SE439402B - Use of metallised, textile surface products as a reflection medium for microwaves - Google Patents

Abstract

Use of metallised, textile surface products as a reflection medium for microwaves. Metallised, textile surface products of synthetic polymers or native fibres, on which precipitates a metal layer of wet chemical dead path, whose surface is particularly suited as a reflector for electromagnetic waves within the areas from 10MHz to 1,000 GHz. To stretched, metallised woven fabrics the reflective radiation is partially polarized, contributing to simplify and respectively raising the provability for an object by means of radar beams. Through periodic stretching and discharge of the woven fabric, modulation of the reflecting microwaves can also be attained.

Description

so019s9-1 2 by s.k. steaming. The surface resistance, measured according to DIN SUBHS at 23 ° C and 50% rF, is then of the order of about or below 1 - 10% 11 .. It was surprising that also layer thicknesses in the range of skin thickness, ie. the thickness of the surface-conducting layer still exhibits a high reflectivity, which should be related to the textile substrate. In the case of nickel layers, for example, the thickness of the surface-conducting layer (skin thickness) at 3 cHz is 0.27 .mu.m, and 9 GHz is 0.16 .mu.m.

The improved observability of even smaller objects, the surface of which is at least partially coated with metallized textile surface products, increases safety, especially in shipping, aviation and in the rescue service.

A special advantage of the use according to the invention is the low weight and flexibility of the material.

It can be attached to uneven surfaces and can be cut to any size. The material is so light that the total weight hardly changes due to the additional applied material. It is a new technical method to increase the reflection ratio of a non-metallic object for radar beams. The durability of the electrolessly applied layer is also higher than one would expect for a vapor-deposited metal layer. In addition, it is possible to further protect the metal layers by means of an extra protective layer, e.g. by varnishing, laminating or coating. Within a range of between 0.02 and 1,000 GHz, ie within a much larger range than just the "classic" radar radiation, the reflectivity is very high.

The textile surface fabric can consist of cotton, polyacrylonitrile, polyamide, aramid, polyester, viscose, modacrylic, polyolefin, polyurethane, PVC, alone or even in various combinations. The electrolessly applied metal layer preferably consists of nickel, cobalt, copper, silver, gold, even in combinations or as an alloy.

The mesh size and the intersection points of the warp gs and weft threads of tissues, respectively, should be less than half the wavelength of the radiation to be reflected. Preferably _A a textile surface article is used, in which the mesh size does not exceed one tenth of the wavelength. The reflection is also dependent on the shape of the textile construction. One therefore chooses the most possible isotropic textile construction, if the reflection is to be isotropic. On the other hand, by tensioning a loose, coarse-meshed textile surface, it is possible to achieve that the microwave rays after the reflection are partially polarized, if non-polarized radiation occurs, or also with linearly polarized, striking radiation the reflection is particularly high, if the mechanical stress and the electric field force vector is perpendicular to each other.

The invention is illustrated in the following by way of example.

Example 1 * - A 100% polyacrylonitrile filament yarn fabric had the following textile construction: »Warp and weft: 258 dtex (effective) of dtex 220 f 96 Z150, 1 58.5 warp threads / cm and 27 weft threads / cm Binding: twill 2/2 Weight: 155 5 / mg.

A colloidal palladium solution according to DE-AS 1 197 720 was immersed at room temperature in a hydrochloric acid bath (pH 2 l).

After a residence time during light movement of the textile product for about 2 minutes, the product was taken out of the bath and rinsed with water at room temperature. The material was then introduced for about 1.5 minutes in a 5% sodium hydroxide solution at room temperature. It was then rinsed at room temperature with water for about 50 seconds and then the material was introduced at room temperature into a solution consisting of 0.2 mol / liter of nickel II chloride, 0.9 mol / liter of ammonium hydroxide, 0.2 mol / liter of sodium hypophosphite, in which so much ammonia was introduced that the pH at 20 ° C amounted to about 9.4. After only 10 seconds, the sample began to darken during nickel precipitation. After 20 seconds, the sample floated upwards during hydrogen evolution and was already completely covered with nickel.

The sample was stored for about 20 minutes in the metal salt bath, taken up, rinsed and dried.

During these 20 minutes the sample (dry weight 7.2 g) had taken up about 5.1 g, i.e. about 40% by weight of nickel metal.

The rapid activatability and the high metal precipitation at room temperature were surprising. The nickel layer thickness on the fiber surface was 0.77 .mu.m.

According to this described process, different thick layers of key coatings were prepared with '8ÛÛ1939-1. textile surface products and the reflection losses between 2 and 25 GHz were measured. The measurement process has been described, for example, in H. Groll: "Mikr0wellenmesstechnik", F. Vieweg & Sohn, Braunschweig, 1969, p. 555 ff, The reflection loss is stated in dB. To eliminate the effect of standing_waves within the area of the measuring object (interface reflection), a broadband frequency modulated radiation with a constant effect is used, e.g. 1.9 ~ 2.4 GHz, 7 - 8 GHz.

Nickel layer thickness Frequency range in GHz i / um 1.9-2.4 748_ 11-12 22-24.8 0.08 2.9 2.6 _ 2.2 5.2 0.10 2.4 2.4 2, 2 2.7 0.15 1.9 2.0 2.0 2.9 01/19 '115. 115' H5 291 0.29 1.1 1.4 _ 1.4 ~ 1.9 0.58 1 .0 1.5 1.5 1.8 0.79 '0.7' 1.1 0.9 2.5 Example 2 Reflection losses of metallised textile surface products in dB with obliquely incident radiation.

The textile surface fabrics were the same as in Example 1. As in Example 1, they were coated with nickel. The angle of incidence was 50 °.

Nickel layer thickness Frequency range in GHz i / um 7-8 -11-12 0.08. 1.0 I 1.2 .0, 10 1.5 1.1 0.15 ~ 1.1 1.02 0.19 0.4 0.4 0.29 0.4 0.4 0.58 0, 1 0.1 Example 5 A coarse spunbonded fabric of polyacrylonitrile-spun fibers in linen wall binding with a large distance between the intersection points between warp and weft threads (1.5 mm spacing between the two warp and weft threads; 50.4 warp threads / 10 cm, 42.2 weft threads / 10 cm, L 1/1) showed a decrease 1,: 8001939-1 5 of the reflectivity with increasing frequency.

Nickel layer thickness Frequency range in GHz i / um - 1.7-2.4 7 ~ 8 11-12 25-24.5 0.2 0.7 ~ 1.0 1.2 5.2 0.78 0.5 0, 9 1.1 2.4 In order to obtain good reflection at short wavelengths, dense tissues were therefore required.

Example 4 Combination of two metal layers.

A textile surface product of Example 1 was coated as indicated in Example 1 with a 0.2 .mu.m thick nickel coating. The product was introduced after rinsing in a still wet state into a gold cyanide bath at 78 ° C. The gold bath based on potassium gold cyanide was adjusted to a gold content of 4 g / l by means of ammonia at a pH of 10.5. After 20 seconds, a shiny metal film had precipitated on the shiny nickel layer. Within 5 minutes, the gold layer thickness on the nickel-plated surface was 0.2 .mu.m. The reflection losses in dB at perpendicularly incident radiation are shown in the table below.

Layer thickness in / μm Frequency range in GHz 1.7-2.4 23-24.5 0.2 Ni + 0.58 Au 0.5 0.8 Example 2 The degree of reflection depends on mechanical stresses.

A linear polarized microwave radiation was allowed to fall perpendicular to a knitting of an acrylonitrile copolymer on which a 0.75 .mu.m thick nickel layer was deposited. Row II in the table below indicates the reflection losses in dB, as the knitting is not subjected to any mechanical stress. Below the line I, the losses when applying a tensile stress (stress direction parallel to the E-vector) are indicated.

Frequency range in GHz 1l7-2.4 7-8 11-12 25-24 ,; I 0.9 0.8. 1, 5 5 11: 2 1, 5 2,6 6 pPOR QUALITY 8001959-1 e A periodic variation of the tensile stress leads to a periodic variation of the reflected microwave intensity. Thereby, the detection of an object sought by means of radar can be significantly improved within an isotropic or at least at the time constantly reflective environment (emergency rescue service, friend / enemy detection, etc.). One either starts from a linearly polarized radiation and evaluates the intensity variation of the reflector or one uses circularly polarized radar radiation, the reflected signal showing a periodic variation of the ellipticity of the polarization, which can be detected by means of an analyzer on the receiver side. Example 6 '7 A polyethylene paper, i.e. a fibrous web of polyolefin staple fibers, was coated with an electroless precipitated nickel layer as described above.

For a 0.47 μm thick nickel layer, the following reflection losses in dB were detected: Frequency range in GHz 7-8 '11-12 1.5 0.9 This metallised, textile surface product was particularly suitable as a distinguishing material, e.g. as an identification mark for observations from reconnaissance helicopters. Due to its light weight, the material can be easily carried on expeditions.

Example 2 A polyester-cotton blend fabric, consisting of 65% by weight of polyester staple fibers based on polyethylene terephthalate and 55% by weight of cotton, showed with a 0 μm thick nickel layer the reflection losses in dB indicated below.

Frequency range in GHz 1.7-2.4 7-8 11-12 0.7 - 0.7 0.7 a This metallised material is suitable for tents, backpacks or clothing for skiers and hikers.

The tissue has only become slightly heavier due to the metallization. It has not lost its textile elastic properties. 8001959-1 7 If you cover the dai with a soft PVC layer in order to make it rainproof, it can also be provided with warning colors. Persons carrying such backpacks or clothing details can be detected by radar devices if they have disappeared in uninhabited areas or on the tundra.

Example gel 8 I A balloon fabric, eg L from a polyester filament yarn fabric or ny10nf6.6 ~ fabric, is coated with an approximately 0.7 .mu.m thick, electrolessly applied nickel layer. In addition, the fabric is given a protective coating of PVC, rubber or polyurethane varnish. This retrofitting does not interfere with the reflectivity of the surface. Row I in the table below shows the reflection losses í_dB for such a fabric, which has been provided with only a 0.7 .mu.m thick layer of nickel. Line II indicates the losses in the event of a further rubberization.

Frequency range in GHz 1.9-2.4 7-a 11-12 22-24.5 I 0.6 1.2 0.7 1.6: I 0.7 1.2 0.8 1.6 A free balloon , which is made from such material, can be easily located by means of the radar of a commercial aircraft.

In tissue construction, glider can also be embedded as the last layer in polyester resin, which means radar locatability for gliders. 'Exemgel Q Use of metallised, laminated tissues in the emergency services. A polyamide or polyester filament yarn fabric is provided with a 0.65 micron thick non-woven fabric. On sale I in the table below, the reflection losses are given in dB. By laminating with a PVC coating (row II) or with a polyethylene coating (row III), the reflectivity of the metallised fabric practically does not change.

Frequency range in GHz 1.8-2.4 7-a 11-12 I 0.5 0.8 0.8 11 0.5 0.5 0.8: II 0.5 0.5 0.9 more, answer n- ... Na aue1939-1 8.

From this metallized fabric, it is advantageous to produce life jackets, which can also be provided with the prescribed warning color BAL 2002. The fabric can also be applied to rescue platforms. If the fabric is applied to the mast tops of sailboats, these can be more easily located by radar without the sailboats being loaded. "_ A further advantage of the metallized textile surface products is that they can be electrically heated. '54

Claims (7)

8001939-1 Patent claims Use of metallised textile surface products of synthetic polymers or native fibers, the metal after activation of the textile surface layer being applied to it chemically and electrolessly with a total metal layer thickness of between 0,02 and 2,5 .mu.m, as reflective materials for microwave and high frequency radiation in the range 0.01 - 1 000 GHz. Use according to claim 1 of metallised textile surface products as reflectors for radar waves in aircraft, land 3. FOPGOH and seagoing vessels or devices. _. Use of metallized textile surface articles according to claims 1 and 2, characterized in that the surface metal has a mesh size of less than one tenth of the wavelength of the radiation to be reflected. _ Use of metallized, textile surface products according to claims 1 - 5, characterized in that the surface metal has an additional galvanically applied metal layer. Use of metallized textile surface articles according to claims 1 - 4, characterized in that the textile surface article has a protective layer. Use of metallized textile surface articles according to claims 1 - 5 as reflectors, wherein the degree of polarization of the reflected radiation is changed by stretching in one or two axis directions of the textile surface article. Use of metallized textile surface products according to claim 6 as variable reflectors, wherein the mechanical stretching is time-dependent. 'mosquito QUALITY