DE4438809B4 - Dipolspeiseanordnung - Google Patents

Abstract

Arrangement for the symmetrical feeding of at least one dipole (1, 2) arranged at a distance in front of a reflector surface (4) via an asymmetrical strip line which has a strip conductor (8) which is arranged at a distance between a reflector surface (4) and a parallel one at a distance from it another conductive counter surface (30) is arranged,
characterized by the following features:
a) the conductor strip (8) extending parallel to the reflector surface (4) ends without a connection;
b) the conductor strip (8) is surrounded by two conductor parts (9, 10) which are U-shaped in cross section and are arranged at a distance (11) from one another in the longitudinal direction of the strip conductor (8);
c) at the mutually facing ends (12, 13) of these conductor parts (9, 10) branch transversely to the conductor strip (8) connecting strips (5, 6; 31, 32; 6 ', 31', 32 ') from the distance are arranged parallel to one another, project through an opening (7) in the reflector surface (4) to the front of the reflector and are connected at their ends to the dipole halves (1, 2);
d) those of the facing ...

Description

The Invention relates to an arrangement for symmetrical dining or more dipoles arranged at a distance in front of a reflector surface over one unbalanced stripline.

In the previously common dipole feed arrangements with direct feed via an asymmetrical line, a galvanic contact must be established between the inner conductor of the asymmetrical feed line and the one dipole half (e.g. after DE 43 02 905 C1 ). This also applies if this asymmetrical feed line is designed as a strip line. The production of a long-term reliable galvanic contact requires a certain amount of effort with antennas, such contact points are often a cause of failure even with careful processing after many years of use.

It is also known to feed dipoles via a balun (balun) and thus convert the unbalanced feed line into a symmetrical feed line ( US 2,327,418 ). Such balancing transformers can also be constructed using stripline technology ( US 4,755,775 or GB 2 089 135 A ), whereby it is also known to design the asymmetrical feed line as a middle strip line between two strip lines arranged at a distance and to let the end of the middle strip line end without a connection ( GB 2 089 135 A ). In addition, it is known to produce the dipoles and their symmetrical supports from the material of the reflector in a directional antenna. Here, however, a galvanic contact must again be made between the inner conductor of the unbalanced feed line and the one dipole half ( DE 4 302 905 C1 ).

It it is an object of the invention to provide a feed arrangement of this type, those unreliable Avoids contact points.

This Task is based on a food arrangement according to the generic term of the main claim solved by its characteristic features. advantageous Further training results from the subclaims.

at the feed arrangement according to the invention is a galvanic, electrically conductive contact between the stripline the unbalanced stripline and the dipole, the Stripline ends without connection. The two dipole halves are over connection strips only with the two additional ones insulated on the conductor strips at an axial distance from each other Conductor parts galvanically connected and these parts can therefore very easily and cheaply made by punching and bending from a piece of sheet metal be, additional galvanic connection points by soldering, screwing or the like become superfluous. A Feed arrangement according to the invention is therefore not only very simple and inexpensive to manufacture, but also extremely reliable, failure due to bad contacts is impossible. The feed arrangement according to the invention is also suitable for the feeding of several dipoles grouped together, such as to increase of antenna gain can be used.

The Invention is based on schematic drawings an embodiment explained in more detail.

1 shows a perspective view of a feed arrangement according to the invention, 2 shows the associated cross section along the section line II.

1 shows one of two dipole halves 1 and 2 existing dipole, which is formed in the embodiment shown as a half-wave dipole. This dipole could also be designed as a whole-wave dipole, the two dipole halves 1 . 2 can also have different lengths and have any cross-sectional shape. These two dipole halves 1 . 2 are at a distance 3 before one for the sake of clarity 1 only a fragmentary reflector surface 4 arranged. The two dipole halves 1 . 2 are at the upper ends of two spaced apart and parallel connection strips 5 . 6 attached through an opening 7 of the reflector 4 extend to the back and the symmetrical feed line for the dipole 1 . 2 form. The connection strips 5 . 6 are preferably in one piece with the dipole halves 1 . 2 punched out of a piece of sheet metal and bent. The opposing conductor surfaces of these two connection strips 5 . 6 and their distance is chosen so that the wave resistance thus formed between the two dipole halves 1 . 2 existing dipole impedance is transformed to a desired output impedance at its terminal ends behind the reflector. On the connection strip 5 . 6 For this purpose, additional sheet metal bends can be provided over part or the entire length in order to achieve an expanded range of the impedance transformation.

In the exemplary embodiment shown, the connection to the transmitter or receiver is made via a strip line, which is shown in FIG another line type, for example a coaxial cable, can pass over. The stripline is parallel by a distance between the reflector surface 4 and a rear wall arranged parallel to the reflector 30 , for example a stripline guided by a mast 8th educated. On this stripline 8th are two conductor parts bent in a U-shaped cross section 9 and 10 put on and in such a way that according to the sectional view 2 a distance from the stripline on all sides 8th have. In the longitudinal extension of the stripline 8th are the two parts of the ladder 9 . 10 immediately below the opening 7 of the reflector 4 at a distance 11 arranged from each other. With the ends facing each other 12 . 13 of the two ladder parts 9 . 10 stand through the opening 7 connecting strips projecting downwards 5 . 6 the dipole feed line in connection, they are in turn preferably made directly from a piece of sheet metal with the conductor parts. The ends 12 . 13 opposite ends of the two conductor parts 9 . 10 are over flanges bent up and down 14 . 14 ' and 15 . 15 galvanically on the reflector 4 or the back wall 30 attached. The one between the ladder parts 9 . 10 arranged stripline 8th ends without a connection in the distance 16 from the short end 14 of the conductor part facing away from the asymmetrical strip line 9 , The lengths of each of the ladder parts 9 . 10 are equal and, for example in the vicinity of λ / 4, are chosen so that their impedance is greater than that due to the symmetrical line 5 . 6 transformed dipole impedance is high. Between the two parts of the ladder 9 . 10 and the reflector surface arranged at a distance from it 4 or rear wall 30 a kind of pot circle is formed.

The U-shaped conductor parts 9 . 10 with their connecting flanges 14 . 14 ' . 15 . 15 ' , the connecting strip branching from it 5 . 6 and the dipole halves 1 . 2 are preferably cut in one piece from a sheet and bent accordingly, they are including the dipole halves 1 . 2 through the flange fastenings 14 . 14 ' . 15 . 15 ' on the reflector 4 or the back wall 30 mechanically held. If necessary, the conductor strip 8th be mechanically supported by one or more dielectric supports, otherwise all parts are electrically insulated from each other by air at their specified distance.

The width 17 the U-leg of the two conductor parts 9 . 10 , their mutual distance 18 and the width and thickness of the stripline 8th and also the axial length of the conductor parts 9 . 10 are selected so that high-frequency currents - indicated by the current arrows - on the wave resistance and the resulting frequency-dependent impedance on the two conductor parts 19 and 20 - are forced at the opposite connection points 12 . 13 the connecting strip 5 . 6 the dipole feed line are the same size, so that on the connecting strip 5 . 6 Correspondingly equal phase feed currents 23 . 24 and thus corresponding equal currents 25 . 26 on the dipole halves 1 . 2 flow. To achieve the required impedance between the conductor parts 9 . 10 and the stripline 8th Both the conductor parts and this conductor strip can have correspondingly different dimensions in the longitudinal extent of the conductor strip, as is the case for the strip conductor 8th through the changes in width 27 . 28 in 1 is indicated schematically. For one-sided power consumption from the conductor parts 9 . 10 to the dipole halves via the connection strips 5 . 6 the conductive connection of the two U-legs of the conductor parts through the U-back is required, the conductor parts are parallel to the reflector 4 arranged that their U-legs each in parallel planes to the reflector 4 lie and their opening is to the side. The characteristic impedance is also selected so that when using this feed arrangement with a transmit dipole, the unbalanced stripline 8th . 4 supplied transmitter energy at the through the inlet of the conductor part 10 formed joint is reflected as little as possible.

If on the the reflector 4 opposite side of the stripline 8th no additional back wall 30 is provided as a partial return conductor, the lower U-legs of the conductor parts 9 . 10 omitted, the conductor parts are then only narrow sheet metal strips between the reflector 4 and stripline 8th are arranged and at their ends with the connecting strips 5 . 6 or the turns 14 . 15 with the reflector 4 are connected.

In the embodiment according to 1 is just a single dipole 1 . 2 shown, the feed arrangement according to the invention is, however, equally well suited for the simultaneous feed of a plurality of dipoles connected in parallel, which are either parallel to one another in front of the same reflector surface 4 are arranged and emit in the same direction, in this case, branches from the connection ends 12 . 13 of the two conductor parts, the associated dipole connection strips are not like the strips 5 . 6 vertically upwards, but for example on both sides laterally at an angle, as is the case with the stripes 31 . 32 is indicated by dashed lines. In some cases, the rear wall can also be used 30 be designed as a reflector and here too a single dipole radiating to the rear or, if necessary, a plurality of dipoles can be arranged, which in this case have connection strips 5 ' 6 ' or 31 ' . 32 ' through a corresponding opening in the rear wall 30 branch off to the rear, this way it is also possible to set up omnidirectional antennas in which lateral reflector surfaces are also provided.

Claims (6)

Arrangement for symmetrical feeding of at least one in front of a reflector surface ( 4 ) arranged dipoles ( 1 . 2 ) via an unbalanced stripline that connects a stripline ( 8th ), the distance between a reflector surface ( 4 ) and a further conductive counter surface arranged parallel and at a distance from it ( 30 ) is characterized by the following features: a) which is parallel to the reflector surface ( 4 ) extending conductor strips ( 8th ) ends without a connection; b) the conductor strip ( 8th ) surround two conductor parts with a U-shaped cross section ( 9 . 10 ) in the longitudinal direction of the stripline ( 8th ) at a distance ( 11 ) are arranged from each other; c) at the mutually facing ends ( 12 . 13 ) of these ladder parts ( 9 . 10 ) branches across the conductor strip ( 8th ) Connection strips ( 5 . 6 ; 31 . 32 ; 6 ' . 31 ' . 32 ' ), which are arranged parallel to each other at a distance, through an opening ( 7 ) of the reflector surface ( 4 ) protrude to the front of the reflector and at their ends with the dipole halves ( 1 . 2 ) are connected; d) the ends facing each other ( 12 . 13 ) opposite ends of the two conductor parts ( 9 . 10 ) are above conductor sections ( 14 . 14 ' . 15 . 15 ' ) with the reflector ( 4 ) or the counter surface ( 30 ) galvanically connected. Arrangement according to claim 1, characterized in that the dimensions ( 17 . 18 ) of the ladder parts ( 9 . 10 ) and their distance from the conductor strip ( 8th ), the reflector surface ( 4 ) and the counter surface ( 30 ) are selected so that at the branch point ( 12 . 13 ) the dipole connector strip ( 5 . 6 ) and along these currents of the same magnitude in opposite phases ( 19 . 20 . 23 . 24 ) flow. Arrangement according to claim 1 or 2, characterized in that the U-shaped conductor parts ( 9 . 10 ) laterally in the direction parallel to the reflector surface ( 4 ) are open. Arrangement according to one of the preceding claims, characterized in that at the mutually facing ends ( 12 . 13 ) of the two ladder parts ( 9 . 10 ) in different directions across the conductor strip ( 8th ) several connection strips each ( 31 . 32 ; 6 ' . 31 ' . 32 ' ) branch off for two or more dipoles. Arrangement according to one of the preceding claims, characterized in that on the dipole connection strips (spaced parallel to one another) ( 5 . 6 ) mutually facing additional conductor surfaces which contribute to the impedance transformation are formed. Arrangement according to one of the preceding claims, characterized in that the two conductor parts ( 9 . 10 ) with the branching connection strips ( 5 . 6 ), the angled conductor sections ( 14 . 14 ' . 15 . 15 ' ) and the associated dipole halves ( 1 . 2 ) each consist of a correspondingly bent one-piece sheet metal blank.