EP0947798A2 - 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 method for manufacturing a camouflage material and a camouflage material itself, in particular a camouflage material according to claims 1 and 17.

When producing broadband Layered structures are known in which multiple layers with different Emissivity / reflectivity superimposed in this way be that the camouflage coatings with a possibly existing carrier as a whole considers the desired one Enable camouflage in the intended spectral range. The The aim of the camouflage is that one with the camouflage material covered object in the given wavelength spectrum with regard to the reflection / emission behavior shows similar behavior in a natural environment, so that a Detecting is at least difficult, if not impossible is made.

Such a camouflage material is, for example, in the United States Patent Mr. 4,495,239, which a Polymer carrier fabric comprising, in one embodiment is plasticized with PVC. This PVC serves as a primer for a subsequent metal layer, e.g. made of aluminium can exist. To protect the metallization, a thin Layer of an IR-transparent polymer applied, which also serves as a primer for the subsequent camouflage paint.

The effective ones for camouflage Layers are then essentially the metal layer and the camouflage paint. The metal layer is for one predetermined reflection in the IR range and on the other hand, together with the cut garnish of the camouflage material, for a certain reflection and absorption behavior in the Radar wave range responsible. The camouflage varnish acts especially in the visible and infrared range of the spectrum.

Swiss Patent Specification No. 667 524 another camouflage material can be removed, in which a Polyethylene layer is evaporated with a metal. Two in coated polyethylene layers produced in this way are then on both sides of the fabric via adhesive layers appropriate.

In addition, camouflage materials have been used recently become known, which is a further improved camouflage exhibit. These camouflage materials are based on the knowledge that that the goodness of camouflage depends on how well it does Camouflage material the floor temperature is assumed and how good the spectral behavior of the sun or the atmosphere be taken into account. With these new materials an attempt is made to apply a metal layer directly to apply the carrier tissue to the spectral behavior of the To improve camouflage material and secondly the to simplify the structure of the camouflage material. At the manufacture of the named camouflage and during manufacture However, product have unforeseen problems result in a practical suitability of the camouflage material oppose. These difficulties are addressed in the essential to the durability and to the Reproducibility of the camouflage requirements of the manufactured Camouflage material.

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

The invention is therefore based on the object cost-effective and reproducible process 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 made possible.

This task is solved to the max surprisingly already through the process steps of Main claim 1, wherein a carrier fabric is provided and this largely from web processing equipment and Surfactant is released and on the cleaned carrier fabric after drying under vacuum a layer of metal is applied, on which a primer is deposited which is the backing layer of the camouflage paint.

In the context of the method according to the invention, it has proved to be very advantageous as a polymer To use carrier fabric, which has a polar character having. It could be shown that through the Tissue polarity a particularly good adhesion of the Metallization on the tissue can be ensured. A Apply a primer, as is often the case with the Technique is done to increase the adhesion to the fabric thus no longer necessary, so that a process step could be saved. This also has the advantage that important for the spreading effect of the camouflage net Surface structure of the base fabric directly on the Transfers metal layer. The surface structure of the carrier fabric is usually designed such that it for diffuse scattering of incident IR radiation, especially in the atmospheric window II (Wavelength range 3 - 5 µm). In which thereby an essentially decreasing reflectivity achievable in the atmospheric window II of the camouflage material is.

Polar are preferably used as carrier material Polymers selected. Polyester is characterized by its high mechanical strength is advantageous.

Furthermore, within the scope of the invention Procedures are found that in the step of Removal of web processing agents or additives and Surfactants must be taken care of after cleaning of the carrier fabric the gasoline-soluble proportion of surfactants is as small as possible about 0.20% and the water-soluble Share is below about 0.02%. A fact, which so far have received little or no attention Has. However, it must be observed when this is the case metallic material applied directly to the base fabric becomes, since at substantially higher values the Adhesion of the fabric with respect to the metal strong is affected.

Is in the method according to the invention Drying the fabric onto this the metal coating upset, so it turned out to be a lot with this step turned out positive if the application of the metal in the Vacuum takes place as the resultant The absence of dust particles is a guarantee that the Spectral behavior of the camouflage material not Contamination of the metal layer is adversely affected. In in this context it was also targeted for one Proven dosed application of the metal, the metal. from one metallic gas atmosphere out onto the carrier fabric evaporate. One so applied to the tissue carrier Metal layer is homogeneous and can be reproduced easily become.

One for the required multispectral Metal, for example, is a good camouflage behavior Aluminum. The surface resistance of the aluminum lies especially in areas where there is also a damping of Radar waves can take place. Depending on the wavelength the resistance of aluminum ranges between 30Ω and 300Ω. With respect to the camouflage material according to the invention can the resistance etc. also set by the layer thickness become. It is obvious to a person skilled in the art that of course other metals such as Silver and / or gold used can be. Combinations of the named metals are also conceivable.

When using the method according to the invention, it has been shown that metallization of the carrier fabric with a surface density of approximately 100 mg / m ² to approximately 200 mg / m ² or preferably approximately 130 mg / m ^{2 is} an essentially optimal result with regard to the spectral behavior the metal layer in the wavelength ranges in question, in particular in the infrared and in the radar wave range, can be guaranteed.

The application of the primer includes the application a polymer layer on the metallization of the Tissue carrier, so it is particularly advantageous if this has polar properties. It becomes an im Greatly improved adhesion to polyolefins on Metal is achieved and the camouflage material receives an additional one particularly high quality weather resistance, in particular the fabric metal layer polymer non-structure. The water-sensitive metal layer is so safe against Protected against moisture influences. By the big one Adhesion resistance of the layers is also high Resistance to mechanical stress is given.

The polymer is cross-linked, preferably partially cross-linked that this has an amorphous structure and the layer appears partially transparent, as it is for the natural environment in the IR is often the case. The Polymer layer continues to provide tissue consolidation sure, which ensures consistent structures and one good punchability to achieve a cut Garnish the camouflage material allows.

Flame retardants are preferably used in the polymer layer used. Are the appropriate Particles, such as with antimony trioxide or correspondingly suitable organic bromine compounds a distribution of the particle size, so in the polymer layer embedded in the primer that about 90% of the particles have a Have diameters of less than 5 microns, they have have very little impact on emissions and Reflection characteristics of the camouflage material or can this influence accordingly in the design of the layers consider. The amorphous structure and the Partial transparency of the polymer layer in the IR is due to the flame-retardant agents are only slightly disturbed.

Offer as a polar polymer for the polymer layer fully or partially crosslinked polyurethanes and / or polyacrylates, which adhere well to the Metal layer allow a homogeneous embedding of the allow flame retardants and as a primer for the subsequent camouflage layer serve.

To make the Tarnet according to the invention is not only in the primer to embed a flame retardant, but also suitable microbiocidal equipment. This mushroom and Bacterial protection preferably comprises a substance Isothiazolinone base. These are characterized by both high spectrum of activity as well as a good one Polymer compatibility. I.e. this also makes the amorphous character and partial transparency in the IR of the polymer not affected.

Furthermore, in the method according to the invention Another hydrolysis protection as part of the primer be applied, the the weather resistance of the existing camouflage material still improved. As a favorite Material has turned out to be carbodiimide, which through a good compatibility with the in the Features primer embedded polymer. Naturally other materials are also conceivable that are similar Have properties like the carbodiimide mentioned above.

With regard to the layers applied as part of the primer, it has proven advantageous in practice that the areal density of the primer is limited to essentially 15 to 16 g / m ² if the primer is followed by a green camouflage paint. In contrast, in the case of a subsequently olive-gray camouflage paint, it has proven useful if the areal density of the primer is preferably between 23 and 24 g / m ² . A possible higher layering of the primer would result in the 6dB attenuation in the radar range not being achieved.

An improved camouflage effect is achieved if that Carrier fabric is metallized on both sides and accordingly if the primer described and Painting is also done on both sides. In addition, thus realize a camouflage material that both in winter and can also be used in other seasons, because on the different sides a customized coating or painting is possible.

For the backing fabric there is a titer with 550 dtex and a plain weave 1/1 with a thread setting from the chain about 14.5 Fd / cm to a weft of about 12 Fd / cm with a thread twist of the chain of about 60 turns and one for a universal camouflage material Thread twist from 0 turns was found to be good when this fabric was coated with about 130 mg / m ² aluminum.

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

Fig. 1

eine schematische Darstellung eines Querschnitts eines erfindungsgemäßen Tarnnetzes

Fig. 2

eine stark schematisierte Darstellung des Querschnitts der erfindungsgemäßen Grundierung

The invention is described below using an exemplary embodiment and with reference to the accompanying drawings. The same parts have been given the same identification.
Show it:

Fig. 1

is a schematic representation of a cross section of a camouflage network 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 a preferred 1 is a woven base fabric 2 made of a polar polymer. With the preferred Embodiment is used to manufacture the universal camouflage material a carrier fabric made of polyester, which has a titer with 550 dtex and a plain weave 1/1 with a thread setting from warp 14.5 Fd / cm to weft 12.0 Fd / cm, with a chain twist of 60 Tours and a thread twist of the shot of 0 tours.

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

The vaporization of the carrier fabric is transferred 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.e. between 2.5 and 5 µm, on the incident steel, whereby the Radiation with an increasing wavelength shows essentially falling course.

In the preferred embodiment, aluminum with 130 mg / m ² 3 is used as the evaporation material. Due to this surface density, the resistance of the aluminum is adjusted in such a way that an essentially optimal damping of radar waves can be achieved.

A primer 4a or 4b is then applied to both sides in a manner known to those skilled in the art. On the top 4a, the primer comprises approximately 15.5 g / m ² and on the underside 4b approximately 23.5 g / m ² . The primer according to FIGS. 1 and 2 has a partially crosslinked polyurethane 6 on the metal layer 3. Antimony trioxide 7 and / or an organic bromine compound is embedded as a flame retardant in the amorphous and in the thermal IR windows II and III or in the frequency ranges between 2.5 and 5 µm and between 7 and 14 µm transparent polyurethane. The crystals have a size distribution such that approximately 90% of the particles have a maximum size of 5 μm. The polymer layer 6 serves as protection for the metal layer and as a carrier for the flame-retardant particles 7. In addition, a microbiocidal finish 8 for protection against fungal and bacterial attack is embedded in the polymer layer 7 of the primer. Furthermore, the primer comprises an additional hydrolysis protection 9 consisting of carbodiimide. The primer described acts as a primer for the subsequent camouflage painting. The camouflage paint applied to the primer 4a, 4b is a special camouflage paint from Schill + Seilacher. The camouflage paint is mainly used for camouflage in the visible area. In the embodiment shown in Fig. 1, a green summer paint 5a was applied on the top and an olive-gray winter color 5b on the bottom.

The camouflage material ranges from 2.5 µm to 4 µm essentially from about 0.9 to about 0.55 falling emission coefficients. This is what it is about is an averaged value that shows a spread of approx. ± 1.5. In the range between 4 and 7.5 µm, in which the Earth's atmosphere is opaque Emission coefficient either to its initial value again back or it reaches the value to which it then moves in Frequency range between 7.5 microns and 14 microns essentially remains constant. This value is around 0.8. A certain spread of the named values for the Experience has shown that emission coefficients cannot be excluded. However, this does not change anything principle emission behavior.

Finally, the ready-made material in a conventional manner by punching with a cut garnish provided, which Reflectivity or diffuse scattering for radar waves can still be improved.

Other embodiments of the invention Camouflage materials are easily manufactured in a similar manner. In a further preferred embodiment of the invention For example, a polyester is used as the polar carrier fabric used.

Also in connection with a changed Transmission / reflection behavior in the IR or radar range of the camouflage material shows the base fabric in others Embodiments of the invention preferably having a titer 550 dtex and a 1/1 plain weave with a Thread adjustment from warp between 11 to 16 Fd / cm to weft between 10 to 14 Fd / cm with one turn of the thread Chain between 0 to 120 turns and a thread turn of the Shot of 0 tours. The base 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. As antimony trioxide and / or flame retardant use organic bromine compounds. In this case, too is the distribution of the particle size such that preferably 90% of the particle sizes of maximum 5 µm have.

The camouflage material according to the invention has the big one Advantage on, depending on the specifications of its spectral behavior regarding emission, absorption and / or transmission due to different environmental conditions or the camouflaging objects to be variable in a wide range. So it’s easy for each application, for example for a winter or a summer camouflage optimal camouflage material, e.g. B. by varying the Fabric structure, the metal and its layer thickness and / or of the applied camouflage paint for the respective purpose Manufacture optimized camouflage material. The same applies to the Camouflage of objects that are compared to the environment have a higher temperature.

In some cases, it may also make sense to go on the move of further improved protection in certain Apply additional layers to spectral ranges.

Claims (19)

Process for producing a camouflage material for the visible spectrum, the near IR and the far IR and the radar wave spectrum, characterized by the process steps: a) providing a base fabric, b) removing weaving agents and surfactants from the base fabric and drying the base fabric, c) applying a metal layer to the carrier fabric, d) applying a primer and a camouflage paint on the metal layer. A method according to claim 1, characterized in that the fabric provided comprises a polar polymer. A method according to claim 1, characterized in that the base fabric comprises a polyester. The method of claim 1, 2 or 3, characterized characterized in that in the step of removing Woven processing agents and surfactants of the base fabric the gasoline soluble fraction to approximately below 0.20% and the water-soluble fraction to approximately below 0.02% is reduced. Method according to one of the preceding claims, characterized in that the step of applying a metal layer on the carrier fabric the step of Include vacuuming. Method according to one of the preceding claims, characterized in that the step of applying the metal layer the vapor deposition of the metal on the Carrier fabric includes. Method according to one of the preceding claims, characterized in that the step of applying the application of the metal layer preferably Aluminum or one in electrical conductivity comparable metal includes. Method according to one of the preceding claims, characterized in that in the step of applying the metal layer, the carrier fabric is coated with approximately 100 mg / m ² to approximately 200 mg / m ² or preferably with approximately 130 mg / m ² . Method according to one of the preceding claims, characterized in that the step of applying a primer is the application of a polar polymer for example a polyurethane or polyacrylate includes. Method according to one of the preceding claims, characterized in that the polymers of the primer preferably have full or partial crosslinking. Method according to one of the preceding claims, characterized in that the step of applying a primer on the metal layer the step of Applying a flame retardant, preferably antimony trioxide and / or an organic Bromine compound. Method according to one of the preceding claims, characterized in that the Flame retardant a particle size of preferably has about 5 µm. Method according to one of the preceding claims, characterized in that the step of applying a primer the step of applying one Microbiocidal equipment against preferably fungal and Bacterial attack includes. Method according to one of the preceding claims, characterized in that the step of applying a step of applying a primer Hydrolysis protection, preferably a polymer Carbodiimide base. Method according to one of the preceding claims, characterized in that the primer has a surface density of preferably approximately 15 to 16 g / m ² on a subsequent green camouflage side and preferably approximately 23 to 24 g / m ² on a subsequent olive gray camouflage side. Method according to one of the preceding claims, characterized in that the steps: Application of a metal layer on the carrier material and Apply a primer and camouflage paint to the metal layer on both sides of the carrier material. Camouflage material, in particular according to a method according to claim 1, comprising: a base fabric, a metal layer, a primer to cover the metal layer and a camouflage for the IR, characterized in that
the carrier fabric comprises a polar polymer. Camouflage net according to claim 17, characterized in that the carrier tissue has a titer with 550 dtex and one Plain weave 1/1 with a thread adjustment by chain between 11 to 16 Fd / cm, preferably 14.5 Fd / cm too Shot between 10 to 14 Fd / cm, preferably 12.0 Fd / cm with a twist of the chain between 0 to 120 tours, preferably 60 tours and one Thread rotation of the weft from 0 tours. Camouflage material according to claim 17 or 18, characterized characterized in that the camouflage material is a cut Garnish.

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