EP1950835A2 - Radiation filter - Google Patents

Abstract

The radiation filter has an elastic base layer (12) and an elastic facing layer (20), which are spaced and connected by a spacing element (18). A hollow space (22) is formed between the base layer and the facing layer through the spacing element. The elastic base layer has two layer coats (12a,12b) having different relative dielectric constants.

Description

The invention relates to a radiation filter according to the preamble of claim 1.

Such a radiation filter serves, for example, to attenuate the IR radiation from an object, such as a vehicle, ship or stationary device, which may be e.g. is a building, a crew shelter or the like. The vehicle may be a military vehicle such as a crew car, an armored vehicle or the like.

Vehicles, ships and stationary facilities or other objects are characterized by their entire or group-specific heat radiation from the background clearly and are therefore easy to understand with heat seeker heads.

In order to reduce such depreciation of the heat radiation from the surrounding background and the view with heat seekers, IR radiation filters, i. IR attenuators, known in semi-hard and hard training, which are attached to the respective object, i. be attached to the respective vehicle, ship or to the respective stationary device. These known IR damping elements are not elastic, so that they can not be optimally adapted to the outer contours of the respective, its IR radiation-absorbing object. In addition, these known semi-hard or hard IR damping elements have an at least partially open-pore surface, so that they are not permanently fit for the fight.

Similarly, radiation filters are known, which are intended for the absorption of radar beams. The radar radiation impinging on the radiation filter hereby becomes heat in accordance with the absorption properties of the radar radiation filter transformed. However, this heat development is in contrast to the above-mentioned desired attenuation of the IR radiation from the respective object in contrast. That is, a desired radar beam absorption and a desired attenuation of the IR radiation are contrary to each other, ie they actually contradict each other.

The invention is nevertheless based on the object to provide a radiation filter of the type mentioned, with which good attenuation and absorption properties both with respect to radar and with respect to attenuation of the IR radiation are achieved, and which is easily adaptable to the contour of the respective object ,

This object is achieved by the features of claim 1. Preferred embodiments or further developments of the radiation filter according to the invention are characterized in the subclaims.

It is particularly advantageous in the radiation filter according to the invention to form this on its surface layer with a closed-pore, structured outer surface. It is expedient if the structured outer surface is formed as a generally rounded nub surface, wherein the nubs have different dimensions - both in cross-section and in height - and are provided distributed irregularly. Such a design has the advantage that the marking of the object provided with a radiation filter according to the invention in relation to the environment, i. with respect to the background of the object, only has a relatively small temperature difference, for example, 5 ° Celsius or less.

The formation of the radiation filter according to the invention with a surface layer of a permanently elastic material, in particular a driven, foamed permanently elastic material with a closed-pore outer surface results in a radiation filter with a durable surface, as required, for example, for military applications.

It may be expedient if the outer surface of the radiation filter according to the invention, ie its surface layer, is colored for optical camouflage, so that a corresponding camouflage effect results from optical surface tearing. The camouflage effect is particularly advantageous due to a surface tear in the IR imaging of the object provided with the radiation filter according to the invention.

By virtue of the fact that the at least two layers of the base layer and the surface layer spaced from the base layer by the spacer elements and connected to it are made of elastic materials, it is advantageous to adapt the radiation filter to the contour of the respective object in an advantageous manner Vehicle, ship or a stationary device can act, possible.

By the formation of the radiation filter according to the invention with a closed-cell outer surface, for example, with differently sized and irregularly distributed, all-round rounded knobs of a driven permanently elastic material in the respective desired color so - as already mentioned - are advantageously both optical Tarneffekte and the desired thermal damping effects - both generated by the object IR radiation as well as generated by incident on the object radar radiation generated IR radiation - and combined with each other. The desired thermal damping is provided by the void between the at least two layered elastic base layer and the elastic surface layer, i. reinforced by the located in said cavity air layer under the driven surface layer in an advantageous manner.

The said layers consist for example of chloroprene rubber, halogenated butyl rubber or butyl rubber. The surface layer forming a scavenger layer for radar rays is expediently made of propelled halogen-butyl rubber of the mixture designation GWB 9269.

The air layer is determined by the spacers of the base layer and the connection system in their thickness.

Radiation filters according to the invention are permanently elastic, walkable, hard-wearing and, if necessary, decontaminable.

The thickness of the layer layers of the base layer is, for example, 1 to 3 mm, it being understood that the said layer layers can also be dimensioned with different thicknesses.

The thickness of the surface layer forming a scavenger layer for radar rays is preferably> 1 mm.

The layers of the base layer are firmly connected to each other over a large area. This compound may be a vulcanization or an adhesive bond.

The layer layers of the base layer have mutually different relative dielectric constants. It has proved to be advantageous in this case if the dielectric constants of the layer layers of the base layer in the direction pointing away from the surface layer become larger in each case.

The thicknesses of the layer layers of the base layer are determined by the frequency of the radar radiation to be damped. According to the invention, a basic attenuation of> 10 dB is achieved in the frequency range from 8.2 to 12.4 GHz, 26.5 to 40 GHz and 90 to 100 GHz. Absorption peaks of> 20 dB are at the frequencies 10 GHz, 35 GHz and 94 GHz. Thus, about a halving of the reconnaissance depth is achieved by enemy radar. The thickness of the respective layer layer of the base layer is an odd multiple of the fourth part of the wavelength of the radar radiation, i. the said thickness d = (2n + 1) • Λ / 4, where Λ is the wavelength and n is an arbitrary integer.

Further details, features and advantages will become apparent from the following description of two illustrated in the drawings embodiments of the radiation filter according to the invention.

Show it:

FIG. 1

in a sectional view a portion of a design of the radiation filter,

FIG. 2

a section of the radiation filter according to FIG. 1 in the direction of arrow II,

FIG. 3

a section along the section line III-III in FIG. 1 through the radiation filter,

FIG. 4

in sections in a longitudinal section - similar to the FIG. 1 - another training of the radiation filter, and

FIG. 5

a section along the section line VV in FIG. 4 ,

FIG. 1 illustrates sections of a sectional view of an embodiment of the radiation filter 10, which is used to attenuate the IR radiation from an object, such as a vehicle, ship or a stationary device, as well as for the absorption of incident on the object radar beams is provided. The radiation filter 10 has an elastic base layer 12, with which it rests against the object to be damped with its base 14.

The base layer 12 consists of at least two layer layers 12a and 12b, which are firmly connected to one another in a material-locking manner over a large area. This mechanically strong compound can be a vulcanization or an adhesive bond.

The layer layer 12b has a relative dielectric constant that is greater than the relative dielectric constant of the layer layer 12a of the base layer 12.

From the base surface 14 opposite surface 16 of the layer layer 12a of the base layer 12 are materialeinstückig spacer elements 18 away.

How out FIG. 3 it can be seen, the spacer elements 18 have different cross-sectional dimensions and are provided distributed irregularly on the layer layer 12a of the base layer 12.

By the spacer elements 18, an elastic surface layer 20 is spaced from the base layer 12 and connected to the base layer 12. The spacer elements 18 define between the elastic base layer 12 and the elastic surface layer 20 a cavity 22 which forms an air layer 24.

The spacers 18 may have any cross-sectional shape; they may have a circular, an oval, a polygonal or any other shaped cross-section.

The elastic surface layer 20 preferably consists of a permanently elastic material, which is expediently a driven, foamed permanently elastic material. The surface layer 20 has a closed-pore outer surface 26. The outer surface 26 is puncture resistant, it may be colored for optical camouflage.

The surface layer 20 constituting a scavenger layer for radar rays is made of, for example, driven halobutyl rubber. It has a thickness of> 1 mm.

The surface layer 20 is formed with a structured outer surface 26. The structuring can be designed as a knob surface rounded on all sides, like the Figures 1 and 2 illustrate schematically.

The surface layer 20 forming a scavenger layer for radar rays may also be formed as a foliage structure or as a network having a structure similar to a chaos structure of a wood wool.

The layer layers 12a, 12b,... 12n of the base layer 12 preferably consist - like the surfaces 20 - of a permanently elastic material. Expediently, the layer layers 12a, 12b,... 12n of the base layer 12 consist of chloroprene rubber.

The surface 16 of the base layer 12 may be planar smooth or - like the surface layer 20 - be structured.

The surface layer 20 is fixedly connected to the spacer elements 18 of the base layer 12. This connection can be a material-bonding connection such as, for example, a weld, a bond or a stitching. Another possibility is that the base layer 12 is positively connected to the surface layer 20 on the spacer elements 18. In FIG. 1 is a positive connection clarifies a push button connection.

The materials used for the radiation filter according to the invention are, for example, foamed, driven cellular rubber or sponge rubber or, as has already been stated, chloroprene rubber, halobutyl rubber or butyl rubber.

The total thickness ie height of the radiation filter is, for example, 5 to 10 mm without, of course, being limited thereto. The gap width of the cavity 22 of the radiation filter 10 is for example 3 mm. Of course, another dimension of the gap width is possible. The wave height of the knobs 28 is for example 1 - 2 mm. The nubs 28 are available for example in three different diameters and heights.

The layer layers 12a, 12b, ... 12n of the base layer 12 are solid, the surface layer 20 have randomly distributed, air-filled pores.

FIG. 4 shows in a sectional view on a larger scale, a portion of the radiation filter 10 with a base layer 12, which has two layer layers 12a and 12b, and with a surface layer 20. From the surface layer 20 facing layer layer 12a of the base layer 12 stand material integrally spacer elements 18 away. In FIG. 4 only one of these spacers 18 is drawn.

Through the spacer element 18 and the layer layers 12a and 12b of the base layer 12, a through hole 30 extends centrally therethrough. The through hole 30 is formed with a recess 32 extending from the base 14 of the base layer 12.

The surface layer 20 is formed with a through hole 34 that axially aligns with the through hole 30 of the base layer 12. The through hole 34 is formed like the through hole 30 with a recess 36. The recess 36 starts from the outer surface 26 of the surface layer 20.

After assembly of the radiation filter 10, the depressions 32 and 36 can be filled with resin.

In the embodiment of the radiation filter 10 according to FIGS FIGS. 4 and 5 the base layer 12 of the glued together or vulcanized layer layers 12a and 12b and the surface layer 20 are fixedly connected to each other by means of plastic locking rivets 38 which extend through spacer elements 18 therethrough. The respective locking rivets 38 consists of two rivet parts 40 and 42. Each of the rivet parts 40 and 42 has two opposing rivet legs 44, 46 (see also FIG. 5 ) on. The rivet legs 44, 46 are each formed with serrated leg surfaces 48 which engage in the assembled state of the plastic rivets 38 and cause a firm connection of the rivet parts 40 and 42 and thus a firm connection of the base layer 12 and the surface layer 20.

The respective rivet part 40, 42 is formed with a rivet head 50, 52, from which the associated rivet legs 44, 46 protrude.

The depression 42 in the base layer 12 serves to receive the rivet head 50 of the rivet part 40. The depression 36 originating from the outer surface 26 of the surface layer 20 in the surface layer 20 serves to receive the rivet head 52 of the rivet part 42.

Same details are in the FIGS. 4 to 5 each with the same reference numerals as in the FIGS. 1 to 3 designated, so that it is unnecessary, in conjunction with the FIGS. 4 and 5 to describe all the details again in detail.

List of reference numerals:

10

radiation filter

12

Base layer (out of 10)

12a, 12b

Layer layers (from 12)

14

Footprint (from 12)

16

Surface (from 12)

18

Spacer elements (from 12 to 16)

20

Surface layer (out of 10)

22

Cavity (between 12 and 20)

24

Air layer (in 22)

26

Outer surface (from 20)

28

Nubs (to 26)

30

Through hole (in 18 and 12)

32

Depression (from 30 to 12)

34

Through hole (in 20)

36

Depression (from 34 to 20)

38

Plastic snap-in rivets (from 10 for 12 and 20)

40

Rivet part (from 38 at 12)

42

Rivet part (from 38 at 20)

44

Rivets (from 40)

46

Rivets (from 42)

48

toothed thigh surfaces (from 44, 46)

50

Rivet head (from 40 to 32)

52

Rivet Head (from 42 to 36)

Claims (27)

Radiation filter for radar beam absorption and for attenuating the IR radiation from an object, such as a vehicle, ship or a stationary device,
characterized,
in that an elastic base layer (12) and an elastic surface layer (20) are provided, which are spaced apart from one another by spacers (18) and joined together by the spacer elements (18) between the base layer (12) and the surface layer (20) Cavity (22) is formed, and wherein the elastic base layer (12) at least two layer layers (12a, 12b, ... 12n) having different relative dielectric constants. Radiation filter according to claim 1,
characterized,
that the surface layer (20) consists of a permanently elastic material. Radiation filter according to claim 2,
characterized,
in that the surface layer (20) consists of a driven, foamed permanently elastic material. Radiation filter according to claim 3,
characterized,
that the surface layer (20) has a closed-pore outer surface (26). Radiation filter according to one of claims 1 to 4,
characterized,
in that the surface layer has a structured outer surface (26). Radiation filter according to claim 5,
characterized,
that the outer surface (26) is resistant to treading. Radiation filter according to claim 5,
characterized,
in that the outer surface (26) is colored for optical camouflage. Radiation filter according to claim 5,
characterized,
in that the structured outer surface (26) is formed with rounded knobs (28) on all sides. Radiation filter according to claim 8,
characterized,
that the nubs (28) have different dimensions and are distributed irregularly. Radiation filter according to one of claims 1 to 9,
characterized,
the at least two film layers (12a, 12b, ... 12n) of the base layer (12) each consist of a permanently elastic material. Radiation filter according to one of claims 1 to 10,
characterized,
that the spacer elements (18) from the surface (16) of the surface layer (20) facing layer (12a) protrude the base layer (12) materially in. Radiation filter according to one of claims 1 to 11,
characterized,
that the spacer elements (18) have different cross-sectional dimensions. Radiation filter according to one of claims 1 to 12,
characterized,
that the spacer elements (18) are provided distributed irregularly. Radiation filter according to one of claims 1 to 13,
characterized,
in that the surface (16) of the surface layer (20) facing layer (12a) of the base layer (12) planar smooth. Radiation filter according to one of claims 1 to 13,
characterized,
in that the surface (16) of the layer layer (12a) of the base layer (12) facing the surface layer (20) is structured. Radiation filter according to one of claims 1 to 15,
characterized,
in that the surface layer (20) is materially connected to the spacer elements (18) of the base layer (12). Radiation filter according to claim 16,
characterized,
that the connection is formed by a bond, a weld or a stitching. Radiation filter according to one of claims 1 to 15,
characterized,
that the surface layer (20) with the spacer elements (18) of the base layer (12) is positively connected. Radiation filter according to claim 18,
characterized,
in that the connection is formed by a Velcro back-to-back connection or by a push-button connection. Radiation filter according to claim 18,
characterized,
that the connection of plastic locking rivets (38) is formed. Radiation filter according to claim 20,
characterized,
that the plastic latching rivets (38) extend through the spacer elements (18). Radiation filter according to one of claims 1 to 21,
characterized,
in that the layer layers (12a, 12b,... 12n) of the base layer (12) consist of halobutyl rubber or butyl rubber. Radiation filter according to one of claims 1 to 22,
characterized,
in that the surface layer (20) consists of driven halogen-butyl rubber according to the mixture designation GWB 9269. Radiation filter according to one of Claims 1 to 23,
characterized,
that the thickness of the film layers (12a, 12b, ... 12n) of the base layer (12) is 1 to 3 mm. Radiation filter according to one of claims 1 to 24,
characterized,
that the thickness of the surface layer (20) is> 1 mm. Radiation filter according to one of claims 1 to 25,
characterized,
that the film layers (12a, 12b, ... 12n) of the base layer (12) are vulcanized together or glued together. Radiation filter according to one of claims 1 to 26,
characterized,
that the relative dielectric constant of the film layers (12a, 12b, ... 12n) of the base layer (12) is larger in each direction away from the surface layer (20).

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