DE2510825A1 - Flexible rod type antenna - rod being held to mounting by plastic spiral spring contg contacting coil - Google Patents

Abstract

A flexible rod type antenna, partic. for use in portable broadcasting instrumentation or devices of a similar type having the antenna rod held within the foot type mounting section by means of a spiral spring, has the spiral spring composed of a contacting coil of windings which are compressed together one on top of another. The spring is manufactured from a plastic of polyolefinic type and has a coil diameter 2-10 times the diameter of the wire forming the coil.

Description

Flexible rod antenna The invention relates to a flexible rod antenna, In particular for portable radios or the like. Their held in a foot part Antenna rod is designed as a helical spring.

Rod antennas for portable radios or other mobile wireless devices Communication devices should be flexible to a particularly high degree and should be used according to each Return to the original position. An aperiodic, mechanical one Swinging into the rest position is particularly important in use of less importance on portable radios.

A whip antenna is disclosed in German Offenlegungsschrift 1 802 094 known for motor vehicles whose antenna rod has a coil spring with a to be attached to the motor vehicle antenna base is mechanically connected. The electric The antenna rod is connected to the communication device, e.g. a receiver via a conductor passed through the helical spring. The flexibility of a However, such a rod antenna is sufficient when used on a portable communication device not off: The greatest possible damage-free deflection from the rest position should are less than + 60 °.

Rod antennas made from a steel band are more flexible.

However, the flexibility is not in all directions of deflection guaranteed, since the steel band is not bent in the direction of its width extension can be.

Finally, a vehicle antenna has also become known (German Utility model 7 418 783), the antenna rod for shortening the mechanical antenna length compared to the electrical antenna length from one in the form of a compression spring with spaced turns spiral-shaped conductor consists.

The compression spring is surrounded by plastic. The flexibility of this Vehicle antenna is also limited; there are only deflections of + 450 accessible from the rest position.

The object of the invention is to provide a flexible rod antenna, which can be deflected on all sides by any angle without damage, and which then resumes the original rod shape of the rest position. In particular should the Rod antenna can be bent or rolled into a circle can.

Based on the flexible rod antennas explained in more detail at the beginning the invention solves this problem in that the helical spring is wound adjacent and has turns elastically pressed against one another. The coil spring contributes this configuration as a tension spring; she can easily go by at least 3600 their rest position are deflected without having to fear permanent deformation. In addition, the rod antenna can be manufactured cheaply because of such coil springs can be produced "endlessly".

It has proven to be advantageous if the inner diameter of the helical spring is in the order of magnitude of the wire diameter of the helical spring, preferably is chosen between two to ten times the wire diameter. This will on the one hand sufficient flexibility is ensured and on the other hand it is secure Raising back up from any position is guaranteed.

In an advantageous embodiment it is provided that the helical spring over its entire length by an electrical one arranged inside the helical spring Short-circuit conductor is short-circuited. The electrical length of the antenna rod remains thus constant even with a deflection from its rest position.

Furthermore, it can be provided that the helical spring with a matt black Shrink tubing is coated from a plastic based on polyolefin. this has not only the advantage of the non-glare antenna rod, but the antenna rod is also electrically insulated and protected against corrosion.

Another embodiment of the invention, which also applies to other embodiments of rod antennas can be of importance, is characterized in that the foot part is designed as a coaxial line, the outer conductor of which is attached to the antenna rod remote end as an outer conductor connection of a coaxial connector serving union holder, preferably carries a union nut and its inner conductor carries the antenna rod at one end and as an inner conductor connection at the other end the coaxial connector is formed in which between the inner conductor and an insulating sleeve is arranged on the outer conductor. That way, the one with the Inner conductor connection of the coaxial connector mechanically connected to the antenna rod be relieved. The tubular outer conductor supports the inner conductor on which the The antenna rod is attached to the swivel mount.

To attach the inner conductor and the outer conductor to each other can the inner conductor and / or the outer conductor screwed onto the insulating sleeve and / or to be glued. In particular, gluing the inner conductor into the insulating sleeve has the advantage that the one at the exit end face of the insulating sleeve between the The antenna rod and the annular gap remaining in the insulating sleeve are sealed by adhesive and moisture penetration can be prevented.

An embodiment that is characterized by simple assembly and is also cheap to manufacture due to the simple shape of the parts characterized in that one end of the insulating sleeve extends over the antenna rod the facing end of the outer conductor engages and an internal thread at its other end carries, into which the inner conductor can be screwed and that between the cap holder and the end of the designed as an inner conductor connection Inner conductor an insulator attached to the inner conductor is provided, which with its the Antenna rod facing end face sits on a ring shoulder of the outer conductor.

The insulating sleeve and the outer conductor can be made with simple molding tools, e.g. by injection molding.

To assemble the rod antenna only the insulating sleeve has to be put together with the tubular outer conductor via the antenna rod attached to the inner conductor pushed and the insulating sleeve screwed to the inner conductor.

A further simplification results when the ÜberwurShalterung is formed in one piece with the outer conductor and the inner diameter of the cap holder to form the ring shoulder is chosen larger than the inner diameter of the outer conductor. Is the clear distance between the insulating body and the one over the face of the Outer conductor gripping end of the insulating sleeve greater than the distance between this end face from the ring shoulder, so when connecting the rod antenna to the counterpart the coaxial connector, the union holder can be rotated freely, whereby prevents damage to the inner conductor connection of the coaxial connector will.

A major advantage of the foot part explained above is that it is the electrically shielded, as well as mechanically protected installation of a Transformation link allows.

The transformation element is here in series with one within the Outer conductor located part of the inner conductor switched. When training the transformation link as an inductance extending the electrical length of the rod antenna, a Coil connected to an interruption in the inner conductor or the inner conductor in a spiral shape be trained.

In the following, an embodiment of the invention will be based on Drawings are explained in more detail, namely: Fig. 1 is a perspective overall view a flexible rod antenna, Fig. 2 is a partial section through a foot part of a first embodiment of the rod antenna; Fig. 3 is a shortened, partially sectioned Representation of an antenna rod and its attachment in the foot part and FIG. 4 a Sectional view of another embodiment of a rod antenna, in which in the foot part a coaxially arranged coil is provided.

Fig. 1 shows a flexible rod antenna, the antenna rod 1 on a End is provided with a cap 3 and attached to a foot part 5 at the other end is. The foot part 5 has at its end facing away from the antenna rod 1 for connection the rod antenna has a coaxial connector 7, the outer conductor connection 9 is designed as a union nut provided with an internal thread 11. 13 designated an inner conductor connection of the coaxial connector 7. The coaxial connector 7 can be screwed to a counterpart of a coaxial socket (not shown) and an electrical connection to the one connected to the inner conductor connection 13 Antenna rod 1 can be produced.

2 shows a partial longitudinal section through the foot part 5.

The antenna rod 1 is electrically conductive at the end 15 of a rod-shaped Inner conductor 17 attached to a coaxial line, their tubular Outer conductor 19 at its end facing away from antenna rod 1 in one piece in the outer conductor connection 9 passes. The end of the inner conductor 17 facing away from the antenna rod 1 forms the Inner conductor connection 13. Between the outer conductor 19 and the inner conductor 17 is a Arranged insulating sleeve 21, which extends over the outer conductor 19 and the connection point of the antenna rod 1 with the inner conductor 17 is supported. The antenna rod 1 is as it was before Will be explained in more detail below, covered with a shrink tube 23, the through a front opening in the insulating sleeve that is adapted to its diameter 21 occurs and seals the opening against the ingress of moisture.

Fig. 3 shows the structure of the flexible antenna rod 1. The antenna rod 1 consists essentially of a helical spring 27 with one against the other under spring pressure Turns. The inner diameter of the helical spring 27 is in the order of magnitude of the spring wire diameter. The coil spring 27 thus acts as a tension spring and can due to their, compared to the inner diameter of cylindrical spiral springs in the foot part of known rod antennas very small inside diameter by almost any Angle are deflected from their rest position. The coil spring 27 can e.g. Bend into a circle without being permanently deformed. Will the antenna rod 1 is deflected from its rest position, the turns of the helical spring 27 on one side they are set apart from each other, but remain on the opposite side Side placed next to each other. After the deflection force ceases, the helical spring springs 27 back to the starting position in which the windings are against each other on all sides issue.

So that the antenna rod 1 also when deflected from the rest position electrical length is maintained in the in Fig. 5 shown Embodiment of the antenna rod 1 beginning and end of the coil spring 27 via a in the interior of the helical spring 27 guided, flexible short-circuit conductor 29 with each other tied together. The short-circuit conductor 29 is at the cap-side end 31 of the helical spring 27 soldered on. The short-circuit conductor is at the end of the helical spring 27 on the foot part 29 out on the outside of the helical spring 27 and together with the helical spring 27 pressed into a central end bore 33 of the inner conductor 17. The coil spring 27 and the short-circuit conductor 29 are also on an end collar 35 of the inner conductor 17 soldered on. The free length of the short-circuit conductor 29 is somewhat selected longer than the total length of the unloaded helical spring 27 to the deflection the coil spring 27 not to hinder.

Spring steel wire (e.g. type C, W. Nr. 1.1200 Din 17 223/1) or heat treatable beryllium bronze wire as usable proven. The inner diameter of the helical spring 27 is preferably the two up to ten times the wire diameter. In one embodiment the rod antenna resulted With a total length of the helical spring 27 of approx. 500 mm, the spring dimensioning is: Spring inner diameter 1.2 mm, diameter of the spring wire o, 6 mm free length of the Short-circuit conductor 29 (copper braid) 1.03 times the spring length.

Such a helical spring allows a deflection of 2 times 3600, without the antenna rod 1 being permanently deformed and is therefore also sufficient Practical requirements.

The helical spring 27 is provided with a shrink tube for protection against corrosion 37 made of a plastic based on polyolefin (e.g. "Thermofit" RT 102) coated. This coating can be chosen in matt black color, if, how e.g. in the case of military communications equipment, glare-free is required.

The cap 3 may be made of an ultraviolet ray resistant Synthetic rubber (e.g. "Buna" or "Neoprene").

Fig. 4 shows another embodiment of the rod antenna.

Parts of this rod antenna, according to structure, function and mode of operation correspond to the parts of the embodiment described with reference to FIGS. 1 to 7, are denoted by the same reference numerals. For an explanation, reference is made to the referenced description above.

The embodiment according to FIG. 4 differs from that above embodiment described essentially in that in series with the inner conductor 17 at a point located within the outer conductor 19 is a coil designed as a coil Transformation element 39 is connected. The transformation element 39 is used for the extension the electrical length of the rod antenna. The coaxial structure of the at points 41 and 43 to the inner conductor 17 or its extension as an inner conductor connection 13 connected transformation element 39 improves its electrical properties.

Fig. 4 also shows the structure of the coaxial connector 7 as it can also be used for the embodiment according to FIGS. The outer conductor 19 is in the area of the coaxial connector 7 in one piece with the outer conductor connection 9 expanded. A substantially seated on an annular shoulder 45 formed in this way disk-shaped insulating body 47 with a disk surface. The other end of the Outer conductor 19 is held by an annular shoulder 49 of insulating sleeve 21. In the Insulating body 47, the inner conductor connection 15 is pressed in or cast. being The end protruding into the outer conductor 19 is provided with a thread 51 and screwed into the insulating sleeve 21. Is the distance between the insulator 47 and the ring shoulder 49 chosen to be greater than the length of the outer conductor 19 between the ring shoulder 45 and the free end face of the outer conductor 19 and is the inner diameter of the outer conductor 19 selected to be larger than the outer diameter of the insulating sleeve 21, so the outer conductor connection 9 provided with the internal thread 11 can be used when connecting the rod antenna can be rotated freely to the counterpart of the coaxial connector 7.

When assembling the rod antenna, the outer conductor 19 and then the insulating sleeve 21 from the end of the antenna rod 1 on the cap side the inner conductor 17 or the transformation member 39 pushed and the insulating sleeve 21 screwed to the inner conductor connection 13. Appropriately when assembling the opening 25, the inner conductor 17 and the thread 51 wetted with adhesive to on the one hand, the penetration of moisture into the area of the transformation link 39 and, on the other hand, to avoid loosening of the thread 51 during operation.

Claims (10)

Claims Flexible rod antenna, in particular for portable communication devices or the like, the antenna rod of which is held in a base part as a helical spring is carried out, characterized in that the helical spring (27) is wound adjacent and has turns elastically pressed against one another. 2. Flexible rod antenna according to claim 1, characterized in that that the inner diameter of the helical spring (27) is in the order of magnitude of the wire diameter the helical spring (27) is preferably between 2 and 10 times the wire diameter is chosen. 3. Flexible rod antenna according to one of claims 1 or 2, characterized characterized in that the helical spring (27) over its entire length by an im Electrical short-circuit conductor (29) arranged inside the helical spring (27) is short-circuited. 4. Flexible rod antenna according to one of claims 1 or 2, characterized characterized in that the helical spring (27) with a matt black shrink tube (57) is coated from a plastic based on poliolefin. 5. Flexible rod antenna, in particular according to one of the preceding Claims, characterized in that the foot part (5) is designed as a coaxial line is whose outer conductor (19) on its end face facing away from the antenna rod (1) one as an outer conductor connection (9) of a coaxial connector (7) serving union holder, preferably a union nut, carries and its inner conductor (17) carries the antenna rod (1) at one end and as an inner conductor connection at the other end (13) of the coaxial connector (7) is formed and that between the inner conductor (17) and the outer conductor (19) an insulating sleeve (21) is arranged. 6. Flexible rod antenna according to claim 5, characterized in that the inner conductor (17) and / or the outer conductor (19) in or on the insulating sleeve (21) are screwed and / or glued. 7. Flexible rod antenna according to claim 6, characterized in that one end of the insulating sleeve (21) over the one facing the antenna rod (1) The end face of the outer conductor (19) engages and an internal thread at its other end carries into which the inner conductor (17) can be screwed and that between the cap holder and the end of the inner conductor (17) designed as an inner conductor connection (13) on the inner conductor (17) attached insulating body (47) is provided, which with his the antenna rod (1) facing end face on an annular shoulder (45) of the outer conductor (19) is based. 8. Flexible rod antenna according to claim 7, characterized in that the cap holder is formed in one piece with the outer conductor (19) and the The inner diameter of the union holder to form the ring shoulder (45) is larger is chosen as the inner diameter of the outer conductor (19). 9. Flexible rod antenna according to one of claims 5 to 8, characterized characterized in that in series with one located within the outer conductor (19) A transformation element (39) is connected to part of the inner conductor (17). 10. Flexible rod antenna according to claim 9, characterized in that that a coil is connected to an interruption in the inner conductor (17) or the inner conductor (17) is formed spirally.