DE19809668A1 - Directional radio - Google Patents

Description

State of the art

The invention is based on the genus, as in independent claim 1 specified.

Short-range directional radio devices are very often built in an integrated version ( FIG. 1). The device is located directly on the antenna and is firmly connected to it.

Two things must be guaranteed:

• 1. Good electrical contact on the Waveguide interface to ensure good electrical matching, little interference and little loss of profit to reach.
• 2. Good mechanical contact, so that attacking loads (Snow / ice, wind, weight ...) safely over the Bracket can be derived.

Now that the two contact levels of device and antenna including pathogens are not identical lies here a mechanical overdetermination.  

Usually this problem is mechanical Overdetermination solved in that the dimensions which the Determine electrical contact level, provide oversize to be sure to make electrical contact guarantee. It is accepted that either the mechanical connection was not clearly defined Has contact relationships or that there is a permanent deformation at the weakest point of the Contact level is coming.

Advantages of the invention

The subject of the application with the features of claim 1 has the following advantage:
Both good electrical and mechanical contact are made without the disadvantages mentioned above.

Advantageous further developments are in the dependent Claims specified, the characteristics of which, to the extent useful, can be combined with each other.

drawing

An embodiment of the invention is in the drawing shown and explained in more detail below. Are there the same reference numerals for several figures essentially the same parts are used. Is schematic shown in

Fig. 1, a radio relay device for short-distance,

Fig. 2 is a detail of FIG. 1 in an exploded view,

Fig. 3 the same section in the assembled state.

Description of the embodiment Structure of the preferred embodiment

The directional radio shown in Fig. 1 has a housing 1 and an integrated directional antenna, which consists of a reflector 2 and an exciter 3 , which is mechanically rigid and electrically connected to a waveguide 4 , which, like the reflector 2, rigid with the housing 1 is connected. In front of the reflector 2 there is a cover 5 for protection against snow and ice.

As FIG. 2 shows, an adapter plate 6 is rigidly attached to the housing 1 , to which a part 7 is rigidly attached during assembly (cf. FIG. 3), which in turn is rigidly connected to the reflector 2 of the directional antenna. The waveguide 4 rigidly arranged in the housing 1 is mechanically rigid and electrically connected to a waveguide 8 which leads to the exciter 3 . A flange 9 is attached to the waveguide 8 . Between this and the part 7 , a spring element 10 is provided in the form of a metallic spring ring.

When assembling (compare FIG. 3), two mechanical contact planes 11 and one electrical (and mechanical) contact plane 12 now result.

Function of the preferred embodiment

In the assembled state, an axially aligned guide surface 13 , which is rigidly connected to the exciter, ensures a defined axial guidance and centering in a suitable recess of part 7 at flange 9 . At the same time, the prestressing of the spring element 10 achieves good electrical contact between the flange 9 and the part 7 and thus with the reflector 2 , with good mechanical contact at the same time. The contact pressure of this waveguide interface can be set via the spring force of the spring ring 10 . The geometry of the parts involved is designed so that the exciter 3 is in its target position in relation to the reflector (parabolic mirror) while the spring travel f of the spring ring has not yet reached its maximum. The manufacturing tolerances that occur are now compensated for by a slight displacement of the exciter 3 relative to the reflector 2 , the electrical contact being retained by the spring ring 10 . The sum of the mechanical tolerances must not exceed the position tolerance of the pathogen, based on the parabolic mirror.

Claims (4)

1. directional radio with housing ( 1 ) and integrated directional antenna, which consists of a reflector ( 2 ) and an exciter ( 3 ), which is mechanically rigid and electrically connected to a waveguide ( 8 ), which, like the reflector ( 2 ), is indirect is rigidly connected to the housing ( 1 ), characterized in that
that the waveguide ( 8 ) is guided axially in at least one part ( 7 ) which is directly or indirectly rigidly connected to the reflector ( 2 ), and
that a flange ( 9 ), which is provided on the waveguide ( 8 ), is axially supported on one side via a spring element ( 10 ) against a part ( 7 ) which is directly or indirectly rigidly connected to the housing ( 1 ). 2. Directional radio according to claim 1, characterized in that the spring element ( 10 ) establishes an electrical connection. 3. Directional radio device according to claim 2, characterized in that the spring element ( 10 ) is a spring ring. 4. Directional radio according to one of the preceding claims, characterized in that the forces of the spring element ( 10 ) on the exciter ( 3 ) facing side of the flange ( 9 ) are directed.