FR2716577A1 - Material, e.g. paint, for reducing radar wave reflection - Google Patents

Abstract

A material (I) for reducing reflection of radar waves consists of several alternating layers of (a) a first type contg. magnetic particles in a polymeric binder; and (b) a second type contg. non-magnetic, non-metallic highly electrically conductive particles in a polymeric binder. The binder in at least one (pref. both) of (a) and (b) is also charged, with hollow microspheres (HMS) of glass or synthetic resin, having dia. below 200 microns. Also claimed is a paint (II) for applying a coating of (I) to a support, contg. a solvent for the polymeric binder which forms part of the compsn. of the partic. layer (a) or (b).

Description

Materials and paints intended to reduce the reflection of waves
radar.

DESCRIPTION
The present invention relates to materials and paints intended to reduce the reflection of radar waves.

 The technical sector of the invention is that of the construction of military vehicles.

 The manufacturers of military vehicles strive to reduce the radar signature of these vehicles, that is to say the radar echo by reducing their radar equivalent surface (SER).

 The radar equivalent surface is very important in the case of military vehicles such as ships, aircraft or tanks whose dimensions are much greater than the wavelengths emitted by the radar which are generally of the order of a centimeter.

 The radar equivalent surface of an object depends on its shape, and the materials of which it is composed.

 Shapes with sharp edges, discontinuities, flat surfaces or slight curvature increase the radar equivalent surface and manufacturers try to choose fleeting or rounded shapes to reduce the radar equivalent surface.

 Another way to reduce the radar equivalent surface is to use materials which reduce the reflection of radar waves by absorbing part of their energy.

 In this way, parts of devices have been protected by bonding absorbent materials which effectively reduce the reflection of radar waves, but which are expensive, dense and have a high thickness, which increases the weight and size of the devices.

 In addition, the performance of the materials used to date may decrease during aging, especially in a marine atmosphere.

 Another possibility for reducing radar echo is to coat the reflective surfaces with one or more layers of paints which absorb radar waves.

 This solution is attractive because it makes it possible to reduce the equivalent radar surface, without greatly increasing the weight and the bulk.

 To date, several paints containing absorbent fillers have been proposed and tested, but the performance of these paints is limited and their implementation is often difficult and expensive.

 The objective of the present invention is to provide materials which can be used either as a paint producing, after drying, a coating reducing the radar echo of the structures to which this coating is applied, or as constituents of certain parts of the structures themselves. .

 The object of the invention is achieved by means of materials which reduce the reflection of radar waves and which are composed of several layers alternately belonging to a first category comprising a polymeric binder loaded with magnetic particles and to a second category comprising a polymeric binder charged with non-magnetic, non-metallic, non-metallic conductive particles and the polymeric binder of at least one of the two categories is additionally charged with hollow microspheres of glass or synthetic resin having a diameter less than 200 μm.

 Advantageously, the layers of the two categories include a charge of hollow glass or synthetic resin microspheres.

 According to a preferred embodiment, the layers of the first category comprise a polymeric binder loaded with particles of ferrite or particles of a magnetic metal, such as iron, nickel, cobalt or chromium or particles of a ferromagnetic alloy.

 According to a preferred embodiment, the layers of the second category comprise a polymeric binder loaded with electrically conductive carbon particles or graphite.

 The materials according to the invention may consist of layers of paint alternately belonging to the first category and to the second category. In this case, the ready-to-apply paint also contains a solvent for the polymeric binder.

 The proportion of the polymeric binder entering into the composition of the two categories of layers can vary between 10% and 99% of the total weight and the proportion of filler can vary between 1% and 90% of the total weight of the dry material, after evaporation of the possible solvent. .

 The polymeric binder is preferably a mixture of one or more polymerizable synthetic resins and hardeners incorporated at the time of use.

 The polymerizable resin is, for example, elastomeric or hard polyurethane, polyetheramine, an epoxy resin, or acrylic, or polyester and, more generally, any synthetic resin or any mixture of polymerizable synthetic resins, in the presence of a catalyst or a hardener, which resins can be reinforced with fibers, for example glass or carbon fibers, if they are to be used to construct parts of stress-resistant structures.

 Thus, parts of vehicle structures can be constructed, for example the edges of airplane wings or parts of ship superstructures, from a material according to the invention composed of alternating layers of polymerized resin alternately charged with magnetic particles and non-metallic, non-metallic particles that are good conductors of electricity.

 The materials according to the invention can also be used in the form of coatings comprising several layers of alternating paints. In this case to make the layers sufficiently fluid to be applied by brush, roller or spray gun, the formulation contains a solvent for the polymeric binder which evaporates later. The solvent used can be any usual solvent for paints, for example an aromatic or ketonic solvent, depending on the nature of the binder which can also be presented in the form of an aqueous emulsion.

 The proportion of solvent can be between 0% and 70% of the total weight.

 In the case where the polymerizable binder is sufficiently fluid, it is possible to apply coating layers comprising no solvent.

 The layers of material of at least one of the two categories defined above additionally comprise a filler composed of hollow microspheres made of glass or synthetic resin, having a diameter of less than 200 μm. The proportion of microspheres is between 1% and 50% of the total weight of the layer.

 The layers of material of each category therefore comprise two essential components which are the polymeric binder and the specific charge thereof and an optional component which is the solvent.

 The layers of the first category include a filler comprising magnetic particles.

 According to a preferred embodiment, these magnetic particles are made of a soft magnetic material, preferably ferrite or a ferromagnetic alloy. It is also possible to use particles made of a hard magnetic material.

It will be recalled that the ferrites are compounds of iron oxide and of an oxide of a bivalent metal M corresponding to the general formula
MO.Fe203.

 It is possible, for example, to use particles of an alkaline earth metal (calcium, barium, strontium) or of a bivalent metal (iron, nickel, cobalt, zinc, manganese, magnesium, copper) or any other known ferrite or mixed particles of several of these ferrites.

 As a variant, the magnetic charge can be composed of ferromagnetic metallic particles (iron, steel, nickel, cobalt, chromium) or of an alloy having magnetic properties such as alloys Fe-Ni, Fe-Co, Fe-Si or alloys containing samarium.

 The magnetic charge can be composed of a mixture of ferrites and magnetic metallic particles.

 In the case where the layers of the first category only contain a binder and a magnetic charge, the proportion of magnetic charge can vary between 1% and 90% of the total weight. This proportion can drop below 1% in the case of a paint which contains a high proportion of microspheres and a solvent.

 The layers of the second category include a filler composed of non-magnetic, non-metallic particles with good electrical conductivity.

 According to a preferred embodiment, electrically conductive carbon black particles are used, or black or silver graphite particles.

 The proportion by weight of the filler is between 1% and 90% in the case where the second layer only comprises a filler of particles and a polymeric binder. This proportion can drop below 1%, in the case of a paint which also contains microspheres and a solvent.

 The materials according to the invention comprise at least two superimposed layers belonging to one of the first category and the other to the second category.

 Advantageously, they have a higher number of layers, for example six layers.

 It is not necessary that the successive layers be in direct contact.

 A layer transparent to radar waves can be inserted between two layers of different category, for example a layer of synthetic resin comprising no charge.

 The materials according to the invention can be used as paints which are applied to parts of the structure of a machine to reduce the radar echo reflected by these parts of the structure or by internal parts of the machine.

 They can also be used in the construction of certain parts of the structure, in particular the parts which can be constructed from laminated synthetic resins.

 The materials according to the invention can also be used in the form of plates or films which can be glued or fixed by any other means to parts of a machine whose radar equivalent surface is to be reduced.

 The hollow microspheres of glass or synthetic resin which are included in the layers of at least one of the categories of layers composing the materials according to the invention have the double function of creating heterogeneities in the structure of the material, allowing the penetration of waves radar, then dispersing in all directions, in synergy with the charged particles, the radar waves which strike them, resulting in a net reduction of the radar echo picked up in a determined direction.

 In addition, these hollow microspheres have a low density and make it possible to reduce the density of the dry material despite the presence in it of magnetic particles having a high density, which has the advantage of being able to apply on a support of relatively thick coatings, without resulting in excessive coating weights.

 The following numerical examples show that coatings having a density of the order of 1.1 to 1.2 g / cm 3 are thus obtained, despite the presence in them of magnetic particle charges of the order from 40 to 50% of the total weight of the fresh paint, thanks to the presence of hollow glass microspheres in proportion of the order of 5 to 10% of the total weight.

Compared with the materials already used to reduce radar echo, the materials according to the invention have the following advantages
They are easy to apply as a coating on any vertical, horizontal or complex surface, without any sagging.

The cost of the raw materials used is relatively low.

 The density and therefore the weight of the coating per unit area are low.

 The coatings and materials according to the invention resist corrosive atmospheres, in particular the marine environment.

 The thickness and therefore the absorption performance of the radar waves can be modulated as a function of the radar brightness of the shapes.

 The drying is rapid at room temperature and the maintenance of the materials according to the invention is easy.

 The coatings and materials according to the invention are compatible with any top coat which can be applied to the coating or to the material in order to obtain a determined appearance, color or surface finish.

 By way of example without any limiting character, the following are indicated, layer compositions which have been produced and tested in the laboratory.

 - Layers of the first category containing a load of magnetic pigments applicable as paint.

 Example NO. 1.

 Composition Proportion by weight a) Polymer binder and hardener.

- Little branched polyester resin: 3.7%
- Branched polyester resin: 15.0%
- Esteramine catalyst: 0.3%
- Aromatic polyisocyanate: 9.3% b) Pigment and filler.

- Calcium ferrite: 41.9%
- Glass microspheres: 5.6% c) Solvent and diluent.

- Toluene: 24.2%
Dry extract by weight of the mixture: 72.71%
100.0% Density of dry material: 1.27 G / cm3
Example NO. 2
Components. Proportion by weight a) Polymer binder and hardener
- Branched polyester resin: 26.72
- Little branched polyester resin: 6.6%
- Aromatic polyisocyanate: 16.7 X b) Pigments and fillers
- nickel powder: 31.7%
- glass microspheres: 7.4% c) solvent and diluent
- toluene: 10.9%
TOTAL: 100.0%
Dry extract by weight of mixture: 83.58%
Density of dry material: 1.14 g / cm3
EXAMPLE NO. 3 Proportion by weight
Components a) Polymerized binder and hardener
- branched polyester: 26.67%
- slightly branched polyester: 6.66%
- aromatic polyisocyanate in solution: 16.7% b) pigments and fillers
- chromium powder: 31.67%
- glass microspheres: 7.5r c) solvent and diluent
- toluene: lo, 8Z
100.00%
Dry extract by weight of the mixture: 83.67%
Density of dry material: 1.13 g / cm3
EXAMPLE NO. 4
Components Proportion by weight a) Polymer binder and hardener
- slightly branched polyester: 3.2%
-branched polyester: 12.5%
- esteramine catalyst: 0.3%
- aromatic polyisocyanate in solution: 7.7% b) pigment and fillers
- zinc ferrite: 47.2%
- glass microspheres: 8.9% c) solvent and diluent
- toluene: 20.2X
100.00%
Dry extract by weight of the mixture: 77.22
Density of dry material: 1.16 g / ci3
EXAMPLE NO. 5
Components Proportion by weight a) Polymer binder and hardener
- slightly branched polyester: 3.20%
- branched polyester: 13.00
- esteramine catalyst: 0.25%
- aromatic polyisocyanate in solution: 8.10 X b) Pigments and fillers
- zinc ferrite: 49.45%
- glass microspheres: 4.75% c) solvent and diluent
- toluene: 21.25%
100.00%
Dry extract: 76.14%
Density of dry material: 1.55
EXAMPLE NO. 6
Components Proportion by weight a) Polymer binder and hardener
- slightly branched polyester: 3.8%
- branched polyester: 15.4%
- esteramine catalyst: 0.3%
- aromatic polyisocyanate in solution: 9.6% b) Pigments and fillers
- calcium ferrite: 43.12
- glass microsphere: 2.9% c) solvent and diluent
- toluene: 24.9% 100.00
Dry extract by weight of the mixture: 7, fox
Density of dry material: 1.56.

 In the six paint examples described above, the aromatic polyisocyanate serves as a hardener and is mixed just before the paint is applied to a support.

 Examples of composition of layers of the second category containing a charge of non-magnetic particles conducting electricity.

EXAMPLE NO. 7
Components Proportion by weight a) Polymer binder and hardener
- epoxy resin in 80% solution 30.8%
in xylene.

- aromatic polyamine (hardener): 15.4Z b) pigments and fillers
- conductive carbon black: 7.7X
- glass microspheres: 7.6% c) Solvent and diluent
- methyl isobutyl ketone: 38.52 100.00%
Dry extract by weight of the mixture: 55,352
Density of dry material: 0.78
EXAMPLE NO. 8
Components Proportion by weight a) Polymer binder and hardener
- epoxy resin in 80% solution
in xylene .: 40.3%
- aromatic polyamine (hardener): 20.2% b) Pigments and fillers
- black graphite: 10.6%
- silver graphite: 6.7
- glass microspheres: 3.75% c) Solvent and diluent
- methyl isobutyl ketone 18,451
100.00%
Dry extract by weight of the mixture: 73.50X
Density of dry material: 1.06%
EXAMPLE NO. 9
Components Proportion by weight a) polymer binder and hardener
- semi solid epoxy resin in
80% solution in xylene 32.0%
- aromatic polyamine (hardener): 16.0% b) Pigments and fillers
- conductive carbon black:
- glass microspheres: 3.9% c) Solvent and diluent
- Methyl isobutyl ketone: 40.1%
100.0%
Dry extract by weight of the mixture: 50.89%
Density of dry material: 0.93
EXAMPLE NO. 10
Components Proportion by weight a) Polymer binder and hardener
- semi-solid epoxy resin
80% solution in
xylene 38.9%
- aromatic polyamine (hardener) 9.5% b) Pigments and fillers
- black graphite: 10.1%
- silver graphite: 6.5%
- glass microspheres 7.2% c) Solvent and diluent
- methyl isobutyl ketone: 17.8% 100.0%
Dry extract by weight of the mixture: 74.43%
Density of dry material: 0.90%
In Examples 7 to 10, the aromatic polyamine which serves as a hardener is introduced into the mixture before the paint is applied to its support.

 Tests have been carried out in the laboratory to compare the intensity of the radar echo returned respectively by an uncoated steel target and by the same target coated with six coats of paint, alternately of the first and second categories defined above. .

 The target used was a steel plate of 500 X 500 X 3 mm.

 The radar waves were sent to the target at normal incidence, that is to say with an angle of incidence with the normal to the plate less than 10.

 The six layers of paint were each 170 Cun thick.

 The first, third and fifth layers starting from the support were magnetic layers having the composition corresponding to example NO.1 above.

 The second, fourth and sixth layers had a composition corresponding to example NO. 7 described above.

 Four successive measurements were made for each of the radar frequencies.

 The average of the measurements corresponding to each frequency is indicated below.

 The result is indicated in decibels.

 It is recalled that an attenuation of 20 db corresponds approximately to a division by 100 of the equivalent radar surface.

Transmission frequency Attenuation measured
(average of 4 measures)
12 CHz - 15 dB
14 GHz - 17.3 dB
15 GHz - 17.1 dB
16 GHz - 19.6 dB
18 0Hz - 22.5 dB.

 These tests show that one obtains in the KU band between 12 and 18 GHz, an attenuation of the radar echo greater than 15 dB.

Claims (14)

 1. Material intended to reduce the reflection of radar waves, characterized in that it is composed of several layers alternately belonging to a first category comprising a polymeric binder loaded with magnetic particles and to a second category comprising a polymeric binder loaded with non-magnetic particles , good conductors of electricity and not metallic and in that the polymeric binder of the layers belonging to at least one of the two categories is loaded with hollow glass or synthetic resin microspheres having a diameter less than 200 μm.  2. Material according to claim 1, characterized in that the polymeric binder of the layers belonging to each of the two categories is loaded with hollow microspheres of glass or synthetic resin.  3. Material according to any one of claims 1 and 2, characterized in that the layers of the first category comprise a polymeric binder loaded with ferrite particles.  4. Material according to any one of claims 1 and 2, characterized in that the layers of the first category comprise a polymeric binder loaded with ferromagnetic metal particles or in or of metal alloys.  5. Material according to claim 4, characterized in that the layers of the first category comprise a polymeric binder charged with particles of a metal taken from the iron, nickel, cobalt and chromium group  6. Material according to any one of claims 1 and 2, characterized in that the layers of the first category comprise a polymeric binder loaded with a mixture of ferrite particles and ferromagnetic metallic particles or particles of ferromagnetic metallic alloys or hard magnetic.  7. Material according to any one of claims 1 and 2, characterized in that the layers of the second category comprise a polymeric binder loaded with particles of graphite or carbon black electrically conductive.  8. Material according to any one of claims 1 to 7, characterized in that the proportion of polymeric binder is between 10% and 99% of the total weight of each layer of dry material and the proportion of filler is between 1% and 90% of the total weight of each layer of dry material.  9. Material according to any one of claims 1 to 7, characterized in that the proportion of glass microspheres or synthetic resin in the layers of at least one of the two categories of layers is between 1% and 50% the total weight of said layers of dry material.  10. Paint intended to apply a coating to supports according to any one of claims 1 to 9, characterized in that it also comprises, for each layer, a solvent for the polymeric binder used in the composition of said layer.  11. Paint according to claim 10, intended to obtain, after drying, layers of the first category, characterized in that it comprises  - a synthetic resin which can be polymerized with a hardener, all in proportion between 10% and 70% of the total weight;  - a compound load  on the one hand, ferrite particles or a powder of a magnetic metal in a proportion of between 10% and 50% of the total weight:  on the other hand, glass microspheres in proportion between 1X and 50% of the tdtal weight;  - And a solvent of the synthetic resin in proportion between 10% and 70% of the total weight.  12. Paint according to claim 11, characterized in that said ferrite is a calcium or zinc ferrite.  13. Paint according to claim 11, characterized in that said magnetic metal is iron, nickel. cobalt or chromium.  14. Paint according to claim 10 intended to obtain after drying of the layers of the second category, characterized in that it comprises  - a synthetic resin polymerizable with a hardener, the whole in proportion between 10% and 70% of the total weight;  - a compound load  on the one hand, electrically conductive carbon black particles or graphite in a proportion of between 5% and 30% of the total weight;  on the other hand, glass microspheres in a proportion of between 1% and 50% of the total weight;  - And a solvent for said polymerizable resin in a proportion of between 10% and 70% of the total weight.