EP0040674A1 - Whip antenna - Google Patents

Abstract

The whip antenna has a plastic rod (1) held at the end on a foot (3). The rod (1) is reinforced essentially over its complete length, at least on its outer surface, with carbon fibres, embedded in the plastic, running approximately parallel to one another. The carbon fibres replace the metal wire normally embedded in such an antenna and can be made contact with without any problems since they are easily accessible at the surface. The antenna is preferably for use at frequencies of more than 70 MHz, in particular at more than 150 MHz. <IMAGE>

Description

The invention relates to a rod antenna with a rod held at the end on a foot made of fiber-reinforced plastic.

Motor vehicle rod antennas are said to be relatively stiff in order to keep bending caused by the wind and vibrations when cornering to a minimum.

Known rod antennas that meet these requirements consist of glass fiber reinforced plastic, in which a copper strand is inserted. The copper wire has the function of an antenna conductor, since glass-fiber reinforced plastic does not conduct electricity. The copper braid must be arranged as centrally as possible in the glass fiber reinforced plastic rod so that the rod can be subsequently shaped. The glass fiber reinforced plastic rod of the rod is usually made endless. In order to be able to connect the copper wire in the rod, it must be subsequently exposed at the foot end.

The object of the invention is to provide a rod antenna with a plastic rod that can be contacted in a simpler manner than conventional rod antennas this type.

This object is achieved in that the rod is reinforced over substantially its entire length, at least on its outer surface, with carbon threads embedded approximately parallel to one another in the plastic. The carbon threads not only reinforce the rod mechanically, but also form the electrically active conductor of the rod antenna. Such a rod can be contacted on its surface, which is possible in a relatively simple manner, for example with the aid of a sleeve or the like.

Surprisingly, it has been shown that the electrical properties of such a rod are not inferior to the electrical properties of conventional antennas with a metal conductor. Despite the embedding in plastic, the individual carbon threads can touch, which usually leads to galvanic conductivity. But even if the carbon filaments are more or less well insulated from one another, the capacitive coupling between the filaments that are not in direct contact with one another is sufficient at frequencies of more than 7o MHz, in particular more than 15o MHz, in order to ensure adequate HF conductivity guarantee.

Another advantage of the rod explained above is its black color, which corresponds to the modern color trend. The rod therefore does not have to be retrofitted, as was previously the case.

Furthermore, the rod is mechanically extremely strong and light, so that it tends very little to undesirable mechanical vibrations.

From the point of view of broadband, the rod antenna also offers advantages over conventional rod antennas with a glass fiber reinforced plastic rod. Rod antennas become wider, the smaller their slenderness is, i. H. the thicker the rod is in relation to its length. Rods made of carbon fiber reinforced plastics have a greater electrically effective thickness than conventional glass fiber reinforced rods, the electrically effective conductor of which consists only of a relatively thin strand inside the rod.

At least part of the carbon threads should extend the entire length of the rod. Rods of this type can be produced from continuous carbon filaments in continuous manufacturing processes. In this way, consistent electrical properties of the rod can be achieved over its entire length.

The rod should be tapered towards the free end, on the one hand to reduce its weight and on the other hand to reduce its area exposed to the wind. The shape can easily be achieved by conically grinding the carbon-thread-reinforced outer surface of the rod.

The easiest way to make the rod is to use carbon-fiber reinforced plastic. To reduce costs, however, it can also have a core made of glass fiber reinforced plastic and can be coated with a layer of carbon fiber reinforced plastic.

In order to obtain favorable electrical properties, the carbon content in the regions of the rod reinforced with carbon threads should be at least 50% by weight of the Total weight of these areas.

• Fig. 1 eine teilweise geschnittene Seitenansicht einer Kraftfahrzeug-Stabantenne für ein transportables Sende- und Empfangsgerät;
• Fig. 2 einen Querschnitt durch die Rute der Stabantenne nach Fig. 1 und
• Fig. 3 und 4 Querschnitte durch andere Ausführungsformen von Ruten.

Exemplary embodiments of the invention are to be explained in more detail below with reference to drawings: It shows:

• Figure 1 is a partially sectioned side view of a motor vehicle rod antenna for a portable transmitter and receiver.
• Fig. 2 shows a cross section through the rod of the rod antenna according to Fig. 1 and
• 3 and 4 cross sections through other embodiments of rods.

The rod antenna shown in FIG. 1 comprises a rod 1 which tapers conically towards its free end and is held on a fastening foot 3 at its larger diameter end. The rod 1, as shown in FIG. 2, has a full cross-section and consists of carbon threads which are embedded in plastic parallel to one another and reinforce it. At the foot end, a cap 5 surrounds rod 1 and contacts the carbon threads exposed to the surface. A coaxial inner conductor 7, for example a coaxial plug connection, is connected to the cap 5. An insulating molded part 9 encloses the cap 5 and carries a coaxial outer conductor part 11, which is not shown as a fastening element.

Although the carbon threads of the rod 1 are partially insulated from one another by the plastic in which they are embedded, the conduction properties are due to the capacitive coupling of the electrically conductors the carbon thread is good with each other if the antenna is operated at frequencies of at least 70 MHz. The capacitive coupling between the carbon threads is particularly important when the carbon threads near the surface do not extend over the entire length of the rod 1; as is to be expected due to the conical shape of the rod 1 according to FIG. 1.

An electrically conductive connection of the foot-side En. of the rod with a connecting part, for example the cap 5, can be produced by gluing with an electrically conductive adhesive.

Fig. 3 shows the cross section through another embodiment of the rod of a rod antenna. This rod comprises a cylindrical core 13 made of glass fiber reinforced plastic, which is surrounded by a jacket 15 made of carbon fiber reinforced plastic. The jacket 15 is chosen so thick that it is not looped through even when conically grinding the rod.

Fig. 4 shows the cross section of another embodiment of a rod 17, which is also made entirely of carbon fiber reinforced plastic, but is designed as a tube to save costs and weight.

Claims (6)

1. rod antenna with a rod held on one end of a foot made of fiber-reinforced plastic, characterized in that the rod (1; 13, 15; 17) essentially over its entire length at least on its outer surface with carbon embedded in the plastic approximately parallel to one another Threads is reinforced. 2. Rod antenna according to claim 1, characterized in that at least some of the carbon threads extend over the entire length of the rod (1; 13, 15; 17). 3. rod antenna according to claim 2, characterized in that the rod (1; 13, 15; 17) is ground conically towards the free end. 4. rod antenna according to claim 1, characterized in that the rod (1; 17) consists entirely of carbon fiber reinforced plastic. 5. rod antenna according to claim 1, characterized in that the rod has a core (13) made of glass fiber reinforced plastic and is coated with a layer (15) of carbon fiber reinforced plastic. 6. Rod antenna according to claim 1, characterized in that in the areas of the rod (1; 13, 15; 17) reinforced with carbon filaments, the carbon content is at least 50% by weight of the total weight of these areas.

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