DE826458C - Tunable antenna for long waves - Google Patents

Description

The invention relates to a so-called long wave range in wireless communication, in particular radio broadcasting, usable tunable antenna. The realization such an antenna encounters many practical difficulties, mainly the following:

a) Dimensions of the antenna

It is well known that in the vicinity of the half-wave height, the effect of a vertical antenna design is achieved their optimum both in terms of radiation resistance and in terms of per power unit radiated field, but with the long, i. H. kilometric broadcast waves factors of a mechanical and economic nature make the use of a half-wave antenna impossible.

b) Width of the frequency range to be transmitted

The factor to be taken into account is known to be the quotient of the modulation frequency band and the frequency of the carrier wave. This factor reaches high values with long waves. However, the separation capability that a thread-like antenna has with a length that is significantly less than the length of the half-wave element does not allow the correct adaptation of the input impedance of the antenna in the entire range of the frequencies to be transmitted.

It is known in the field of medium and short waves in radio transmission as Antenna using a rigid metal mast, whose effective electrical length is the same half the wavelength. It is common practice to measure the geometric length of this mast To reduce the placement of a terminal capacitance at the top of the antenna. This final capacity, whose Radiation in itself is negligible can be made from

ίο a senior resting on the top of the mast Plate or a downwardly opening conductive cone. You can do the geometric Shorten the dimensions of the mast to about an eighth of the wavelength. The one in this Antennas designed in this way have a relatively good selectivity.

On the other hand, the technology of meter waves has led to the investigation of conical antennas. The results of the theoretical considerations and practical tests have shown that the such radiating structures transmitted frequency band is greater than that under the same conditions Frequency band transmitted by a thread-like air conductor of equal dimensions.

Using this knowledge gained for meter waves, according to the invention a vertical antenna that can be used in the area of long waves is primarily created in that a pole surrounded by radiating conductors in a cone shape with an end capacitance in shape a cone with the tip pointing upwards with adjustable length and thus the radiant one The main part of the antenna is formed by the first-mentioned cone with the mast as the axis. A Another feature of the antenna according to the invention is that the A'ersteifungsglieder securing this conical radiation structure in its rigidity are traversed by currents, the direction of which is chosen so that they generate a field, which partially cancels the field created by the parts of the structure acting as final capacity is broadcast and because of the direction opposite to the direction of the main field of its vertical component is harmful. A structurally and economically particularly advantageous design an antenna designed according to these guidelines is made possible by the fact that the parts the conical radiation pattern, if necessary to maintain the rigidity of the vertical Can let the structure of the antenna interact.

The drawing illustrates the antenna according to the invention, for example in one embodiment. Fig. Ι gives a side view of the antenna again and Fig. 2 is a course and direction diagram showing the currents in this antenna. Figs. 3 and 4 show on a larger scale the upper end of the antenna according to Fig. 1 in side view and in plan view. Fig. 5 and 6 show two modifications of a detail of the antenna according to Fig. 1. In all pictures the same parts are denoted by the same reference numerals.

According to Fig. 1, the antenna consists of three different parts:

a) One component of the antenna is formed with the aid of an insulator 2 inserted in between standing vertically on the ground mast 1, at the top of which is the platform 3, which like the Mast is made of steel. The height of the mast is at least equal to one eighth of the wavelength. The platform 3 carries a star-shaped structure 4 made of light metal, for. B. Duralumin, which consists of several, e.g. B. nine, triangular arms, which are hinged to the platform 3 (see Fig. 3 and 4) and are assembled from light metal tubes or light metal strips. The mast l is well known Way braced at three points of its height, and the metal cables 14 used for bracing are by isolators into sections of short length to reduce the strength of the ones flowing through them divided into electrical currents.

The rigidity of the light metal structure represented by the arms 4 is (see. Fig. 3 and 4) through the tension wires 5 attached to an extension 6 of the mast are secured. This extension 6 brings an improvement in the electrical behavior of the mast, so to speak, free of charge, as it Achieving the mechanical rigidity of the star-shaped structure consisting of the arms 4 is essential is.

b) The second component of the antenna according to Fig. i, 3 and 4 is the end capacitance, which is arranged at the top to increase the electrical length of the mast 1 and consists of the conductors 7 which, like the rods of an umbrella, the upper end of the mast τ surrounded by being arranged after the generatrix of a cone, the tip of which lies at a point of the extension 6 of the mast 1. At their lower ends, the conductors 7 are connected by insulators 9 with metal cables 8 holding them taut, which in turn are each connected to a holder inserted into the ground with the interposition of a mechanical adjustment device which allows a certain cable length to be released or drawn in and from a winch or can consist of a counterbalance regulator. Once adjustment is effected, one can, if desired, rigidly connect the lower ends of the cables 8 to a sturdy anchorage. u ₀

At their upper ends, the conductors 7 (see. Fig. 3) are on guide rollers 10. which are attached to the outer ends Ends of the arms 4 are mounted, each connected to a winch 13 arranged on the platform 3, which mechanically at will the useful length of the ladder 7. d. H. the distance between the rollers το and the isolators 9 allowed. Namely, the value of the final capacitance which the antenna charges is a function this part of the total length of the conductors 7, and this also applies to the electrical length of the antenna. With the roles το are not only the conductor 7 resting on them, but also the Tension wires 5 in electrical contact. The winches 13 can be made by any equivalent device be replaced which is the effective length

the ladder 7 individually or simultaneously from the platform 3 or to regulate from the foot of the mast 1.

c) The third component of the antenna according to Fig. i, 3 and 4 is the radiation structure, which is composed of several ladders 11 provided in the same number as the arms 4, whose upper ends (see Fig. 3) are in electrical contact with the rollers το and in their Are attached near the arms 4 and their lower ends at the foot of the mast 1 (see. Fig. 1) directly or via a connecting link to the non-illustrated feed line connection to have. In; electrical relationship behave this z. B. nine conductors 11 at the frequencies considered like a coherent conductive cone with mast 1 as its axis. As is well known the frequency band passing through such a radiating structure is wider than that of a radiating structure of smaller cross-section.

The ladder 11 can be used to maintain the Rigidity of the vertical body of the antenna cooperate and for this purpose made of metal cables, z. B. made of steel wires. Under certain circumstances you can also use this mechanical one .Advantage and omit the conductors from copper wire and only use it for electrical power supply. For the individual ladder ι r can not shown clamping devices such. B. in the form of counterweights on which The foot of the mate 1 may be provided to which the conductors 11 are electrically connected in some way are.

In the extension 6 of the mast 1 can (see. Fig. 3) a rod 12 in the form of a tube or a bar of relatively small cross-section be slidably disposed over the The mast extension protrudes and may be used to regulate the antenna during operation can while the previous scheme in retirement of the antenna by setting the effective Length of the ladder 7 is reached.

The effective length of the conductor 7 can also from the connection point of the tensioning cable 8 by a Winch or a similar device can be adjustable and herel> ei each ladder 7 at its upper End under the action of a counterweight arranged on the platform for the purpose of balancing the on him ülx> r the tensioning cable 8 are tensile stress exerted. One can also use such a balance weight Provide longitudinally displaceable on each of the conductors 11 and parallel to this through a Guide means hold the end of the corresponding conductor 7. The one attacking the end of the conductor 7 Counterweight preserves the rigidity of the whole Antenna formation and is when a train from the lower end of the cable 8 is exerted on the conductor 7 will increase, and vice versa, when a certain length of the cable 8 is released at the mast base will, lower and thereby take the conductor 7 and thereby the insulator 9 according to the Lift up roller 10. The cross-sections of the conductors 7 and the tension wires 5 can be fulfilled depending on ! the mechanical conditions be the same or different.

Fig. 2 shows schematically the distribution and direction of the currents in the various conductors of the antenna according to Fig. 1, 3 and 4. The conductors n are supplied with current at the foot of the mast 1 through a connection cell connected to the feed line. At the upper end of the conductor 11, the through current flowing ladder 7 divides at the rollers 10 between the final capacity of the mast 1 representing and guaranteeing the rigidity of the star-shaped structure 4 tensioning wires 5. The power distribution is essentially dependent on the on the rollers ¹ 10 given by the individual conductors 7 and wires 5 impedances.

The electromagnetic emitted by the conductors 7 Field has a perpendicular component of a sense of direction that is to the direction of the main field emitted by the conductors 11 is opposite. That by the streams in the Tension wires 5 generated electromagnetic field, however, has a vertical component that adds itself to the main field.

The opposing field emitted by the conductors 7 is less, the shorter these conductors are geometrically. It is therefore desirable to extend it by parts whose total radiation is zero. This leads to the cone formed by the conductors 7 as shown in FIG. 5 being supplemented by a polygonal conductor 15 which connects the lower ends of the conductors 7. In order to nevertheless enable the effective length of the conductor 7 to be regulated, the polygonal conductor 15 can preferably be designed according to a shape-variable line layout. Fig. 5 shows a possible embodiment for this, in which the length of the conductors 7, when the tensioning cables 8 are subjected to tensile stress, can be changed to a certain extent while maintaining a tensioned overall wire structure. According to Fig. 5, the tensioning cable 8 with points B _1, B ₂ ... B ₉ connected to the Vielecksleiters 15, each successive equidistant from two connection points A _1, A, and A _2, A _3. . . A _s , A _{g of} the conductors 7 lie, and the length of the conductor 15 is dimensioned so that, when the effective length of the conductors 7 is set to the maximum value, it assumes the shape of a regular polygon, while with shorter lengths it assumes the shape of a regular polygon Head 7 merges into a star-shaped polygon in which the angles at the star tips B ₁ , B ₂ ... B ₉ are smaller, the shorter the length of the conductor 7.

The polygonal conductor 15 can be made particularly elastic according to Fig. 6 in that its corners are replaced by joint parallelograms formed from wires A ₁ , B ₁ , C ₁ , D ₁ ... A%, B9, Ca, Dg , in which the two opposite corners C ₁ and D ₁ ... C ₉ and D _{9 are} connected to the correspondingly subdivided polygonal conductor 15, while each of the two other corners A ₁ and / ^ ₁ ... A ₉ and B _{9 has} one A ₁ . . . A _{9 is connected} to a conductor 7 and the other B ₁ ... B _{9 is} connected to a tensioning cable 8 via an insulator 9. at

an increase in the effective length of the ladder 7, the points A ₁ . . . Remove A ₉ from the center of symmetry of the entire wire structure and try to widen the joint parallelograms. The points B ₁ and C ₁ ... B ₉ and C _{9 will increase} in their mutual spacing sufficiently to compensate for the increase in length of the sides of the circumscribed polygon, the radius of which has lengthened. Conversely, the effective length of the conductor 7, the points A ₁ ... A ₀ approaching the center of the wireform and the Gelenkparallelograjnme increased with a decrease, so that an approximation of the points C ₁ and D ₁ ... D ₉ and C ₉ entry.

Both when lengthening and shortening the ladder 7, the displacements of points B ₁ ... B ₉ remain far below the displacements of points A ₁ . . . A ₉ . The displacement stroke of this arrangement is naturally very limited. In order to enable adjustment in a larger range, the length of the polygonal conductor 15 must be changed. Instead of articulated parallelograms, other shape-variable intermediate members of a known type that produce the desired elasticity of the entire wire structure can also be switched into the polygonal conductor.

In the particularly simple embodiment of the antenna shown in the drawing according to the Invention can control the distribution of currents between the wire-shaped conductors and the mast as a result of the electrical power available at several points Connection of these parts takes place, an effect on the inlet reactance and the selectivity the antenna as well as the radiation resistance. Therefore, after further training of the inventive concept, this current distribution can possibly be influenced by that you have insulating links or conductors with equivalent reactance, in particular to the Inserting contact points between the mast and the wire-shaped conductors.

Claims (6)

PATENT CLAIMS: ι. Tunable antenna for the long wave range the radio transmission, characterized in that a vertical, with his Base on an insulator (2) resting mast (1) of about one eighth of the wavelength the same length at its tip carries a platform (3) to which a star-shaped, from Light metal structure composed of strips or tubes (4) is hinged that also several wire-shaped, radiating conductors (11) according to the generators of a mast (1) surrounding the axis and with the tip close to the Mast foot ending cone are arranged and this group of ladders (11) at the top Ends in electrical contact with a second group of conductors (7) of adjustable length which is mechanically connected to the free ends of the star-shaped light metal structure (4) and after the generatrices one that widens downwards and becomes a point aligned a point in an extension (6) of the mast (1) having cone are (Fig. 1). 2. Antenna according to claim 1, characterized in that at the free ends of the star-shaped Light metal structure (4) rollers (10) are attached, over which the radiant Head (7) are guided, which represent a downwardly open cone (Fig. 3). 3. Antenna according to claim 1 and 2, characterized in that the one open at the bottom Cone-forming conductors (7) are tensioned by cables (8) anchored to the floor (Fig. 1). 4. Antenna according to claim 1 to 3, characterized in that the guided over the rollers (10) Ladder (7) by one or more arranged on the platform (3) of the mast (1) Winches (13) can be wound and unwound and the tensioning cables (8) anchored on the ground by regulating devices Can be extended or shortened (Fig. ι and 3). 5. Antenna according to one of claims 1 to 4, characterized in that the electrical connection between the one tapering downwards Conical group of conductors (11) and the mast (1) given by impedances is necessary for the favorable current distribution between these conductors (11) and the mast (1) are selected (Fig. 1, 3 and 4). 6. Antenna according to one of claims 1 to 5, characterized in that the conductor (7) representing an upwardly tapering cone is connected to one another by a polygonal conductor (15) and shape-variable conductive intermediate members (A ₁ , B ₁ , C ₁ , D ₁ ... A ₉ , B ₉ , C ₉ , D ₉ ) are provided to enable the effective lengths of these conductors to be set (Fig. 6). 1 sheet of drawings 1 2652 12.