DE756558C - Directional antenna system for generating guide beams - Google Patents

Description

Directional antenna systems are known for generating two ^{guide beams offset by 180 a} / which consist of a continuously fed center dipole and two alternately scanned radiation-coupled reflectors arranged on both sides of the transmitting dipole. With directional antennas of this type, it has proven to be expedient to supply the energy to the transmitting dipole on one side, in that the feed line runs within the one tube-shaped or trap-shaped dipole half. At the point where the feed line enters the radiator, an electrical blocking element must then be switched on so as not to disturb the dipole properties of the radiator. A special embodiment of such a blocking element, which is particularly useful for the shortest wavelengths, is the so-called A / 4 blocking cup. Because of the low degree of attenuation, such a structure has an extremely sharp resonance effect, in complete contrast to the radiator itself.

In order now to take advantage of this good blocking effect not to the exact compliance the operating frequency with regard to the sharpness of resonance of the locking member

the invention turns to a directional antenna system for generating two i8o ° offset guide rays, which from a in the aforementioned manner via a coaxial Power line continuously fed dipole and two alternately keyed, radiation-coupled There are reflectors, in front of the point at which the coaxial line merges into the oscillating dipole, in the course of this ίο Line two designed as flywheel circles Switch on locking pots one behind the other and dimension them in such a way that the feed line is decoupled for a larger frequency range. A band filter effect is achieved by this measure.

The concept of the invention is explained below with the aid of a description of the construction explained in more detail.

Fig. Ι shows the elevation of a directional beam system, that the invention is based on, while

Fig. 2 shows the side view; Fig. 3 is a side section through the structure in Fig. 1, taken along the section plane 3-3 to the side view to illustrate the main dipole;

Fig. 4 shows a front view of the main beam dipole according to Fig. 1, with details;

Figs. 5 to 8 show the structural design of the individual parts, in particular that in Fig. 4 labeled 5, 6, 7.

From Fig. 1 it can be seen that the main dipole 10 is fed from the lower end via a coaxial line consisting of the inner wire ττ ^Α and the jacket n ^B. It is carried by a mast 13 (see also Fig. 3). The latter has a transverse arm 14, at the extreme ends of which the vertical supports are adjustably attached so that their distance from the mast 13 can be changed. The reflector dipoles 16 and 17, which are identical to one another, sit on the vertical supports 15. Both halves 18 of each reflector are provided with slidable ends 19 for regulating the length, whereby the dipoles can be tuned. In each case a central part 20, 21 in the form of a weatherproof housing contains a push button relay which is actuated by the line 22 and 23, respectively. The contacts of the relay 20 are arranged so that they connect the two halves of the dipole 16 in the rest state; in the case of the relay 21, the reverse is the case with respect to the two members 18 of the dipole 17. The operating characteristics of the two relays 20 and 21 are, as usual, related to one another in such a way that when the two relays are excited at the same time, the relay 20 opens its contacts before the relay 21 closes its contacts. Conversely, if the excitation of the two relays ceases at the same time, the relay 21 opens its contacts first.

The lines 22 and 23 are laid perpendicular to the secondary dipoles and also to the main dipole 10, so that the lines lie transversely to the polarization direction of the radiation field. The lines 22 and 23 are expediently provided with throttles which can be accommodated in the housings of the relays 20 and 21; further chokes, e.g. B. 24, can be provided close to the main dipole 10. At the junction 31 of the dipole 10, the lines 22 and 23 are connected to the two halves 5 and 6 of the dipole 10, as shown in more detail in Figs. 4 and 8, so that the coaxial power line also transmits the DC keys.

The structure of the main dipole 10 can be seen in detail in FIGS. 4, 5, 6, 7 and 8. From Fig. 4 it can be seen that the main dipole has a lower part 5 and an upper part 6, which are mechanically held together by means of the main connection 31; it also includes an auxiliary part 7 (Figs. 4 and 7). The parts 5 and 7 are mechanically united by the threaded continuous inner tube, as can be seen more clearly from FIGS. 5, 7 and 8. The main connection 31 of the main dipole 10 is protected by a wooden housing (Fig. 4 and S). The upper dipole half 6 is protected by an insulating tube 32 which rests on the housing 31. A cap 33 protects the upper end of the protective tube 32 against the ingress of moisture and dirt. A lower protective tube 34 (Fig. 4) similar to the protective tube 32 envelops the lower dipole half 5 and the auxiliary part 7; the protective tube 34 is held in place by a clamp 35 and is also attached to the underside of the housing 31 (Fig. 8). The construction of parts 5 and 7 embodies the features of the invention; the exact construction of these parts, as well as the other parts that make up the main dipole, is clearly illustrated in Figs. 5, 6, 7 and 8. It can be seen in particular from FIG. 5 that the lower dipole half 5 contains an inner tube 40 which is displaceable ^{over the outer jacket ii ß.} The tube 40 is surrounded by a further tube 41 and connected to it in a conductive and rigid manner by means of the disk 42. An insulating ring 43 ensures the centering at the lower end of 41. At this point, a cylinder ring 44 is also arranged longitudinally displaceable on the outer surface of 41, conductively connected via the ring 45. A wipe in the cylindrical space 44 and the end of the Rohres 41 iiineinragender and with these a capacity

forming cylinder ring 46 is screwed onto the tube 40 so that it is in the axial direction can be finely adjusted to change the capacity between 41, 44 and 46. One Lock nut 47 is provided to lock cylinder 46 after adjusting in position to keep.

A tube 49 is likewise arranged displaceably above the tube 41, the lower end of which can be clamped by means of a clamp 50. The upper end of the outer tube 49 is connected by a brass disc 51 to the jacket ii- ⁸ in connection by this disc is clamped between the metal frame 52 and nut 53rd The socket 52, for its part, is ^{soldered to the jackets 5} and provided at its upper end with an external thread for the nut 53. The interior of the socket 52 contains an insulating bushing through which the inner wire ττ ^Α passes.

It can be seen that part 5, ie the lower dipole half, consists of two parts which can be longitudinally displaced into one another, one of which comprises the outer tube 49, the socket 52 including nut 53, the jacket n ^ß and the inner vein ιι ^λ as a rigid whole. The other comprises the inner tube 40 together with washers 42 and 43 and the tube 41. Furthermore, this includes the sleeves 44 and 46 with lock nut 47, even if these components, as described, are not actually fixed with respect to the tube 41 or 41 ' are. In order to adjust the total length of the lower dipole half 5, one only needs to loosen the clamp 50 and then move the tube 41 with accessories telescopically along the jackets ⁵ .

From Fig. 6, which shows the upper dipole half 6 in itself, it can be seen that this consists of a main tube 60, which is closed after the Dipolmftte by a metal disc 61 into which the inner conductor II- ⁴ is screwed. A spacer ring 56 (Fig. 8) ensures a certain distance between the disc 61 and the socket 52. Inside the main pipe 60 is an extendable pipe section 62, the upper end of which is closed by a brass disc 63 soldered to it. This is used to adjust the length of the upper dipole half 6; after the correct setting has been achieved, the extension tube is held in place by tightening a clamp 65.

In Fig. 7 the auxiliary part 7 is shown, the structure of which is that of the one already described Part 5 is basically similar. An outer tube 70 is adjustable on the same inner tube 40 attached, which also carries the tube 41. About the axial displacement of the pipe 70, the tube 40 is threaded near the lower end, to screw on a brass disk 71, which is soldered to the end of 70. The lock nut 72 is used to fix it. 73 is again an insulating ring around the Distance tube 70 also at the upper end. As it is beneficial to be able to the sleeve 46 (Fig. 5) to be able to remove without the entire length of the tube 40 with Having to provide a thread, the latter is designed in two parts, with a pipe socket 74 ensures cohesion.

Near the upper end, the tube 70, in contact with it via the ring γβ , surrounds a short tube piece 75. Another cylinder ring yj, adjustable by means of a thread, plunges into the space thus formed between 70 and 75. The purpose of this arrangement forming the actual invention, as well as the analogous one according to FIG. 5, will be described further below.

The manner in which the described parts 5, 6 and 7 are arranged and connected to one another in order to form the main dipole 10 can best be seen in FIGS. As already indicated in connection with the description of FIGS. 5 and 7, the inner tube 40 g ₀ produces the mechanical connection between the parts 5 and 7. Therefore, if the length of the lower dipole half 5 is initially changed by moving the tube 41 up or down, the distance between the adjacent ends of the parts 5 and 7 is maintained. Likewise, the adjustment ^ of the extension tube 62 upwards or downwards within the upper dipole half 60 (Fig. 6) without affecting the mutual distance between parts 6 and 5 Isolators 81 are attached.

At the lower end of the conduit 11 at the exit of the protective tube 34, an appropriate insulating and airtight seal is provided, and optionally may also means are provided around the inside of the tube n- ⁸ with a gas under ordinary no Lichem or elevated Keep pressure filled.

Having fully described the exact nature of a preferred embodiment of the invention, the operation will now be briefly set forth. n ₅

The lower part of the tube 41 (below the disk 42) with the sleeve 44 attached forms together with the central sleeve 46 and the inner tube 40 a flywheel resonance circuit (so-called lock pot), which can be tuned by changing the capacity between the sleeve 46 and the cylindrical surfaces of the

Parts 44 ^and 4 ¹ · To roughly change the capacity, the outermost cylinder ring 44 is shifted. A fine adjustment can be easily made by turning the ring 46 on the thread.

A second resonance circuit is formed with the help of part 7. The effective elements here are the outer tube 70 with the sleeve 75 attached, the cylinder γγ and the inner tube 40. The coordination is carried out in the same way as in part 5.

The first resonance circuit prevents the feed current from flowing back on the Outer skin of the lower half of the dipole. This resonance circuit is naturally very resonance-sharp, d. H. it can only be used for a single frequency used or it would have to be retuned for each frequency. In order to avoid this, the second resonance circuit is provided according to the invention, which is more or less coupled to the first resonance circuit. This creates a about a band filter-like effect, d. H. within a certain frequency range, the Interference currents are prevented from flowing, and at the same time the feed line is completely decoupled.

Claims (2)

Patent claims: i. Directional antenna system for generating two guide beams offset by 180 °, Consists of a dipole that is passed by a transmitter in the axial direction one-sided supplied coaxial power line is continuously fed, and two alternately keyed, radiation-coupled ones arranged on both sides of the transmitting dipole Reflectors, characterized in that at the point where the coaxial line enters the oscillating Dipole passes, in the course of this line two designed as flywheel circles Locking pots are connected in series and dimensioned such that the feed line is decoupled for a larger frequency range. 2. Directional antenna system according to claim 1, characterized in that inside of the coaxial line auxiliary lines for the push button relays of the reflectors are laid. 50 To differentiate the subject matter of the invention from the state of the art, the granting procedure the following publications have been considered: German patent specification No. 549 857,
577 35 °. 600 on; French Patent No. 816 120; British Patent No. 414296; U.S. Patent No. 1,831,921. For this purpose 2 sheets of drawings 1 5527 10.