DE3614017A1 - MULTI-SPECTRAL CAMOUFLAGE - Google Patents

Description

The invention relates to a plastic film with low Emissivity in the 2nd and 3rd atmospheric window and higher Transparency in other spectral ranges, for example against microwaves. The camouflage film is suitable due to their special characteristics

• - as a simple, replaceable, low-emitting Coating,
• - For thermal imaging camouflage of fixed systems, in particular Radomes,
• - as a universal component in multispectral camouflage systems.

The camouflage of objects against enlightenment by thermal imaging devices contains a special problem. Different than in Visibility is visible in the thermal infrared range  of an object not only from its surface properties (such as color, reflectance, roughness) but is additionally affected by the temperature of the surface and the temperatures of the environment, the background and the Heaven determined.

Low emissive coatings are used for camouflage. This measure reduces, proportionally to the level of emissivity ε of the surface, the heat radiation emanating from this object; In this way, the detectability can be reduced, particularly in the case of objects that are warmed up more.

In addition to the paints, other infrared camouflage agents are similar Effect known: for example low emissivity Textiles, laminated metal foils, infrared camouflage nets with metallic elements (layers, foils, threads), galvanic, low-emissivity coatings and the like.

Common feature of this infrared active camouflage is that the low-emitting effect by storing metallic layers or particles is reached. Low Infrared emissivities below about 70% occur in homogeneous Materials only if this is metallic in character and have a certain metallic conductivity.  

Conventional metal-containing IR camouflage and IR camouflage have some typical drawbacks that affect their uses and severely limit effectiveness: The metal component causes the layers to be electromagnetic Radiation is generally opaque and strong Show reflection effect. In the visual field, the unwanted reflection usually with the help of color pigments suppressed, but this is in the microwave and Radio wave range not possible, so this IR camouflage show no camouflaging effect against radar reconnaissance or the discoverability tends to be increased even more when the object is itself radar neutral.

For the same reason, conventional low-emissivity Layers not for camouflaging communication systems such as transmitting and receiving antennas, radome and others appropriate facilities are used.

The present invention is based on the object to create multispectral camouflage.

This object is achieved with the help of a coated Plastic film released, the coating made non-metallic, infrared-transparent material and the layer thickness is set in relation to the calculation index  is that due to interference effects, the heat radiation reduced in the 2nd and / or 3rd atmospheric window becomes. The arrangement has a high permeability for radiation in the microwave and radio wave range and each according to the embodiment also in other spectral ranges (visible light, near infrared) so that the multispectral Camouflage is guaranteed or not hindered.

By lining up several film segments with different radiation (emissivities) and more suitable Geometric shape can easily be more Camouflage effects by contour decomposition or generation of any Infrared signatures can be achieved.

The invention is described in more detail below with reference to figures. It shows:

FIG. 1 cuts through the structure of the films in three embodiments,

Fig. 2 shows the spectral profile of the reflectance of the three embodiments in Fig. 1,

Fig. 3 shows the use of a multilayer system as a film structure,

Fig. 4 shows the representation of a dome and the possibility of the simulation does not existing structures on the dome,

Fig. 5 shows a section through the structure of a radar absorber device.

Fig. 1 shows the simple structure of the camouflage film in three different settings. An infrared-transparent, dielectric interference layer 4 is located on a preferably infrared-transparent carrier film 2 (for example made of polyethylene). The film covers the object 6 to be camouflaged against an observer. A protective layer 8 can optionally be used, it must in any case be transparent in the IR frequency range of the application. The area 10 represents the air space between the film and the object.

For a given layer material, the layer thickness d of the interference layer determines the amount of heat radiation, the emissivity, the overall arrangement of film and object. If a particularly low radiation, i.e. a cold surface, is to be simulated, the thickness should be set approximately to the value d = λ / (4 · n ) ( FIG. 1 a ), where n means the refractive index of the layer and λ wavelength of the radiation. As a rule, λ is related to the center of the atmospheric window (approximately 4 µm and 10 µm).

This is a low IR transmittance and a low one Radiated heat from the object to be camouflaged and camouflage film.  

The opposite extreme case (high emission, high surface temperature) is set by the arrangement according to FIG. 1 c and a medium state according to FIG. 1 b . In FIG. 1 b , the thickness d is calculated as d = 3 · λ / (8 · n ) and in FIG. 1 c , d receives the value d = λ / (2 · n ). All other intermediate states can be easily implemented in this way.

For clarification, FIG. 2 shows the spectral profile of the reflectance of the three arrangements sketched in FIG. 1. It can be seen how the reflection maxima are shifted in relation to the atmospheric windows and how the described effect arises.

Figs. 1 and 2 describe the situation of interference on a layer. Reflex-reducing and reflex-enhancing effects can be increased even further by using systems with two or more interfering layers. However, the practice of infrared camouflage shows that in most cases it is not the extreme values, but rather average emissivities of ε = 30-70% that can be generated with the single-layer interference that are advantageous.

A larger number comes as a possible layer material  of substances into consideration. The selection depends on the required transmission range in the infrared and in the optical Spectrum, as well as practical and technical Aspects such as manufacturability, durability and cost. It offers broadband camouflage and good stability Group of semiconductors such as silicon, germanium, graphite, as well Metal sulfides, metal selenides and metal tellurides, which too can be used as a raw material for compact IR windows. In addition, there is transparency in the visual field oxidic materials such as, for example, are desired SiO₂, Al₂O₃, SnO₂, In₂O₃, TiO₂, CeO₂, MgO, Fluorides such as MgF₂, PbF₂, BaF₂ and other compounds can be used with similar properties.

Another important criterion for the choice of material is the refractive index of the layer and its dispersion, i.e. its spectral course. High refractive indices are generally advantageous since the required layer thickness decreases with increasing n and the camouflage effect is still present even at increasingly oblique viewing angles. The dispersion must be taken into account if a simultaneous effect in both atmospheric windows is to be optimized. Is z. B. a layer set to maximum reflection (low emission) at g ₃ = 10 µm ( d = λ / (4 · n ₃); n ₃ = average refractive index in the 3rd atmospheric window)), this layer also has a reflection maximum in the 2nd atmospheric window, the exact location of which depends on the refractive index n ₂ (at 3-5 µm):

If the refractive index is not frequency-dependent ( n ₂ = n ₃), the maximum is λ ₂ = 5 µm. A slight increase in the distance between the two maxima ( λ ₂ - λ ₃), which will generally be desirable, requires that n ₃ is somewhat larger than n ₂.

Fig. 3 shows, instead of a compact interference layer using a multilayer system in which two thinner films 4 having high refractive index at the distance d through the layer 12 are separated with a low refractive index. The particular advantage of this embodiment is that a transparent plastic film can be used as layer 12 , the z. B. is identical to the carrier film 2 . In this case, the layers 4 can be made much thinner than the above λ / 4 layers, so that the arrangement gains greater flexibility, which has a very advantageous effect for many applications. However, the optical effect of this arrangement corresponds to the one-layer interference. The air gap 10 is located between the carrier film 2 and the object 6 to be camouflaged.

Further features and advantages of the invention are intended to be based on typical applications.

The camouflage film according to the invention can be very advantageous for Cladding of radome (radome) can be used. Today's design of radomes has changed with regard to the detectability in the IR range is extremely unfavorable proven. Due to the low thermal conductivity and heat capacity of the radome outer skin (plastic foam material or foils) the surface temperature is strong subject to weather-related fluctuations in what these objects an unusually well-defined thermal image signature gives. Countermeasures with conventional camouflage means without No effects on radar transmission are known.

FIG. 4 shows symbolizes this application. FIG. 4 a shows a typical signature of a radome in sunlight. The upper half of the sphere is warmed up and stands out against the much darker background. At night, the light-dark conditions are just the other way around due to the low sky temperature, but just as easily recognizable. With the help of the foil according to the invention, which is attached to the outer surface of the radome, an effective contour decomposition is brought about by typical structures of the surroundings, such as, for example, B. rectangular areas in agricultural fields ( Fig. 4 b , without background) or settlements, building structures ( Fig. 4 c ) or other landscape formations (horizon lines, ranges of hills, forest areas, river courses) can be simulated.

A similar situation exists with the camouflage of others Systems and components of transmission technology, i.e. radio transmitters, Telecommunications stations, satellite receiving antennas, Radio control systems or direction finding and reconnaissance systems). All these defensible facilities in the event of a defense, which so far can be seen as easily recognizable and vulnerable Help of the invention effectively camouflaged against thermal imaging without any impairment of their function.

Other applications are in the IR camouflage of buildings, Roads, bridges and similar facilities; Likewise strategically very important objects that were previously compared to the Thermal imaging observation not or only at the expense of increased Protect radar detectability. This is advantageous also that the camouflage film according to the invention is not constantly - like a coat of paint - must be present, since if necessary can be spread out and removed very quickly can. For some objects, such as streets and Airfield facilities, this is the only conceivable solution.  

An application where the permeability in the microwave range is also a crucial requirement, are radar absorbing materials and structures. These known camouflaging agents against radar reconnaissance are without exception good IR emitters and therefore light in the thermal image detectable, but on the other hand with low emissivity Not to treat metal-based paints, since then the Radar absorber effect is lost.

FIG. 5 shows a cross section through this arrangement. The IR-active camouflage film with plastic carrier 2 and interference layer 4 is connected directly to the radar absorber material 14 . The above-mentioned variants for contour decomposition and signature simulation can of course also be used advantageously here.

An additional camouflage effect in the visible or near infrared is possible by using colored plastic foils. If foils with good optical transparency are used, then the visual camouflage effect can be deposited and thus easily changeable paint coats can be achieved, or it is due to the existing camouflage of the object already given.

In the conceivable application of the camouflage film according to the invention on vehicles, ships, airplanes, steel bridges, steel masts  and the like, there is a special aspect. These Objects exhibit due to their predominantly metal Structure a clear and characteristic Radar signature. This problem can basically be solved by Application of radar absorbers and multispectral camouflage film, as described above. But are radar absorbers for any reason (weight, cost, availability) not wanted or not possible, then with help a combined IR-radar camouflage effect can be achieved in that the film on the object side is completely or partially metallized. Certain characteristic radar signatures of the object can be canceled or falsified in this way.

Claims (8)

1. Device for multispectral camouflage of objects against reconnaissance, characterized in that a plastic film ( 2 ) with a non-metallic, a reduced heat-transmitting coating ( 4 ) is used and this coated film has a high permeability in other, the thermal infrared adjacent Has spectral ranges in which a camouflage effect should also be achieved. 2. Apparatus according to claim 1, characterized in that the low-emitting effect in the temperature radiation range is brought about by an interference effect in the layer ( 4 ) or in a multilayer structure and the layer thickness (s) is adjusted in relation to the refractive index of the interfering layer (s) in this way ( that the lowest order reflection maximum is in the center of the 3rd or 2nd atmospheric window, depending on the application. 3. Device according to claims 1 and 2, characterized in that that the lowest order reflection maximum of Interference layer system in the 3rd atmospheric window is placed and a simultaneous effect in the 2nd atmospheric Window through the reflection maximum of the next higher Order arises. 4. Device according to claims 1 to 3, characterized in that lower reflection values of the film, synonymous with higher emission of the overall order in which the reflection maxima are more or less from the center of the atmospheric windows will. 5. The device according to claim 1, characterized in that the object to be camouflaged ( 6 ) with a plurality of lined up film segments according to claim 2 to 4 is covered or covered with different emissivity, so that an IR contour tear and adaptation to the background is achieved and this Segments are designed in any geometric shape. 6. Device according to claims 1 to 5, characterized in that they are used for heat generation from radomes and others Antenna systems and transmission stations is used. 7. Device according to claims 1 to 5, characterized in that that they are used to camouflage buildings, bridges, Roads, airfields and other facilities are used becomes. 8. Device according to claims 1 to 5, characterized in that the film ( 2 ) on the object side is completely or partially metallized and is used for multispectral camouflage of predominantly metallic objects such as vehicles, ships, planes, bridges, masts and other corresponding objects.