation.

So, the radiation, for example from a GOS missile, in the UV region of the spectrum of electromagnetic radiation when exposed to the proposed masking system is converted (transformed) into the optical or infrared region of the spectrum of electromagnetic radiation or radiation in the optical region of the spectrum is converted to the infrared region of the electromagnetic spectrum when using phosphor 17, converting the absorbed radiation into radiation of another spectral region with a longer wavelength of electromagnetic radiation (figure 2, 11). In this case, the invisible incident radiation can become visible and vice versa.

As such luminescent compounds used as luminescent fillers in the material of polymer tapes 6, 11, 18 or in a camouflage color-bearing layer 10, 16, for example, a phosphor 17 containing yttrium oxide activated by antimony and manganese can be used (26-34% mass.), and providing the transformation of invisible radiation in the UV region of the spectrum with a wavelength of 200-460 nm in the region of the red component (500-700 nm) of the spectrum of electromagnetic radiation (composition No. 1).

A phosphor can be used in the form of a complex compound of europium tenoyl trifluoroacetonate with 1,10-phenanthroline, which converts radiation in the UV region of the spectrum with a wavelength of 250-380 nm into the visible and IR regions of the spectrum of electromagnetic radiation with a wavelength of 560-760 nm.

A phosphor 17 corresponding to the chemical formula can also be used: K ₂ Y _1-xy Nd _x Yb _y F ₅ , where 0.001 <x <0.150; 0.02 <y <0.20, which converts the radiation of the UV and visible spectral regions with a wavelength of 300-570 nm into the infrared radiation of the spectrum with a wavelength of 860-1040 nm (composition No. 2). Luminescence spectra and luminescence excitation spectra were obtained upon excitation by a halogen lamp using monochromators with registration by means of a photomultiplier with a light filter. The received information was recorded and processed on a microcomputer.

The transparent surface-smooth polymer films of the carrier network base 1 themselves have a reflected mirror beam, which can lead to masking of the masked object in the daytime due to “glare”. To create camouflage color effects, the polymeric material can also be painted by, for example, applying a masking layer 10, 16 to the desired masking colors.

To obtain polymeric tapes 6, 11, 18 in the material or in the color-masking mask 10, 16 of a pigmented phosphor 17 transforming the incident radiation of one range of the electromagnetic spectrum into another, pigment additives based on ocher, lime, cobalt blue or chromium oxides are used, iron or titanium, etc., for example, red pigment of iron oxide, yellow - iron oxide, black - soot, and brown - barium sulfide, both individually and in various proportions depending on the background area, in which A swarm of camouflage net is applied. So, for the preparation of a pigmented phosphor 17, for example, a red glow on the basis of rare-earth elements, for example, the following process is carried out: a phosphor based on rare-earth elements in an amount of, for example, 10 kg is pulped in 20 l of water for 5-10 minutes. Then, 10 g of aluminum nitrate dissolved in 2 L of water and 370 ml of a 13.5% suspension of iron oxide (Fe ₂ O ₃ ) in a 2 × 10 M sodium pyrophosphate solution are added to the resulting suspension. After stirring for 5 minutes, 20 g of ammonium fluoride are added to the resulting mixture. The mixture was stirred for 15 minutes and then filtered on a suction filter. The pigmented phosphor precipitate separated in this case is washed with 1.5 L of water and then dried at 100-110 ° C. In this case, a suspension of pigmented (red, yellow, etc. glow colors) phosphor 17 is formed.

In addition to the transformation of absorbed radiation, for example from a GOS missile, of one range of the spectrum of the electromagnetic radiation spectrum into radiation of another range with a longer wavelength of the same or a different spectral region, a luminescent compound is used to mislead the enemy, which converts the incident radiation of one range of the spectrum region of electromagnetic radiation into radiation of a different range, including another region of the spectrum, but with a shorter wavelength of the electromagnetic spectrum. As such a phosphor, so-called anti-Stokes phosphors 21 are used.

As such anti-Stokes phosphors 21, for example, a luminescent composition based on lead fluoride, germanium oxides and a solid solution of oxides of activating elements - ytterbium and thulium is used, which converts the incident radiation of the infrared region of the spectrum of electromagnetic radiation into the visible (475 nm) region of the spectrum, for example, the following ratio of components,% mass .: PbF ₂ (68,2802); GeO ₂ (17.5530); Y ₂ O ₃ (14.1317); Tm ₂ O ₃ (0.035).

As an anti-Stokes phosphor 21, for example, a luminescent composition based on zinc fluorides of a metal of the zinc group with the general formula: (Zn _1-x Cd _x ) F ₂ , where x <0.2, is activated by erbium or erbium and ytterbium, which converts the radiation of the infrared region of the spectrum in the wavelength range of 1200-1600 nm of electromagnetic radiation into the radiation of the visible region of the spectrum in the wavelength range from saturated red to yellow, depending on the fluoride of the corresponding metal of the zinc group (composition No. 3).

Luminescent compounds in the form of phosphors 17 and anti-Stokes phosphors 21, including in the form of pigmented phosphors, are introduced into polymer material 6, 11, 18 or in a color-masking layer 10, 16 by one of the known methods (for example, at the granulation or melt stages) in the form of luminescent fillers.

The use of luminescent compounds in the form of phosphors 17, converting the incident, for example from GOS missiles, radiation into radiation of a different range, including another region of the spectrum of electromagnetic radiation, with a longer wavelength, or in the form of anti-Stokes phosphors 21, converting the incident radiation into radiation of a different range , including another part of the spectrum of electromagnetic radiation, but with a shorter wavelength, allows you to mislead the enemy at all stages of observation, detection, recognition and capture of targets automatic tracking due to the fact that the monitoring and tracking equipment of modern weapons and radar, operating in only one region of the spectrum of electromagnetic radiation or in strictly defined rather narrow operating ranges, does not perceive electromagnetic radiation returning from an object masked by the proposed masking network, after sending a signal from such equipment, but converted to a different range (another region) of the spectrum) of electromagnetic radiation. Thus, the “invisibility” of the masked object is provided for reconnaissance and surveillance equipment, GOS systems of modern weapons, radar, etc.

It should be noted that even if the luminescent fillers 17, 21 used are not pigmented and the masking color or its pigmentation is associated with certain technological difficulties for the particular phosphor 17, 21 used, then the material of the polymer tapes 6, 11, 18 or the masking color-bearing layer 10 , 16 may contain a pigment of a masking color, for example, of the same ocher, lime, cobalt blue or chromium, iron or titanium oxides, etc., selected according to the background in which the application of agaemogo masking material. For example, a mixture of yellow iron oxide pigment Zh-1, chromium oxide (green), carbon black, or a mixture thereof with a pigment concentration of 0.4-20.5% by volume, can be used as a masking pigment. Moreover, the lower limit of 0.4% vol., Is the minimum share of masking pigment, in which its masking properties are manifested in a transparent polymer layer. A concentration of 20.5% vol. - the maximum proportion of masking pigment, which still retains sufficient transparency of the masking color-bearing layer 10, 16 for the effective operation of reflective structures with pointed 22 and (or) rounded peaks 23.

Masking pigment is introduced into the material of the polymer tapes 6, 11, 18 or into the binder of the masking color-bearing layer 10, 16 as a filler using one of the known methods, as mentioned above, together or sequentially with the introduction of a luminescent filler. As a transparent binder in the camouflage color-bearing layer 10, 16, for example, AK-545 varnish (STP 6-10-500-31-87), Metafont glue can be used.

Multicolor camouflage design is also possible. This will change the absorbing characteristics of masking materials by an order of magnitude and will allow providing the required spectral characteristics to the protected object. So, to reduce the gloss of the smooth face of the material of polymer tapes 6, 11, 18 while maintaining its basic characteristics on the working side, for example by spraying, a solid or non-continuous thin layer (undercoat) of absorbing paints and enamels of a standard color gamut of a protective color can be applied, for example , brands ХВ-518, ХВ-519.

A reflective coating 9, 15 with a reflectance of at least 80% is applied to one of the sides of the carrier network base 1, including the front faces (on the working side of the polymer tapes 6, 11, 18) and (or) the back surfaces 30 of the formed structures with pointed 22 and rounded 23 peaks, one of the known methods, for example by thermal evaporation in a vacuum installation, deposition in a plating bath, etc., the corresponding metal with highly reflective properties, such as steel, aluminum, copper, silver, molybdenum, their alloys andetc., or by spraying onto a working surface particles with highly reflective properties dispersed in a binder. As such particles can be used materials made of both metals and non-metals or non-metals with a metal reflective coating. It can be aluminum, bronze, silver, brass, etc. powder, particles of mica, particles of a polymer, for example, lavsan film, with a reflective layer such as “eye gloss” applied on them, titanium oxide, etc. with a particle size of 0.2-0.3 microns. As a binder, for example, Metafont varnish manufactured by the LIT enterprise in Pereyaslavl-Zalessky or another suitable binder of the type of optical glue can be used.

The reflective coating 9, 15 on the sides of the polymer tapes 6, 11, 18 of the proposed masking network can also be performed, for example, by spraying aluminum with a protective color ХВ-518, which ensures the creation of an absorbing color-bearing coating.

Masking color-bearing layer 10, 16 can be applied directly to the material of polymer tapes 6, 11, 18 from its working side (in the case of applying a reflective coating 15 only to the back surface of the material of polymer tapes 6, 11, 18, including the back surfaces 30 formed designs with pointed 22 and rounded 23 peaks). This embodiment of the camouflage network is possible if the material of the polymer tapes 6, 11, 18 is made of a transparent polymer material in the electromagnetic wavelength ranges in which camouflage is provided using the proposed camouflage network.

The masking color-bearing layer 10, 16 can be applied to the reflective coating 9, 15 from the working side of the material of polymer tapes 6, 11, 18 (in the case of applying the reflective coating 9 only to the front surface of the material of polymer tapes 6, 11, 18, including the front ones surfaces of formed structures with pointed 22 and rounded 23 peaks, or in the case of applying reflective coatings 9, 15 to both the front and back surfaces of the material of polymer tapes 6, 11, 18, including the front and back surfaces of 30 formed structures with sharp 22 and rounded end vertices 23). This embodiment of the camouflage network is possible if the material of the polymer tapes 6, 11, 18 is made of an opaque polymeric material in the electromagnetic wavelength ranges in which camouflage is provided using the proposed camouflage network, or if the camouflage network is double-sided.

In the case of performing a camouflage network, a double-sided camouflage color-bearing layer 10, 16 can be applied to the reflective coating 9, 15 on both sides of the material of the polymer tapes 6, 11, 18, and both sides of the proposed camouflage network in this case can be working (Fig. 2).

The introduction of masking pigments into the material of polymer tapes 6, 11, 18 or the use of a masking color-bearing layer 10, 16 allows, while maintaining their sufficient transparency and, therefore, operability of the reflecting surface 9, 15, to increase the inconspicuousness of the masked object in the optical range of the spectrum of the electromagnetic radiation against the surrounding background when observing with the naked eye or using reconnaissance and surveillance means in this range, such as binoculars, rangefinders, etc.

In addition, the invisibility of a masked object having a higher temperature compared to the environment, such as tools, motors, generators, etc., is increased by reducing the temperature contrast from such an object in comparison with the ambient temperature through reflection coming from the masked object thermal radiation, a reflective coating 9, 15 in the opposite direction during the masking of infrared radiation (thermal range) emitted from the masked object, its subsequent scattering, for example, through surface of the earth. It should also be noted that increased thermal radiation from such masked objects of the infrared spectrum of electromagnetic radiation is converted by a luminescent compound present in the masking material into radiation of a different range of another spectral region, for example, visible, which, in turn, also reduces the thermal contrast of the masked object by ambient background.

The carrier network base is made with many recesses 13 and (or) depressions 12 in the form of peaked structures with peaked 22 and rounded 23 peaks (Fig.1-11). Such cavities in the form of pointed structures with a pointed 22 and rounded 23 peaks can be made by, for example, stamping. In the polymer tape 6, 11, 18, for example, from polyethylene terephthalate, cavities are formed using, for example, a stamp with a pattern on the working surface in the form, for example, of pointed structures with pointed 22 and rounded 23 vertices. Moreover, some structures with pointed 22 and rounded 23 peaks on the working surface of the stamp can be made with an angle of, for example, one face of the pyramids 26 different from the angle of the other faces of the remaining 27, and these pyramids 26, 27 are placed in the form of mirror images of real pyramids 26, 27 on a polymer tape 6, 11, 18. Some of the pyramids on the working surface of the stamp can be made with an even number of faces, and the other part of the pyramids with an odd number of faces.

As pointed structures with pointed 22 and rounded 23 peaks, polyhedral pyramids (three-, four-, five-, hexagonal, etc.) can be used (Figs. 4-8), cones (Fig. 3), ribs ( 1), recesses 13 and troughs 12 in the form of waves (FIG. 2), as well as parts of spheroids, and (or) ovals, and (or) ellipsoids, and (or) elliptical paraboloids, and (or) hyperboloids, and t .P. Moreover, the pyramids can be used both in the form of straight pyramids, at the base of which are regular triangles, tetrahedra, squares, pentagons, etc., and with faces located at different angles to the base (Figs. 4-8).

The supporting network structure 1, for example, of strong polymer threads provides increased rigidity, stability and strength of the interwoven polymer tapes 6, 11, 18 of the proposed masking network located in the transverse and longitudinal directions (Fig. 1).

The execution of polymer tapes 6, 11, 18 with an additional base 31, mounted on the back side 30 of the corresponding peaks of pointed 22 or / and rounded 23 structures, for example in the form of a layer repeating the shape of the trihedral pyramids 28 distributed over its surface, corresponding polymer ribbons 6, 11 , 18, provides increased rigidity, stability and strength of the polymer tapes 6, 11, 18 of the proposed masking network. At the same time, the air spaces formed by the additional base 31 with polymer tapes 6, 11, 18 in places of contact with voids formed by pointed structures with a pointed 22 and rounded 23 peaks, increase the efficiency of the masking properties of the proposed masking network in the infrared range by reducing it thermal conductivity as a result of the presence in the proposed masking network of air voids (Fig.9, 10).

The masking network operates as follows.

A masked object is covered, for example, the hull of an aircraft or a tank, provided by a camouflage net and strengthened.

As you know, one of the means of dealing with systems based on laser ranging is an adaptive change in the scattering indicatrix of the signal reflected from the object as a whole or from its local elements, which has an intermittent character in space (scattering indicatrix of the “hedgehog” type) and consisting of separate rays with between them are "dead zones", i.e. areas where the signal level is either comparable to or lower than background values. Moreover, the characteristics of the signal reflected from the masking networks created on the basis of such indicatrices are complicated by the process of mutual movement of the observer and the object of observation relative to each other.

Each beam from the system of reflected rays has a cross-sectional size equal to the size of the illuminated surface and multiplied by the tangent of the angle of divergence of the incident radiation. The cross-sectional area with increasing distance from the object increases according to the tangential law, while the area of the "dead zones" increases according to the cubic law. This suggests that the farther away from the object the “observer” is, the greater the distance between the diverging rays and the less the probability of detecting a signal reflected from the object.

The definition of the target image of typical weapons and military equipment takes place during comparative computer processing of the measurement results of the scattering indicatrix obtained by laser ranging with a database of typical targets. Changing the standard reflective characteristics from local areas of the object masked by the proposed camouflage network leads to a malfunction in the system for decrypting the image of the object. This, in turn, makes it unpromising to create target image recognition programs based on the known characteristics of a diffuse-reflected signal, since it is almost impossible to predict the nature of the spread of signals reflected from the object in the case of using such masking networks.

Such opportunities are provided by polymer film materials that are transparent to the emitting radiation and have an embossing texture, consisting of various types of structures with pointed 22 and (or) rounded peaks 23. The propagating radiation, passing through a transparent layer, falls on the walls, for example, pyramids 26-28 with a different number of faces and angles at the apex and is reflected from them. Depending on the angle at the apex of the pyramids 26-28 and the number of faces, the reflected beam is repeatedly reflected inside the pyramid, divided into several reflected rays, which exit from the pyramids 26-28 at certain angles.

The number of rays, into which the reflected signal is divided, depends on the number of faces and types of pyramids 26-28, as well as on the spatial arrangement of their bases relative to each other. As a result, the scattering indicatrix of the radiation reflected from the object becomes discontinuous in a wide range of azimuthal angles. The dependence of the spatial location of the reflected radiation on the angle of incidence of the locating radiation when moving objects leads to a constant change in their position in space. All this additionally increases the complexity of detecting rays in space and retaining observation and guidance systems on them.

The energy of the returned individual rays depends on the number of reflections inside the pyramids 26-28, as well as on the optical properties of the materials used and / or the optical properties of the reflective coating 9, 15 and the mask layer 10, 16.

Getting on the work surface of gabled structures with gabled 22 and rounded 23 peaks, electromagnetic radiation of the optical or infrared range passes through a masking color-bearing layer 10, 16 (or through a masking color-bearing layer 10, 16 and the material of polymer tapes 6, 11, 18, if reflecting the coating 15 is applied from their backside 30) and undergoes complete reflection on their faces or side surfaces, is reflected and directed at a certain angle to the incident beam, depending on the inclination of the faces or sides on top to the base. That is, in this case, when an object is detected in the optical or infrared ranges of the electromagnetic spectrum, the reflected radiation from the protected object covered by the proposed camouflage network does not fall on the tracking and observation equipment from which the radiation was sent, but is directed in completely different directions, determined by the angle the inclination of the faces and lateral surfaces to the base of structures with a pointed 22 and rounded 23 peaks, thereby causing erroneous actions in the personnel of the tracking and surveillance equipment. Thus, the protected object becomes difficult to detect or even “invisible” due to the “erosion” of the re-reflected radiation into the space around the masked object (aircraft, tank or other protected object), many times exceeding the dimensions of the protected object itself.

The irregular distribution over the surface of the material of the carrier network base 1 of structures with a pointed 22 and rounded 23 vertices (Fig. 4) makes it possible to further complicate the characteristics of the signal reflected from the masking networks created on the basis of such indicatrixes, especially in the process of mutual movement of the observer relative to each other and object of observation.

The implementation of the reflective coating 9, 15 with a reflection coefficient varying on the surface of the respective tapes also allows to further complicate the characteristics of the signal reflected from the masking networks created on the basis of such indicatrixes, especially in the process of mutual movement of the observer and the observation object.

The implementation of the reflective coating 9, 15 with a surface resistance of 2 to 50 Ohms makes it possible to increase the effectiveness of the camouflage properties of the proposed camouflage network when exposed to it in order to observe and investigate the locating radiation of the radio wavelength of the electromagnetic spectrum, and also eliminates the possibility of accumulation of static electricity on the camouflage material networks both as a result of possible intense exposure to locating radiation, and as a result of possible friction during transport ke, deployment, etc. The latter, in turn, makes it possible to increase the fire safety of the camouflage network and increase the effectiveness of its camouflage.

The execution of the heights and bases of structures with a pointed 22 and 23 rounded peaks different on the surface of the corresponding polymer tapes 6, 11, 18 also makes it possible to further complicate the characteristics of the signal networks reflected from the masking networks created on the basis of such indicatrices, especially in the process of relative movement relative to each other friend of the observer and the object of observation.

The radiation of the radio range (from a few millimeters to centimeter and longer waves) behaves similarly to the radiation of the optical and IR ranges on the faces or side surfaces of other structures with a pointed 22 and rounded 23 vertices. Moreover, the wavelength of the locating radiation in the radio range is commensurate with the dimensions of structures with a pointed 22 and rounded 23 vertices.

It should also be noted that in the event of the cure of various ranges of the electromagnetic spectrum falling onto the working surface of the proposed camouflage network, when using the faces of pyramids 26-28 with different angles of inclination to the base, corresponding to the angle of refraction of one of these ranges, the waves of the latter are reflected mainly on their respective wavelength faces with a certain angle of inclination. And after re-reflection on these faces of pyramids 26-28, all incident wavelengths will also separately come out at different angles to the incident radiation in accordance with the angle of inclination of the corresponding faces of pyramids 26-28. The side surfaces of other structures with pointed 22 and rounded 23 peaks work similarly.

When the angle of inclination of the faces of the pyramids 26-28 to the working surface of the material of the corresponding polymer ribbons 6, 11, 18, not exceeding 16 °, there is no re-reflection of the incident radiation on the faces of the pyramids 26-28 or the side surfaces of other structures with a pointed 22 and rounded 23 peaks, and it is reflected directly into the space in front of the reflective coating 9, 15 under the direction specified by the angle of inclination of the faces to the base and the number of faces in the pyramids 26-28. This is important because the transformation of the incident radiation of one wavelength into the radiation of a different wavelength of the electromagnetic spectrum occurs even when it first falls on the edge of pyramids 26-28, and its further re-reflection on other faces of the pyramids 26-28 The rereflection, which can occur when the angle of inclination of the faces of the pyramids 26-28 to the base over 16 °, will only lead to an increase in the temperature of the material of the carrier network base 1 due to the return of part of the light energy to it and the deterioration of its masking properties (in particular, to increase the visibility in IR -wavelength range). The side surfaces of other structures with pointed 22 and rounded 23 peaks work similarly.

Placement on the working surface of polymer films 6, 11, 18 of structures 33 imitating resemblance to natural vegetation, for example foliage, grass bunches, etc., with the possibility of imparting similarity to the surface of polymer films 6, 11, 18 with a background surrounding the masking network in the form natural vegetation provides increased masking efficiency of the proposed masking network in the visible region of the electromagnetic spectrum (11).

Based on the foregoing, a new achieved technical result of the invention is provided by the following technical advantages.

1. The proposed camouflage network allows for multispectral and broadband masking of the object from the locating radiation in the visible, infrared and near radio frequency ranges.

2. The proposed broadband camouflage network based on camouflage materials using the principle of protecting a camouflaged object, based on changing the characteristics of incident (locating) radiation, for example from GOS of modern weapons, provides masking of important military and military equipment, military facilities, economic facilities, public administration systems and infrastructure, land and air vehicles, aircraft, military installations and structures, etc. and personnel from observation equipment, target detection, recognition and target acquisition systems for automatic tracking operating in the laser location mode, can increase the effectiveness of masking by reducing the likelihood of recognition of a masked object and, accordingly, the probability of its destruction by about 1.5-3 times .

3. The expansion of the functionality of the masking material to ensure the masking of the object and its protection from equipment for observation, detection, recognition and target capture for automatic tracking by converting the incident radiation, for example from GOS of modern weapons, into radiation of another part of the spectrum of electromagnetic radiation, including both towards longer wavelengths and towards smaller wavelengths.

4. Increasing the efficiency of masking an object by at least 50% by expanding the range of changes in the characteristics of incident radiation, including by transforming it into other areas of the spectrum of electromagnetic radiation, as well as by reducing the temperature contrast of the masked object compared to the surrounding background by applying highly reflective metal layer and the use of masking pigment.

5. Providing the possibility of application for various, including mobile, objects and objects of a rounded shape, for example in the form of an awning. The advantage of the proposed camouflage network is its flexibility, mobility and the ability to easily deploy and collapse the masking network, if necessary, due to its implementation in the form of a thin polymer film of a roll type.

6. Simplification of the structure due to the combination of functions: the carrier network base 1 and the coating with recesses and (or) protrusions, which allowed to reduce the specific gravity and reduce the height dimensions of the proposed masking material.

Experimental samples of various masking materials at various objects after laboratory and bench tests have proved the main types of scattering indicatrixes, the nature of controlling the energy of reflected rays, the fundamental possibility of realizing tasks to effectively protect masked objects from detection, recognition, observation and guidance of weapons, as well as disrupting capture GOS targets without violating the mask of an object when it is visually observed. The masking properties of the proposed masking material have been tested both on clean materials and after they are wetted with water and contamination (to simulate conditions close to field conditions).

Sources used

1. US patent No. 3069796, 1962, MKI F41H 3/00.

2. Europatent No. 0129744, 1987, MKI F41H 3/02.

Claims (28)

1. A camouflage network containing a supporting network base of threads located in the transverse and longitudinal directions, placed at free intervals relative to each other, electrically conductive from at least one side of the polymer tape with a metal coating, a layer repeating on both sides the shape distributed over its surface recesses and (or) protrusions, a camouflage color-bearing layer, characterized in that the threads of the carrier network base are placed with the formation of cells, polymer tapes are made in the form of a layer, repeat on both sides of the surface of the recesses and (or) protrusions distributed on its surface, the metal coating is made reflective and applied to the surface of the polymer tapes from at least one side, a color masking layer is applied to the corresponding reflective coating, and the recesses and protrusions are made in in the form of structures with a pointed or / and rounded apex, providing reflection on their side surfaces of the emitting radiation in at least one direction different from the source of the emitting and radiation, while the polymer tape is placed in the transverse direction or in the longitudinal direction in the corresponding sequentially located cells with the possibility of their retention by the respective sides of the cells. 2. Camouflage net according to claim 1, characterized in that the polymer tape is made reinforced. 3. The camouflage network according to claim 1, characterized in that the polymer tape is made of a material that is transparent in the infrared wavelength range. 4. The camouflage network according to claim 1, characterized in that in the case of applying a camouflage color-bearing layer to the reflective coating on one corresponding side of the polymer tapes and performing structures with a pointed and / or rounded apex in the form of recesses, a reinforced base is additionally introduced into the camouflage network on the back of the corresponding peaks of pointed or / and rounded structures of the respective polymer tapes. 5. The camouflage network according to claim 1, characterized in that in the case of applying a camouflage color-bearing layer to the reflective coating on one corresponding side of the polymer ribbons and performing structures with a pointed or / and rounded apex in the form of protrusions, a reinforced base is additionally introduced into the camouflage network on the back of the surface of the respective polymer tapes. 6. The camouflage network according to claim 1, characterized in that the structures with a pointed or rounded top are made of the same type, while at least one side surface or part of at least part of the structures is located at an angle to the base, excellent from the angle of inclination to the base of the rest of the side surface or other side surfaces. 7. The camouflage net according to claim 1, characterized in that the dimensions of the heights and bases of structures with a pointed or rounded top are made different on the surface of the respective polymer tapes. 8. The camouflage network according to claim 1, characterized in that the structures with a pointed or / and rounded peak are distributed irregularly on the surface. 9. The camouflage network according to claim 1, characterized in that in the case of constructions with a pointed peak, at least part of the structures with a pointed peak is made in the form of polyhedral pyramids or a conical shape. 10. The camouflage network according to claim 9, characterized in that in the case of designs with a pointed peak in the form of polyhedral pyramids, at least one part of the pyramids is made with a number of faces different from the number of faces of the remaining pyramids. 11. The camouflage network according to claim 9, characterized in that in the case of structures with a pointed peak in the form of polyhedral pyramids, at least part of the structures with a pointed peak is made in the form of trihedral pyramids. 12. The camouflage network according to claim 1, characterized in that the structures with a rounded apex are made as part of spheroids, and (or) ovals, and (or) ellipsoids, and (or) elliptical paraboloids, and (or) hyperboloids. 13. The camouflage network according to claim 1, characterized in that the structures in the form of protrusions are made in the form of ribs. 14. The camouflage network according to claim 1, characterized in that in the case of the execution of polymer tapes with recesses and protrusions, the polymer tape is made wavy. 15. The camouflage network according to claim 1, characterized in that the reflective coating is made with a surface resistance of 2 to 50 ohms. 16. The camouflage network according to claim 1, characterized in that the reflective coating is made in the form of a metal highly reflective layer or a layer of particles with a highly reflective surface. 17. A camouflage network according to any one of claims 1, 15, 16, characterized in that the reflective coating is made with a reflection coefficient varying on the surface of the respective polymer tapes. 18. The camouflage network according to claim 1, characterized in that in the case of applying a reflective coating to the surface of the polymer tapes on one corresponding side, the polymer tapes are made in the form of an additional camouflage color-bearing layer with a camouflage color different from the camouflage color of the camouflage color-bearing layer on the reflective coating . 19. The camouflage network according to claim 1, characterized in that in the case of applying camouflage color-bearing layers on reflective coatings on both sides of the polymer tapes, camouflage color-bearing layers are made with different camouflage colors. 20. The camouflage network according to claim 1, characterized in that the camouflage color-bearing layer is made of a polymer binder with pigment additives. 21. The camouflage network according to claim 18, wherein the additional camouflage color-bearing layer is made of a polymer binder with pigment additives. 22. The camouflage network according to claim 20, characterized in that the pigment additives of the polymer binder of the camouflage color-bearing layer are made of ocher, lime, soot, barium sulfide, cobalt blue or chromium, iron or titanium oxides. 23. The camouflage network according to claim 21, characterized in that the pigment additives of the polymer binder of the additional camouflage color-bearing layer are made of ocher, lime, carbon black, barium sulfide, cobalt blue or chromium, iron or titanium oxides. 24. The camouflage network according to claim 20, characterized in that the polymer binder of the camouflage color-bearing layer is made transparent in the infrared wavelength range. 25. The camouflage network according to claim 21, characterized in that the polymer binder of the additional camouflage color-bearing layer is made transparent in the infrared wavelength range. 26. The camouflage network according to claim 1, characterized in that the camouflage color-bearing layer is additionally activated by a luminescent compound made in the form of a phosphor that converts the absorbed radiation into radiation of another spectral region with a longer wavelength of electromagnetic radiation, or as an anti-Stokes phosphor that converts the absorbed radiation into radiation of another spectral region with a smaller wavelength of electromagnetic radiation. 27. The camouflage network according to claim 21, characterized in that the additional camouflage color-bearing layer is additionally activated by a luminescent compound made in the form of a phosphor that converts the absorbed radiation into radiation of another spectral region with a longer wavelength of electromagnetic radiation, or in the form of an anti-Stokes phosphor that converts the absorbed radiation into radiation of another spectral region with a smaller wavelength of electromagnetic radiation. 28. The camouflage network according to claim 1, characterized in that it additionally introduces structures simulating similarities to natural vegetation and placed on the corresponding working surface of polymer films with the possibility of imparting similarity to the surface of polymer films with natural vegetation.

Images