DE1268232B - Low reflection damping arrangement for electromagnetic waves - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

HOIq

German KL: 21a4-71

Number: 1268232

File number: P 12 68 232.5-35

Filing date: March 26, 1963

Opening day: May 16, 1968

The invention relates to an anechoic damping arrangement for electromagnetic waves, consisting of a carrier block with a low dielectric constant of less than ε - 2.6 with an essentially flat front side facing the incident waves and a rear side facing away from the incident waves, of which the conical is covered with a resistive layer Recesses, e.g. B. hollow cones or hollow pyramids protrude with the tips to the front in the support block, the mutual distance for a given upper limit frequency is sufficiently small.

Such a damping arrangement can, for. B. as an anechoic cladding of reflective objects or serve walls. So are anechoic measuring rooms in which the interference radiation measurements or the measurements of the antenna radiation diagrams are made, thereby largely Designed to be reflection-free so that the walls and possibly the surfaces are more reflective Objects are provided with anechoic cladding.

It is already known to make such panels from a variety of conical, in particular conical or assemble pyramid-shaped, electromagnetic wave damping bodies. Included point the tips of these conical bodies away from the reflection wall in the direction of the impinging ones Waves.

As the individual attachment of such conical bodies to the walls to be clad with low reflection is cumbersome and may cause difficulties, it is already known, so-called Manufacture hollow cone plates. Such hollow cone plates are in German Patent 1120 529 described. This hollow cone plate - referred to below as the carrier block - has a number of conical recesses, e.g. B. cone-like recesses provided, from the back of this Starting from carrier blocks, run into these. The tips point towards the front of this Plate facing the waves that hit it. The surfaces of these recesses are with Resistance material provided. This has the task of dampening the electromagnetic waves. The cone-like recesses are moved so close together that on the back of the carrier block, facing the reflection wall, only extremely small surface segments of the the original back of the plate are present, which are not connected to each other by bars on the back of the carrier block are connected.

Low reflection damping arrangement for
electromagnetic waves

Applicant:

Siemens Aktiengesellschaft, Berlin and Munich, 8000 Munich 2, Wittelsbacherplatz 2

Named as inventor:

Dipl.-Phys. Dr. rer. nat. Josef German,

Dipl.-Ing. Günter Vollhardt, 8000 Munich - -

In the German patent applications S 84302 rXd / 21a * and S 84344 IXd / 21a ^{4 it} has been proposed to keep the distance between the conical recesses so large that a closed area remains around the base edge lines of each recess, which forms part of the back of the carrier block. The back of the carrier block is provided with an absorber cover acting as an electrical short circuit and electrically contacted with resistance layers located in the recesses. The conical recesses of these proposed damping arrangements are at least partially filled with an absorber filler which has at least as good properties as the carrier block material. In the second-mentioned patent application, the conical recesses are of unequal length.

The back of a shaft absorber device with a cover acting as an electrical short circuit to provide, is from the "Journal for Applied Physics", Vol. 11, 1959, H. 12, p. 453 bis 455, known. It is also known there to use the resistance layers on the shaft walls Contact the back of the absorber device electrically.

It is the object of the invention to provide such an anechoic damping arrangement with the same or in particular a lower reflection factor shorter than usual since then. Especially with the damping of meter waves, such damping arrangements are relatively thick. So these show Damping body construction depths of more than a third of the largest wavelength to be damped, when a stress reflection factor of less than 10% is to be achieved. With an even lower chip

809 549/153

Ation rejection of 3%, such damping elements are even four fifths of the maximum that can be damped Wavelength thick. This means that the cones or support blocks have a depth of up to 1 m and possibly also have. One aim of the invention is to reduce the overall depth. In this way it becomes possible to gain more free space in the measuring space. Besides, the Saving of damping material is very important for reducing the cost of such damping arrangements. The reduction in the reflection factor is also an object of the invention. Surprisingly, it has been found that a extensive reduction of the reflection factor or the construction depth in the case of the one described above Damping arrangement can be achieved if the above-mentioned damping arrangement according to the invention is improved by the combination of the following features:

a) The distance between the conical recesses is kept so large that around the The base edge of each recess remains a closed area that forms part of the Forms the back of the carrier block;

b) the back of the carrier block has a known per se acting as an electrical short circuit Provided absorber cover and with resistance layers located in the recesses electrically contacted;

c) the relative permeability is less than 1.5, and the difference between the real parts of the dielectric constant and the permeability of the carrier block ε - μ is between +0.1 and +0.3.

In-depth theoretical and experimental investigations have shown that the inventive design of the damping arrangement with the layer attached to the back of the carrier block acting as an electrical short circuit and the allocation of the recesses and the choice of carrier block material can achieve extremely large improvements within the meaning of the object of the invention. If the relative permeability of the carrier block is about μ,. = 1.0, then the maximum best results, ie the lowest reflection factors with at the same time the lowest construction depth with a dielectric constant of about 1.2 ~ - 1.3 are achieved. By using substances of such a dielectric constant, e.g. B. of synthetic foams optionally with dielectric filler material, the depth of the absorber can be kept lower than with a dielectric constant of less than 1.2. In contrast to this, an increased dielectric constant of more than 1.3 leads to an even shorter construction depth of the carrier block, but at the same time the reflection factor is increased. The inventive limitation of the dielectric constant between 1.2 and 1.3 with a μ of approximately 1.0 therefore results in optimal values.

Compared to this damping arrangement according to the invention, a further improvement, in particular a smaller overall depth, is achieved with equally favorable reflection factors when the foam of the carrier block has a permeability between approximately 1.0 and 1.5 due to the addition of a permeable material. As extensive studies have shown, the difference ε - μ 'should be between approximately +0.1 and +0.3. If a permeable filler is added to the carrier block, the dielectric constant can therefore also be greater than 1.3, as long as the difference ε'-μ ' given above is maintained. The achieved shortening of the construction depth compared to absorbers with a permeability of μ = μ ₀ , ie μ _Γΐ1 = 1, is then μ '. If, for example, carbonyl iron powder is used as a permeable filler and a μ ' of around 1.4 is achieved, the relative dielectric constant can be around ίο 1.6, without the reflection factor compared to an absorber with &' = 1.2 at a μ ' of 1.0 is enlarged. The construction depth, on the other hand, was reduced by a factor of 1.4. This result is all the more surprising since, because of the known characteristic impedance adaptation Z = 1 / - ^ - the relative

Since then, the permeability has been chosen to be as equal as possible to the relative dielectric constant. It becomes a broad spectrum with a reflection factor r <C 10% of

for example

J m

> 1:50 reached.

In a further embodiment of the invention, the recesses of the carrier block are filled with a filler filled out. This filler should have a dielectric constant and possibly permeability, which are equal to or greater than that of the carrier block. These fillers can e.g. B. can also be designed as cones or pyramids if the recesses of the support block are conical or are pyramidal. The filling elements do not need the entire free space of the Fill in the recesses. It is advantageous to also use it yourself or your surfaces with electrical To fill or cover resistance material, so that the sheet resistance of the entire arrangement increases from the front of the carrier block to the rear, for example in an exponential approximation. In a further embodiment of the invention, the carrier block has recesses of different lengths.

For example, there are a plurality of rows and columns with relatively long cutouts in the carrier block intended. Between these larger recesses, additional smaller ones can then be made Be arranged recesses. This training is a decrease in the Surface resistance of the absorber in the direction of the rear of the absorber in a roughly approximated exponential Course reached.

The cover acting as an electrical short circuit on the back of the carrier block can be used as an electrical conductive plate, as a metal foil or for example also be designed as a sufficiently narrow mesh. The mesh should be a have a smaller mesh size than about a tenth of the smallest wavelength to be attenuated. Of the Wire mesh itself or a coating over this wire mesh has a high electrical conductivity on. The wire can be made of copper, or the wire has a thin layer of copper overdrawn.

The filling of the recesses with dielectrically acting material can, for. B. also happen in this way, that the carrier block, the recesses of which are covered with resistive layers, with dielectric Material is poured out. This filler material can have a relative Have a permeability greater than 1. However, this relative permeability should also be the same as with

Carrier block material smaller than the relative dielectric constant this filler.

The material of both the support block and the filler can be rigid or flexible be. Light building materials such. B. foamed plastic is used. In particular it is It is advantageous to use non-flammable, fire-retardant or self-extinguishing substances or the absorber body spray or soak with fire retardants. The resistive layers, e.g. B. soot-containing Paints, in the recesses and, if necessary, on the fillers can be sprayed, dipped, Foaming, pouring, vapor deposition or similar onto the inner or outer surfaces of the be applied conical recesses and packing.

The opening angle, especially of the longest recesses, should be less than 15 °. To this A particularly good attenuation with a very low reflection factor will also occur for waves, which deviate significantly from a perpendicular incidence on the front side of the carrier block.

1 to 4 are examples of the inventive Damping arrangement specified.

In Fig. 1 shows a section of a damping arrangement according to the invention. The carrier block 1 consists of a foamed material, for. B. polystyrene or phenolic resin foam. It is provided with conical recesses 2 which run from the rear of the carrier block in the direction of the front 3. The electromagnetic waves impinge on the front side 3 of the carrier block, for example, in the direction of the arrow y, that is to say essentially perpendicularly. The walls of the recesses 2 are covered with resistance material 4, for. B. soot-graphite paints covered. In the recesses 2 fillers 5 are made of z. B. polystyrene, polytetrafluoroethylene or mixtures of thermoplastics with z. B. Titanium dioxide filling with a higher dielectric constant than that of the carrier block 1 is filled. The back of the carrier block is covered with an electrically conductive aluminum plate 6. The dielectric constant of the carrier block material is approximately ε = 1.25, the relative permeability is approximately μ = 1.0.

In Fig. 2 shows a detail of a rear view of the arrangement according to the invention with the aluminum plate removed for the sake of clarity. This expresses the fact that the base edge lines 2 'of adjacent cones do not touch each other, so that areas 7 of the rear of the absorber that are still connected and covered with resistive layers 4 remain between the individual cones. The recesses filled with dielectric material with a dielectric constant of, for example, ε zn 5 are covered on the rear side with the aluminum plate 6 (not shown in this figure). This is in contact on the surfaces 7 with the resistance layers 4 located within the cutouts.

In Fig. 3 shows a further embodiment of the invention in which the carrier block 1 contains recesses 2 a and 2 b of different lengths. Cone-like fillers are used in these recesses. A hollow cone 5 a and a further smaller cone 5 b are used in the longer conical recesses 2 α and only the smaller cones 5 b are used in the smaller recesses 2 b. The insides of the recesses and the outsides of the cones are covered with resistance material. The resistance material of the smaller cones 5 b has the same or higher electrical conductivity than that of the larger cones 5 a and the recess resistance layers. The back of the carrier block is covered with an aluminum foil 6.

In Fig. 4 the dependence of the overall depth BT and the reflection factor r on the dielectric constant ε is shown schematically. The parameters given are the permeabilities of the carrier block material. As the dielectric constant increases, the construction depth is reduced. At the same time, the reflection factor increases. If the permeability of the carrier block is increased, ζ. Β. If μ '= 1.2 is selected, a lower reflection factor is achieved when the overall depth is reduced. Within the range between μ = 1.0 and μ = 1.5 and with a dielectric constant of around 1.2 to around 1.7, construction depths and reflection factors have been found to be optimally favorable.

Claims (14)

Patent claims: 1. Low-reflection damping arrangement for electromagnetic waves, consisting of a Carrier block with a low dielectric constant of less than ε = 2.6 with one of the incident ones Waves facing, essentially flat front and one of the incident waves facing away from the back, from which conical recesses covered with a resistive layer, z. B. hollow cones or hollow pyramids protrude into the support block with the tips facing the front, their mutual distance is sufficient for a given upper limit frequency is small, characterized by the combination of the following features: a) The distance between the conical recesses (2) is kept so large that around the base edge lines (2 ') of each recess (2) a closed surface (7) remains, which forms part of the carrier block back; b) the back of the carrier block has a known per se acting as an electrical short circuit The absorber cover (6) is provided and electrically contacted with the resistance layers (4) located in the recesses (2); c) the relative permeability is less than 1.5, and the difference between the real parts of the dielectric constant and the permeability of the carrier block ε-μ is between + 0.1 and +0.3. 2. Damping arrangement according to claim 1, characterized in that the relative dielectric constant of the carrier block at a relative permeability of about μ _τ = 1.0 is about 1.2 - ^ 1.3. 3. Damping arrangement according to claim 1, characterized in that the relative dielectric constant of the carrier block at a relative permeability of about μ _τ = 1.2 is about 1.4. 4. Damping arrangement according to one of claims 1 to 3, characterized in that the conical recesses are of unequal length. 5. Damping arrangement according to one of claims 1 to 4, characterized in that the conical recesses are at least partially filled with a filler that is at least equal good dielectric as the carrier block material acts. 6. Damping arrangement according to one of the preceding claims, characterized in that that the filler as a conical, z. B. conical or pyramidal element is formed. 7. damping arrangement according to one of the preceding claims, characterized in that that the filler elements on the outer and / or inner surfaces with resistance material are covered. 8. damping arrangement according to claim 7, characterized in that the resistance material has a relative permeability greater than one. 9. damping arrangement according to one of the preceding claims, characterized in that that the filler consists of several nested conical elements, e.g. B. hollow cones or hollow pyramids, whose dielectric constant varies from the larger to the smaller filler elements increases. 10. Damping arrangement according to one of the preceding claims, characterized in that that the opening angle of the conical recesses is less than about 15 °. 11. Damping arrangement according to one of the preceding claims, characterized in that that the carrier block and / or the filler consist of foamed plastic. 12. Damping arrangement according to one of the preceding claims, characterized in that that the carrier block and optionally the filler are flexible. 13. Damping arrangement according to one of the preceding claims, characterized in that that the carrier block and / or the filler consist of combustible material and / or with are provided with a fire-retardant protective cover. 14. Damping arrangement according to one of the preceding claims, characterized in that that the cover of the back of the carrier block as a mesh with a mesh size of less than a tenth of the shortest wavelength to be attenuated is formed from wire mesh with good electrical conductivity. Considered publications:
German Patent No. 1120 529;
"Journal for Applied Physics", 1959, Vol. 11, H. 12, pp. 453 to 455. 1 sheet of drawings 809 549/153 5.68 © Bundesdruckerei Berlin