DE1255747B - Low reflection damping arrangement for electromagnetic waves - Google Patents

Description

Low reflection damping arrangement for electromagnetic waves Die The invention relates to a low-reflection damping arrangement for electromagnetic Waves.

Such a damping arrangement can, for. B. as an anechoic cladding reflecting objects or especially reflecting walls are used. So are shielded measuring rooms in which the radiation measurements or the measurements of the Radiation diagrams of antennas are made, thereby largely reflection-free designed so that the walls and possibly the surfaces are more reflective Objects are provided with anechoic cladding. Since the wall parts of such Measuring rooms are usually provided with covers with good electrical conductivity in order to To eliminate the influence of external electromagnetic interference fields would be the reflection the electromagnetic waves present in the measuring room on the walls are relatively large. They would falsify the measurement curves to be recorded at the receiving location. To these disadvantages to avoid and to adapt this measuring space to the conditions of the so-called "free space" adapt, such anechoic damping arrangements in front of the walls arranged. The electromagnetic waves incident on it are attenuated and only reflected to a relatively small extent of less than 10%.

It is already known to assemble such anechoic coverings from a multiplicity of conical or pyramid-shaped, electromagnetic wave-damping bodies (French patent 1091571). In addition, it is known to build such an anechoic absorber from several layers with different electrical conductivity and / or different dielectric constants (German utility model 1760 260). The electrical conductivity of the layer facing the incident waves increases in the direction of wave propagation. It is also already known to increase the dielectric constant of the individual layers in the direction of wave propagation. Furthermore, it is already known to assemble reflective damping arrangements from honeycomb-like composite waveguide-like elements.

The honeycomb walls consist of a resistance material or are made of support bodies covered with resistance material, e.g. B. hard paper plates formed (German Auslegeschrift 1 024 433). It is also already known to arrange absorbent material in the form of small individual bodies of different grain size in such a way that the layer on the incident side of the electromagnetic waves has individual bodies of larger grain size and the layers behind it have individual bodies of smaller grain size (cf. German patents 1 021437 and 765 298) . In these known absorbers, the individual bodies are combined to form a structural body by a binding agent, or they lie loosely on a base. Finally, it has also already been proposed to apply resistance layers to block-like, cuboid foam bodies and to assemble them in a honeycomb construction.

The invention is based on the object of the assembly effort in the To reduce the arrangement of high-frequency absorbers in front of reflective walls. Included it should be possible to customize the absorber arrangement to meet the individual requirements to adapt as much as possible without having to resort to special auxiliary forms.

It is based on a damping arrangement that consists of a large number of small lossy grains compared to the thickness of the damping arrangement exists, which lie against one another in such a way that pore spaces remain between the grains. In order to achieve the object set, the grains are in the form of with according to the invention electrically conductive material coated foam balls as bulk material between Walls filled.

The absorption material consists of foam balls, e.g. B. Balls made of pure polystyrene coated with an electrically conductive resistive varnish or the like. Are coated. Depending on the diameter of these balls, the electric ones Conductivity of the resistance material and its layer thickness on the balls can be the specific sheet resistance of a chamber filled with such spheres be determined. It is therefore very easy to adapt to the to undertake each existing frequency range in which the damping arrangement should have a low reflection factor.

For this purpose a Cover sheet stretched and the bulk material between the reflective wall and this Cover foil filled. If the reflective wall has openings, niches or has similar unevenness, is according to the invention on this reflective wall a wall film and a cover film stretched at a distance from this wall film and the bulk material is filled between these foils in the chamber thus formed. The wall film can also be partially arranged at a distance from the reflective wall be around bumps in the cushioning assembly necessary for certain cushioning tasks are desired to form. So it is advantageous that the cover sheet and optionally the wall film are stretched in front of the reflective wall in such a way that they are rib-like form projections running along the wall. These ribs can advantageously run in intersecting rows along the absorber arrangement.

If the reflective wall itself does not or only partially a metal screen is covered in a further embodiment of the invention as Wall foil uses a material with good electrical conductivity. The wall film is made while z. B. made of copper.

Are appropriate, the clamping should prepare such cover films and optionally wall film to the reflecting walls difficulties, the bulk material is poured in cuboid container in another embodiment of the invention, there are the walls of an electrically non-conductive material and the aufae front of the reflective wall is. This arrangement according to the invention is particularly advantageous when a measuring space is to be subdivided. The cuboid containers filled with bulk material of this type are set up as a boundary wall in the room next to and on top of one another, so that they themselves form a wall.

It is particularly advantageous to use the container with waste measurements 33-50 - 100 cm or more preferably from 5 - 33 - produce 100 cm. Measurements by this waste, it is possible that the damping assembly may have a thickness of 5 to 100 cm, depending on the position of the container. If these containers are set up, for example, in such a way that the damping arrangement has a depth of 5 cm, then the damping arrangement has a lower limit frequency of approximately 2 GHz. If the containers are set up differently so that the depth of the damping arrangement is 33 cm, the lower limit frequency is approximately 500 MHz, and with a total depth of the damping arrangement of 1 inch, the lower limit frequency is approximately 100 MHz.

Analogous to the already known step absorbers, whose electrical surface resistance decreases in the direction of propagation of the wave towards the reflecting wall, according to the invention either several rows of containers are arranged one behind the other or several film walls are spanned and bulk material of different electrical surface conductivities is introduced into the interstices. In this case, for example, the containers A or chambers arranged directly on the wall have a bulk material a whose electrical surface resistance is smaller than the surface resistance of the bulk material b of containers B which are arranged in front of the first-mentioned containers A.

By perforating the container or the film or by using it Mesh-like material can also reduce acoustic reflection be achieved.

On the basis of the FIGS. 1 to 7 illustrated embodiments, the invention is explained in more detail.

In fig. 1 shows the section through the rear of a measuring space R. The electromagnetic waves are incident on the measuring chamber rear wall 1 in the y direction, for example. 2 with the floor of the measuring room and 3 with the ceiling of the measuring room. The measuring room rear wall 1 consists, for example, of masonry clad with Cu plates. In the measuring room floor 2, in the measuring room ceiling 3 and in the measuring room rear wall 1 , tensioning dowels 4 are embedded, with the aid of which both a cover sheet 5 and a wall sheet 6 are stretched on the central part of the rear wall 1. The rib-like projection of the cover film 5 and wall film 6 running along the measuring chamber rear wall 1 is made possible by a push rod 7 and by two tie rods 8 , which are shown in FIG. 2 are shown in more detail in partial detail. Perlon or nylon ropes 9 run between the tensioning dowels 4 on the ceiling and the floor of the measuring room, as shown in FIG. 3 are still shown in the front view. In order to tension these ropes 9 , additional tensioning elements 10 are provided. The push rods 7 are connected horizontally along the wall with a cross bar 11 . The cover film 5 is placed over the cable and transverse strip system. It represents a wall for the bulk material 12 filled between the cover sheet 5 and the space formed by the rear wall 1, the floor 2, the ceiling 3 and the wall sheet 6. The foam balls of the bulk material are coated with a resistive varnish. For filling the bulk material 12 into the intermediate spaces, openings are provided at the upper end of the cover film 5 in the vicinity of the ceiling 3 , which are not shown in the figures. The spacing of the ropes 9 in the horizontal direction is approximately 1 in.

In FIG. 4 shows a bulk material container, the dimensions of which are approximately 100-50.33 cm. The bulk goods container wall 13 consists, for example, of plastic. The bulk material 12 already described above is filled into the container.

The bulk goods containers are either set up on the reflective wall without any special securing and anchoring arrangements or in free space. If special anchoring is required, for example according to FIG. 5 at the grid spacing of the bulk goods container to be erected tie rods 14 connected to the walls via tension dowels 4. The bulk containers are inserted between the tie rods, and the one shown in FIG. 6 , after the bulk goods container has been inserted, the end piece 15 shown in a top view is indented as a front closure into the tie rod recesses 16 provided for this purpose ( FIG. 7). This ensures that the bulk goods containers cannot be easily moved away from the wall or can move away from the wall automatically in the event of vibrations or similar mechanical stresses.

Claims (2)

1. A reflection arms damping arrangement for electromagnetic waves consisting of a plurality of with respect to the thickness of the damping arrangement small lossy grains against one another so as to remain between the granules void spaces, d a d u rch in that the grains in the form of electrically Foam balls coated with conductive material are filled as bulk material (12) between walls (1; 2; 3; 5; 6; 13). 2. Damping arrangement according to claim 1, characterized in that the bulk material (12) is filled between a reflective wall (1) and a cover sheet (5) stretched at a distance from the reflective wall. 3. damping arrangement according to claim 1, characterized in that the bulk material (12) is filled between one each disposed on the reflective wall (1) wall film (6) and clamped at a distance from the wall film cover sheet (5). 4. damping arrangement according to claim 3, characterized in that the wall film (6 ') extends partially at a distance from the reflective wall (1) . 5. Damping arrangement according to one or more of the preceding claims, characterized in that the cover film (5) and optionally the wall film (6) are stretched in front of the reflective wall in such a way that they form projections extending like ribs along the wall. 6. Damping arrangement according to one or more of the preceding claims, characterized in that the wall film (6) is designed to be electrically conductive. 7. damping arrangement according to claim 6, characterized in that the wall foil (6) consists of copper. 8. Damping arrangement according to claim 1, characterized in that the bulk material (12) is poured into cuboid containers (13) made of electrically non-conductive material, which are placed in front of the reflective wall or in free space. 9. damping arrangement according to claim 8, characterized in that the container (13) have the following dimensions: 5 - 33 - 100 cm. 10. Damping arrangement according to claim 8, characterized in that the container (13) have the following dimensions: 33 -50. 100 cm. 11. Damping arrangement according to one or more of claims 8 to 10, characterized in that a plurality of rows of containers (13) are set up in front of the wall (1) , whose container (A) arranged directly on the wall contains a bulk material (a), whose electrical surface resistance is smaller than the electrical surface resistance of the bulk material (b) of containers (B) which are arranged in front of the first-mentioned containers (A) . 12. Damping arrangement according to claim 11, characterized in that the bulk material (12 [a]) has smaller foam balls than the bulk material (b). 13. Damping arrangement according to claim 11 or 12, characterized in that the balls of the bulk material (a) have thicker, electrically conductive layers than the balls of the bulk material (b). 14. Damping arrangement according to claim 11 to 13, characterized in that the electrically conductive layers of the balls of the bulk material (a) have a greater specific electrical conductivity than the balls of the bulk material (b). Considered publications: German Patent Specifications No. 765 298, 1 021437; German Auslegesehrift No. 1029 433; German utility model No. 1760 260; French patent specification No. 1091571.