DE3347504A1 - CIRCULAR POLARIZATION GRID FOR ANTENNA RADIATORS - Google Patents

Description

Siemens Aktiengesellschaft Our mark Berlin and Munich VPA

83 P 1 9 8 1 DE

Circular polarization jitter for antenna radiators

The invention relates to a circular polarization grating for Antenna radiators, in particular for radar antennas, with two parallel, interconnected rails and lattice elements arranged parallel to one another between the rails.

Antenna radiators from radar antennas, e.g. from so-called cake box or pillbox radar antennas, show in the generally have a linear polarization, as this provides the greatest range under normal conditions can. With a linearly polarized antenna, however, you can get rain cloud echo signals that have a similar spectral distribution how target echo signals have, from "real" target echo signals do not distinguish. With circular polarization, however, rain echoes are largely suppressed, so that it is easier to distinguish between flight targets and rain clouds. It is therefore often the linear polarization of the antenna through a polarization grating placed in front of the radiation aperture into a circular one Polarization converted. In the case of circular polarization, all grid elements must have an angle of 45 to E-vector (= electric field vector) of the incident wave and are therefore exactly parallel to each other. Such Circular polarization gratings are known, for example, from American patent specification 2,800,657. This shows a Grid, the elements of which are inclined at 45 ° and arranged parallel to each other in a rigid rectangular frame are. Such circular polarization grating must be

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linear polarization can be folded away or removed. Folding away or removing a circular polarization grating but creates difficulties in particular when it comes to mechanical and climatic protection in the antenna outlet a radome e.g. made of rigid foam and the grid between the radome and the radiation aperture is arranged. If, on the other hand, the circular polarization grating is made movable, e.g. foldable, so the production of the parallelism of the grid elements causes difficulties, since the grid elements are then rotatably mounted must be and a parallel guide with many pivot bearings of the grid elements in the production very costly and can hardly be realized in terms of production technology because all the hole spacings of the pivot bearings are absolutely the same have to. However, since the bearing distances are subject to tolerances in practice and thus different folding radii arise, jams a movable grille with fixed pivot bearings for the grille elements in motion, is stiff, sometimes blocks or the grid elements are bent inadmissibly.

The invention is therefore based on the object of a polarization grating for converting the linear polarization of an antenna radiator into circular polarization and vice versa create that enables quick switching and when positioning in the circular polarization position an exact parallelism of the grid elements with high repeatability is guaranteed.

In the case of a circular polarization grating of the type mentioned at the outset according to the invention, this object is achieved by that the rails, at least at their end areas each a strut, which is mounted at its ends in a swivel joint on the rails, with each other

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are connected, and that in the area of the ends of the parallel to the struts arranged lattice elements each have a spring mounted on the lattice element with a spring end encloses a bearing bolt fixedly arranged on the rail on the side thereof facing away from the grid element, so that the Grid element on the opposite side of the bearing pin is pressed against this.

In this way, a movable circular polarization grating is made up of a collapsible parallelogram grating formed, which can be firmly arranged in the antenna outlet of a linearly polarized antenna radiator, by folding up one of the two parallel rails and the lattice elements, a quick conversion of the linear ones Polarization of the antenna radiator in circular polarization allows and also when the circular Polarization is to be canceled again, by folding an equally fast conversion of the circular polarization allowed into the original linear polarization. The folded parallelogram grid must can neither be folded out of the antenna outlet nor removed completely, as it is outside the radiation aperture can be arranged. A circular polarization grating according to the invention can therefore be fixed to the antenna radiator are arranged and always remain on the antenna radiator even with polarization conversion. This is special Advantage if a radome, e.g. made of hard foam, is used in the antenna outlet for mechanical and climatic protection is because the circular polarization grating is controlled from the outside and between the radome and the radiation aperture can be arranged without a removal of the radome is necessary for polarization conversion.

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83 P 1 9 8 1 DE

In addition, in a circular polarization grating according to the invention from a collapsible parallelogram lattice for the lattice elements no fixed one Pivot bearing, but a rotatable one, but on the bearing pin only spring-loaded storage provided. The spring-loaded connection of grid elements and bearing bolts is guaranteed a safe, play-free installation of the grid elements on the bearing pin and an exact parallelism of the Lattice elements with high repeatability, i.e. the exact parallelism of the lattice elements is always guaranteed Folding up the parallelogram grating into the circular polarization position is always guaranteed. the Lattice elements therefore do not require any tolerance-afflicted holes for their storage, the bearing bolts also in the usual tolerance range of the manufacturing possibility can be without the function of the foldable and foldable Obstruct lattice.

In the case of a circular polarization grating according to the invention, it is particularly expedient if the spring is designed in this way and is arranged at the ends of the grid elements that the connecting line between the bearing pin-side and support points of the spring on the lattice element side goes through the center of the bearing pin. This is of great advantage, especially with thin grid elements, because this avoids bending moments on the thin lamellas and the parallelism even with lattice elements thin slats are retained in all grid positions.

In a preferred embodiment of an inventive With a circular polarization grating, the spring for mounting the grating elements consists of a bow spring with two U-shaped interconnected via a transverse web

Spring clips. Such a spring can be particularly easily attached to the lamellar because of its clip effect Fasten the grid elements. In such a bow spring, it is useful if the distance between the two spring clips from each other approximately equal to the clear outside width of the grid elements is and the end regions of the grid elements with two each protruding beyond the clear outer width of the grid elements lateral shoulders are formed on which the spring clips can be attached, so that the one Clamp legs on the side of the grid elements facing the bearing bolt and the other clamp legs on the the side facing away from the bearing pin of the grid elements is located. Here, the spring clasps with the radius of the U-shaped bracket the lateral shoulders of the lattice elements. Through the interlocking of the bracket radius and Lateral shoulders is the grid element - since one spring end encompasses the fixed bearing pin and is therefore held there is - also fixed in its longitudinal direction.

The springs are advantageous to facilitate assembly designed so that the ends of the clamp legs are bent away from the grid element. This allows the Springs can easily be pushed over the bearing bolts and then automatically lock into the desired position.

The adjustment of a circular polarization grating according to the invention is expediently carried out from the outside by means of a drive which has suitable adjustment elements one of the connecting struts of the parallel grid rails acts and the grid moves into the circular polarization position Erects the grid elements with an inclination of 45 ° and against a correspondingly arranged stop pushes or the grid collapses when the

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Circular polarization should be canceled again.

A circular polarization grating according to the invention is based on an exemplary embodiment shown in the drawings described in more detail below.

Fig. 1 shows a view of an attachment housing of an antenna radiator with inserted, in a circular polarization position located polarization grating,

FIG. 2 is a view A according to FIG. 1,

3 shows a section through the exit of the antenna radiator and through the attachment housing,
FIG. 4 shows a first spring for mounting a lattice element and the end region of a lattice element, and FIG. 5 shows a second spring.

The antenna radiator 1 (Fig. 3) is a linearly polarized radar antenna, e.g. a so-called cake box or pillbox radar antenna, which is used to switch is formed on circular polarization with a circular polarization grating 2, which is fixed to the antenna is mounted and always remains on the antenna, i.e. even when the polarization is switched to linear polarization.

The circular polarization grating 2 is behind a radome 4 made of hard foam, which is inserted into an attachment housing 3, however arranged outside the radiation aperture and designed to be collapsible, so that it is circular polarization into the corresponding position with grating elements 5 inclined at 45 to the Ε vector of the incident wave can be folded up and folded up again with linear polarization so that its elements are again are outside the radiation aperture. The circular polarization grating 2 consists of the grating elements 5

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or two rails 6 and 7, which are guided parallel to one another and connected to one another, of which the lower rail 6 is fixedly mounted in the attachment housing and the upper rail 7 can be moved parallel to the rail 6. The rails 6 and 7 are designed as U-profiles facing each other with the open sides and - depending on the length of the lattice, at least at the two ends via a strut 9 or 10, which at their ends in a swivel joint 11 between the side legs 8 of the Rails are mounted on these, connected to each other. In the embodiment shown, the struts 9/10 are firmly mounted on the rails 6, 7. A swivel joint 11 is formed, for example, by a bolt 11a fixedly mounted on the side legs 8 and an end 11b of a connecting strut 9 or 10 that completely surrounds it. In this way, a collapsible parallelogram is formed. Parallel to the connecting struts 9, 10 and to one another, the grid elements 5 are arranged between the side legs 8 of the rails 6, 7 and consist of electrically conductive, strip-like lamellae. The connecting struts 9, 10 also expediently consist of similarly designed, here also electrically conductive lamellae, which, however, are stiffened by beads or embossings arranged on the longitudinal side. In contrast to the connecting struts, which are fixedly mounted here, there is no fixed pivot bearing for the grid elements 5, but a rotatable one _; but only spring-loaded storage provided. To support the grid elements 5, bearing bolts 13 are used, which consist of cylindrical pins firmly mounted in bores in the side legs 8 of the rails 6, 7 and a pressure element in the form of a spring 14, with a spring being mounted at each end of a grid element 5, which is connected to a spring end encloses a bearing bolt 13 on the side facing away from the grid element 5, so that the grid element is pressed against the bearing bolt on the opposite side of the bearing bolt.

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Here, the two springs 14 of a grid element are arranged on this in such a way that the bearing pin enclosing spring end 17 is located on different sides of the grid element, so that the grid is smaller is collapsible. In addition, the springs 14 are designed and arranged at the ends of the grid elements 5, that the connecting line between the bearing pin-side and the lattice element-side support points of the The spring always goes through the center of the bearing pin 13.

The more detailed design of a spring for mounting the grid elements is shown in FIGS. 4 and 5 in two embodiments. A spring 14 made of wire is shown in FIG and an end region 23 of a lamellar Lattice element 5 shown, while Figure 5 shows a spring 14a made of sheet metal. Each spring 14 or 14a consists of a bow spring with two U-shaped spring clips 16 or 16a, which are each formed by two clamp legs 17,18 and 17a, 18a, which at their junction with a bracket radius 19 and 19a are bent from one another. Here, the clip legs 18 and 18a are each connected to one another at one end as with the wire spring or between the bracket radius 19a and the free end 20a as with the sheet metal spring 14a connected via the transverse web 15 or 15a, while the other clamp leg 17 or 17a as a "free" clamp leg for enclosing a bearing pin 13, that is to say for mounting a grid element 5. For this purpose, the Springs 14 and 14a of the end area of the free clamp leg 17, 17a with an approximately semicircular offset 21 and 21a, respectively provided, the radius of which is slightly larger than the radius of the bearing pin 13- In the case of the spring 14a in Fig.5 is also also the free end region 20a of the other clamp leg 18a is provided with a semicircular crank 22a, with which the clamp legs 18a on the bearing pin

facing side of a grid element rests. With both springs there are finally the free ends of the clamp legs, that is, the ends of the clamp legs 17 / 17a and 18a are bent outwards away from the clamp legs.

In addition, the distance between the two spring clips 16 and 16a for both springs 14, 14a is approximately equal to the clear outside width, thus the width b (Fig. 4) of a grid element 5, the end regions 23 of a grid element each having two lateral shoulders 24 projecting beyond this width b are formed. The springs 14 and 14a are thus on this Shoulders 24 attachable so that the clamp legs connected to one another via the transverse web 15 or 15a and 18a on the side of the grid element facing away from a bearing pin 13 and the free clamp legs 17 or 17a are located on the side of the grid element facing a bearing bolt. The springs 14 and 14a thus enclose the on the shoulders 24 of a grid element 5 attached state with the crank 21 or 21a of the free bracket leg 17 or 17a resiliently clasp a bearing pin 13 with the bracket radius 19 or 19a, the lateral shoulders 24 of a grid element and press this with the other clamp leg 18 or 18a on the side of the lattice element facing away from the bearing bolt 13 against the bearing pin. Through the interlocking of Clamp radius 19 or 19a and lateral shoulders 24 of a grid element, this is also in his Fixed lengthways. The spring-loaded connection of the grid elements and bearing bolts ensures a safe, play-free installation of the grid elements on the bolts and a high degree of parallelism of the grid elements in all grid positions preserved.

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The spring mounting provided for the grid elements can may also be used for struts 9/10.

To adjust the parallelogram lattice can be shown in Fig.1 and 3 only indicated, also arranged on the attachment housing 3 drive 25 are provided, which by means of a Drive spindle 26 via a pivot lever 27 on one of the connecting struts, e.g. on the connecting strut 10, acts and the grid against an adjustable stop 12 mounted in the attachment housing 3 in the circular polarization position with 45 inclination of the grating elements erects or collapses when the circular polarization should be canceled again.

15 claims
5 figures

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Claims (15)

Claims -Vi- VPA Circular polarization grating for antenna radiators, especially for radar antennas, with two parallel, interconnected rails and parallel lattice elements arranged between the rails, characterized in that the rails (6,7), at least at their end regions, each have one Strut (9,10), which is mounted at its ends in a swivel joint (11) on the rails (6,7), with one another are connected, and that in the region of the ends of the grid elements (5) arranged parallel to the struts (9, 10), respectively a spring (14,14a) is mounted on the grid element, which with a spring end (17,17a) is fixed to the rail (6,7) arranged bearing pin (13) encloses on the side facing away from the grid element (5), so that the grid element (5) on the opposite side of the bearing pin (13) is pressed against this. 2. Circular polarization grating according to claim 1, characterized in that the spring (I4, i4a) in such a way is formed and arranged at the ends of the grid elements (5) that the connecting line between the Support points of the spring on the bearing pin side and on the grid element side always through the center point of the bearing pin (13) goes. 3. circular polarization grating according to claim 1 or 2, characterized in that the two springs (14,14a) of a grid element (5) are arranged on this in such a way that the spring end (17, 17a) surrounding the bearing pin (13) is located on different sides of the grid element (5) is located. 4. Circular polarization grating according to one of claims to 3, characterized in that the spring (14,14a) a bow spring with two U-shaped spring clips (16, 16a) connected to one another via a transverse web (15, 15a). 5. circular polarization grating according to claim 4, characterized in that the distance between the two spring clips (16, 16a) is approximately equal to the clear outside width of the grid elements (5) and the end regions (23) of the grid elements (5) each with two lateral shoulders protruding beyond the clear outer width (b) of the grid elements (24) are formed, onto which the spring clips (16, 16a) can be attached, so that one of the clip legs (17,17a) on the side of the grid elements (5) facing the bearing bolt (13) and the other clamp leg (18,18a) is located on the side of the grid elements (5) facing away from the bearing pin (13). 6. Circular polarization grating according to one of the preceding claims characterized in that the one surrounding the bearing pin (13 ") Spring end (17,17a) is provided with an approximately semicircular offset (21,21a), the radius of which is somewhat is larger than the radius of the bearing pin (13) 7. circular polarization grating according to claim 5 or 6, characterized in that the end region of the clamp leg (18a) on the side of the grid elements (5) facing away from the bearing pin (13) with one on the grid element overlying approximately semicircular crank (22a) is provided. -Κ- VPA »^ 8. Circular polarization grating according to one of the claims to 7, characterized in that the ends of the clamp legs (17, 17a, 18a) away from the grid element (5) are turned. 9. Circular polarization grating according to one of the claims to 8, characterized in that the spring clips (16,16a) interconnecting transverse web (15,15a) is provided in such a way that it connects the clamp legs (18,18a) to the the side of the grid elements (5) facing away from the bearing pin (13) connects to one another. 10. Circular polarization grating according to one of the preceding Claims, characterized in that the spring (14) is made of wire. 11. Circular polarization grating according to one of claims to 9, characterized in that the spring (14a) made of sheet metal consists. 12. Circular polarization grating according to one of the preceding claims, characterized in that the rails (6,7) consist of U-profiles facing each other with the open sides, between the side legs (8) the Struts (9,10) and the grid elements (5) are mounted. 13 · circular polarization grating according to one of the preceding claims, characterized in that at least the grid elements (5) consist of electrically conductive, strip-like lamellae. 14. Circular polarization grating according to one of the preceding claims, characterized in that the bearing pin (13) for the grid elements (5) consist of cylindrical pins. - «- ^ * VPA 83P 1 98 IGE 15. Circular polarization grating according to one of the preceding Expectations, characterized in that the struts (9,10) fixed to the Rails (6,7) are mounted. 5