EP0947798B1 - Camouflage material and maufacturing process therefor - Google Patents

Abstract

A process for the production of a camouflage material (I) for the visible, near infrared, far infrared and radar wavelengths comprises: (A) preparation of a carrier fabric (B) removal of processing aids and surfactants from the fabric and drying (C) application of a metal layer onto the fabric (D) application of a primer and camouflage paint onto the metal layer. An Independent claim is included for the resulting camouflage material (I) comprising a support fabric, a metal layer, a primer layer and a camouflage paint for infrared.

Description

The invention relates to a process for the preparation a camouflage material and a camouflage material itself, in particular a camouflage material according to claims 1 and 16.

In the production of broadband acting Camouflage materials are known layer structures in which several layers with different Emissions / reflectivity superimposed in such a way be that the Tarnbeschichtungen with a possibly existing carrier as a whole considers the desired Camouflage in the intended spectral range allow. The aim of the camouflage is that one with the Camouflage material covered in the given Wavelength spectrum with respect to the reflection / emission behavior a similar to the natural environment Behavior shows, so that detecting at least difficult, if not impossible.

Such a camouflage material, according to the preamble of claim 1, is for example in the US Patent No. 4,495,239 which discloses a Polymer backing comprises, in one embodiment is plasticized with PVC. This PVC serves as Primer for a subsequent metal layer, e.g. may consist of aluminum. To protect the metallization becomes a thin layer of an IR-transparent polymer applied, which further as a primer for the subsequent camouflage is used.

In the true sense of the camouflage effective Layers are then essentially the metal layer and the camouflage paint. The metal layer is on the one hand for a given reflection in the IR range and on the other hand, along with the cut garnish of the Camouflage material, for a particular reflection and Absorbtionsverhalten in the radar wave range responsible. The camouflage paint works especially in the visible and infrared Range of the spectrum.

Furthermore, Swiss Patent No. 667 524 another camouflage material are taken, in which a Polyethylene layer is steamed with a metal. Two in Coated polyethylene layers made in this manner are then on adhesive layers on both sides of the Fabric attached.

U.S. Patent No. 5,348,789 also describes a camouflage material from a Polyester knitted fabric with a hole structure. Here are already incorporated into the polyester knit fabric metal fibers and the Knitted fabric is provided with a polymer layer, what a complicated process means.

In addition, recently camouflage materials became known, which further improved camouflage exhibit. These camouflage materials are based on the knowledge that the quality of a camouflage depends on how good of the Stealth material the soil temperature is assumed and as well the spectral behavior of the sun or the atmosphere be taken into account. With these new materials An attempt is made to place a metal layer directly on top Apply the carrier fabric to the spectral behavior of the Camouflage material and secondarily the to simplify the structural design of the camouflage material. at the production of the named camouflage and the finished Product, however, have unforeseen problems resulting in a practicality of the camouflage material conflict. These difficulties are addressed in the essential to the durability and on the Reproducibility of the stealth requirements of the produced Camouflage material.

The potential benefits of such a simplified Structure in terms of its spectral behavior, but also their cost advantages due to their simple structure However, they can only be used in practice if the problems of production are solved.

The invention is therefore based on the object cost-effective and reproducible method or To provide camouflage material by means of which visible spectral range, the near IR, the far IR and, or the radar wave spectrum a comprehensive camouflage is possible.

The solution of this task is at the highest Surprisingly, already through the process steps of the main claim 1, wherein a carrier fabric provided is and this largely of weaving agents and surfactants is freed and purified on the Carrier fabric after drying under vacuum Metal layer is applied to a primer is deposited, which is the backing layer of camouflage paint represents.

In the context of the method according to the invention it has proved to be very advantageous, a polymer as a carrier fabric to use, which has a polar character. It could be shown that by the Tissue polarity a particularly good adhesion of Metallization on the tissue can be ensured. One Applying a primer, as often in the state The technique is used to increase the adhesion on the fabric is thus no longer necessary, so that a procedural step could be saved. In addition, this has the advantage that the important for the scattering effect of the camouflage network Surface structure of the carrier fabric directly on the Metal layer transfers. At the same time the surface structure becomes the carrier fabric usually designed so that they for the diffuse scattering of incident IR radiation, especially in the atmospheric window II (Wavelength range 3 - 5 am), can contribute. In which thereby a substantially decreasing reflectance achievable in the atmospheric window II of the camouflage material is.

The carrier material is preferably polar polymers selected. Whereby polyester by their high mechanical resilience advantageous characterize.

Furthermore, in the context of the inventive Procedures are found that at the step of Removal of weaving tools or avivages and Surfactants must be taken to ensure that after cleaning of the carrier tissue, the gasoline-soluble fraction of surfactants is less than about 0.20 ° s and the water-soluble Proportion is below about 0.02%. A fact, the previously found little or no attention Has. However, it should be noted when the metallic material directly on the carrier fabric is applied, since at substantially higher levels the Adhesiveness of the fabric with respect to the metal strong is impaired.

Is in the method according to the invention Dry the fabric on this the metal coating upset, so it has in this step as much positively exposed when applying the metal in the Vacuum takes place as the resulting Dust particles is a guarantee that the Spectral behavior of the camouflage material not through Contamination of the metal layer is adversely affected. In this context, it has also been targeted for one dosed order of the metal proved, the metal from one metallic gas atmosphere out on the vehicle fabric evaporate. One applied to the fabric carrier Metal layer is homogeneous and can be easily reproduced become.

One for the required multispectral camouflage behavior For example, well-suited metal is aluminum. Of the Sheet resistance of the aluminum is in particular Areas where an attenuation of radar waves occur can. Depending on the wavelength of the moves Resistance of aluminum between 30Ω and 300Ω. With reference on the camouflage material according to the invention, the resistance et al also be adjusted by the layer thickness. For the skilled person is obvious that of course others Metals such as e.g. Silver and / or gold are used can. Also combinations of named metals are conceivable.

In the application of the method according to the invention has showed that a metallization of the carrier tissue with a surface density of about 100 mg / m2 to about 200 mg / m2 or preferably at about 130 mg / m2 in the significant optimal result in terms of spectral Behavior of the metal layer in the candidate Wavelength ranges, especially in the infrared and in the Radar wave range, can be guaranteed.

The application of the primer comprises the application a polymer layer on the metallization of the Fabric carrier, so it is of particular advantage when this has polar properties. It will become one compared to polyolefins greatly improved adhesion to Metal achieves and the camouflage material receives in addition one particularly high weather resistance, in particular the fabric metal layer polymer layer structure. The water-sensitive metal layer is so safe against Protected against moisture. By the big one Adhesion resistance of the layers is also high Resistance to mechanical stress given.

The polymer is so crosslinked, preferably partially crosslinked, that this has an amorphous structure and the layer appears partially transparent, as it is for the natural environment in IR is also often the case. The Polymer layer further provides a tissue consolidation certainly, which ensures consistent structures and one good punchability to achieve a cut Garnishing the camouflage material allows.

Preferably, flame retardants are used in the polymer layer used. Are the corresponding ones Particles, such as in antimony trioxide or in according to suitable organic bromine compounds with a distribution of particle size, so in the Embedded polymer layer of the primer, that about 90% the particles have a diameter smaller than 5 μm have, these possess only very little influence on the emission and reflection characteristics of the Camouflage material or can be this influence accordingly take into account when designing the layers. The amorphous structure and the partial transparency of the polymer layer in the IR, this is only possible by the flame-retardant agent slightly disturbed.

As a polar polymer for the polymer layer are available For example, fully or partially crosslinked polyurethanes and or polyacrylates which have good adhesion to the Metal layer allow a homogeneous embedding of allow flame retardant agents and as a primer for the serve subsequent camouflage.

For improved practicality of the Tarnetzes invention is not in the primer just to embed a flame retardant, but also a suitable microbiocidal equipment. This mushroom and bacterial protection preferably comprises a substance Isothiazolinone basis. These are characterized by both high spectrum of activity as well as good Polymer compatibility. That this also makes the amorphous character and partial transparency in the IR of the Polymer not impaired.

Furthermore, in the process according to the invention in Under the primer another hydrolysis protection be applied, the weather resistance of the this camouflage material even better. As preferred Material has been found carbodiimide, which by a good compatibility with the in the Primer embedded polymer distinguishes. Naturally Other materials are also conceivable, similar ones Have properties such as the above-mentioned carbodiimide.

With reference to in the context of priming Applied layers, it has in practice as proved advantageous that the surface density of the primer is limited to substantially 15 to 16 g / m2, if a green camouflage finish follows on the primer. On the other hand it has a subsequent olive-gray camouflage paint Proven when the areal density of the primer preferably between 23 and 24g / m2. A possible higher stratification of the primer would cause the 6dB attenuation in the radar range is not achieved.

An improved camouflage effect is achieved when the Carrier fabric is metallized from both sides and accordingly if the described primer and Painting also done on both sides. In addition, one could thus realize a camouflage material, both in winter as well as other seasons can be used, since on the different sides each a matched coating or painting is possible.

For the carrier tissue has become a universal camouflage material a titre of 550 dtex and a Plain weave 1/1 with a thread setting of warp about 14.5 Fd / cm shot to about 12 Fd / cm with a Thread turn of the chain of about 60 tours and one Thread turn of the shot of 0 turns as well when exposed to this tissue at about 130 mg / m2 Aluminum was coated.

With universal camouflage material is intended here for the purpose of Description to be called a material which on the one hand to camouflage objects at different Weather conditions and / or environmental conditions and is also suitable for camouflaging objects that have a have higher temperature than the environment.

The invention is described below with reference to a Embodiment and with reference to the attached Drawings described. The same parts have the same same identification received.

Fig. 1

eine schematische Darstellung eines Querschnitts eines erfindungsgemäßen Tarnnetzes

Fig. 2

eine stark schematisierte Darstellung des Querschnitts der erfindungsgemäßen Grundierung

Show it:

Fig. 1

a schematic representation of a cross section of a camouflage net according to the invention

Fig. 2

a highly schematic representation of the cross section of the primer according to the invention

Starting point of the camouflage material 1 of a preferred Embodiment of FIG. 1 is a woven carrier fabric 2 made of a polar polymer. At the preferred Embodiment is for the production of the universal Camouflage material a carrier fabric made of polyester, which has a titre of 550 dtex and a plain weave 1/1 with a thread setting of chain 14.5 Fd / cm too Shot 12.1 Fd / cm, with a thread turn of the chain of 60 turns and a thread turn of the shot of 0 Tours.

Before metallization, all yarn and Weaving tools such as sizing and aviagen from the fabric removed to ensure the greatest possible adhesion of the metal on Reach tissue. Furthermore, the residual moisture of the To pay attention to the quality of the metal coating 3 is also detrimental. For this reason, the Metal vaporization according to the invention on both sides immediately after a drying process. Whereby the steaming of the Metal always takes place in a vacuum.

By vaporizing the carrier fabric transfers its three - dimensional structure directly on the Metal layer 3. The surface structure of the related Fabric 1 is chosen so that it has a diffuse scattering effect in the atmospheric window II, i. between 2.5 and 5 μm, on the incident radiation exerts, while the Broadcasting with increasing wavelength in the shows significant falling course.

In the preferred embodiment, as Steaming material aluminum with 130 mg / m2 3 used. Due to this surface density, the resistance of the Adjusted aluminum such that a substantially optimal damping of radar waves is achievable.

Afterwards it is known on both sides on the expert Art applied a primers 4a and 4b. On the Top 4a comprises the primer about 15.5 g / m2 and on the bottom 4b about 23.5 g / m2. The primer according to the Figures 1 and 2 has on the metal layer 3 a partially cross-linked polyurethane 6. In the amorphous and in the thermal IR windows II and III or in the Frequency ranges between 2.5 and 5 microns and between 7 and 14 μm transparent polyurethane is antimony trioxide 7 and / or an organic bromine compound as a flame retardant Embedded funds. The crystals have one Size distribution on that about 90% of the particles size have a maximum of 5 microns. The polymer layer 6 serves as Protection for the metal layer and as a carrier for the Flame-retardant particles 7. In addition, in the Polymer layer 7 of the primer a mikrobiocides Equipment 8 for protection against fungal and bacterial attack embedded. Furthermore, the primer comprises one Carbodiimide existing additional hydrolysis protection 9. The described primer acts for the subsequent camouflage Painting as a primer. In which on the primer 4a, 4b applied camouflage paint is a special Camouflage paint from the company Schill + Seilacher. The camouflage paint is used essentially for camouflage in the visible range. In the in Fig. 1 illustrated embodiment was on the Top applied a green summer paint 5a and on the bottom an olive-gray winter color 5b.

The camouflage material has in the range of 2.5 microns to 4 a substantially from about 0.9 to about 0.55 decreasing emission coefficients. It is at an averaged value, which is a dispersion of approx. ± 1.5. In the range between 4 and 7.5 microns, in which the Earth atmosphere is intransparent, goes the Emission coefficient either to its initial value back again or he reaches the value to which he then in Frequency range between 7.5 microns and 14 microns substantially remains constant. This value is about 0.8. A certain dispersion of named values for the According to experience, emission coefficients can not be excluded. This does not change anything principal emission behavior.

Finally, the ready-made material in a conventional manner by a punching process with a Stepped garnish provided, whereby the Reflectance or the diffuse scattering for Radar waves can still be improved.

Other embodiments of the invention Camouflage materials are similarly easy to manufacture. In a further preferred embodiment of the For example, the invention will be described as a polar carrier web Polyester related.

Also related to a changed Transmission / reflection behavior in the IR or radar range of the camouflage material, the carrier fabric in others Embodiments of the invention preferably have a titer with 550 dtex and a plain weave 1/1 with a Thread setting of chain between 11 to 16 Fd / cm too Shot between 10 to 14 Fd / cm on with a thread turn the chain between 0 to 120 tours and a thread turn shot of 0 tours. The carrier fabric is in different embodiments of the invention with others Metals such as silver, nickel or gold steamed.

For the polymer layer, which is a polar polymer includes comes in yet another embodiment a partially cross-linked polyurethane is used. When Flame-retardant agent becomes antimony trioxide and / or used organic bromine compounds. In this case, too is the distribution of the particle size of such that preferably 90% of the particle sizes of a maximum of 5 microns have.

The camouflage material according to the invention has the large Advantage, depending on the specifications of its spectral behavior in terms of emission, absorption and / or transmission due to different environmental conditions or to camouflaging objects to be variable in a wide range. This makes it easy for the particular application, for example, for a winter or a summer camouflage optimal camouflage material, z. B. by variation of Tissue structure, the metal and its layer thickness and / or the applied camouflage one for each Purpose to produce optimized camouflage material. same for for the camouflage of objects compared to the environment have a higher temperature.

In some cases, it may also be useful in the course a further improved protection in certain Spectral areas to apply additional layers.

Claims (18)

1. A method of making a camouflage material (1) for the visible spectrum, the near IR and the far IR and the radar wave spectrum, characterised by the method steps:

   a) preparing a carrier fabric (2) comprising a polar polymer,

   b) removable of web processing agents and surfactants of the carrier fabric (2) and drying of the carrier fabric (2),

   c) application of a metal coating (3) to the carrier fabric (2),

   d) application of a primer (4, 4a, 4b) and a camouflage paint to the metal coating (3).
2. A method according to claim 1, characterised in that the carrier fabric (2) comprises a polyester.
3. A method according to claim 1 or 2, characterised in that during the step of removal of web processing agents and surfactants of the carrier fabric (2) the benzine-soluble fraction is reduced to approximately less than 0.20% and the watersoluble fraction to approximately less than 0.02%.
4. A method according to any one of the preceding claims, characterised in that the step of applying a metal coating (3) to the carrier fabric (2) comprises the step of vacuumising.
5. A method according to any one of the preceding claims, characterised in that the step of applying the metal coating (3) comprises vapour coating the metal on to the carrier fabric (2).
6. A method according to any one of the preceding claims, characterised in that the step of applying the metal coating (3) comprises applying preferably aluminium or a metal comparable in respect of electrical conductivity.
7. A method according to any one of the preceding claims, characterised in that during the step of applying the metal coating (3) the carrier fabric (2) is coated with approximately 100 mg/m² to approximately 200 mg/m² or preferably approximately 130 mg/m².
8. A method according to any one of the preceding claims, characterised in that the step of applying a primer (4) comprises applying a polar polymer (6), for example a polyurethane or polyacrylate.
9. A method according to any one of the preceding claims, characterised in that the polymers (6) of the primer (4) preferably have full or partial cross-linking.
10. A method according to any one of the preceding claims, characterised in that the step of applying a primer (4) to the metal coating (3) comprises the step of applying a difficultly flammability agent (7), preferably antimony trioxide and/or an organic bromine compound.
11. A method according to any one of the preceding claims, characterised in that the difficultly flammability agent (7) has a particle size of preferably approximately 5 µm.
12. A method according to any one of the preceding claims, characterised in that the step of applying a primer (4) comprises the step of applying a microbiocidal finish (8) to protect preferably against fungal and bacterial attack.
13. A method according to any one of the preceding claims, characterised in that the step of applying a primer (4) comprises the step of applying a hydrolysis protection (9), preferably a carbodiimide based polymer.
14. A method according to any one of the preceding claims, characterised in that the primer (4) has a density per unit area of preferably approximately 15 to 16 g/m² on a subsequently green camouflage painted side (4a) and preferably approximately 23 to 24 g/m² on a subsequently olive-grey camouflage painted side (4b).
15. A method according to any one of the preceding claims, characterised in that the steps:

    application of a metal coating (3) to the carrier material (2),

    and

    application of a primer (4) and a camouflage paint (5a, 5b) for the metal coating

    are carried out on both sides of the carrier material (2).
16. A camouflage material (1), particularly according to a method according to claim 1, comprising

    a carrier fabric (2),

    a metal coating (3),

    a primer (4) to cover the metal coating (3) and

    a camouflage painting (5a, 5b) for the IR,

    characterised in that
    the carrier fabric (2) comprises a polar polymer.
17. A camouflage netting according to claim 16, characterised in that the carrier fabric (2) has a titre with 550 dtex and a linen weave 1/1 with a warp thread setting of between 11 to 16 threads/cm, preferably 14.5 threads/cm, to a weft of between 10 to 14 threads/cm, preferably 12.0 threads/cm, with a warp thread twist of between 0 and 120 turns, preferably 60 turns and a weft thread twist of zero turns.
18. A camouflage material (1) according to claim 16 or 17, characterised in that the camouflage material (1) has a cut lining.

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