WO1982001278A1

WO1982001278A1 - Protecting envelope for radio installations,particularly antennas

Info

Publication number: WO1982001278A1
Application number: PCT/DE1981/000167
Authority: WO
Inventors: & H Montage Gmbh G
Original assignee: Goebel A; Patschke H
Priority date: 1980-10-06
Filing date: 1981-10-06
Publication date: 1982-04-15
Also published as: EP0049523A1; ATE24795T1; DE3037726A1; EP0049523B1; DE3175823D1

Abstract

A protecting envelope for radio installations, such as antennas, is comprised of prefabricated construction elements, placed side by side so as to surround the antenna. When the presence of transporting machines with metal structures such as cranes is prohibited, a direct attachment to the envelope, which is made of a hard alveolar material, such as polyurethane, must be provided. To this effect, anchoring parts (5) made of a material poorly susceptible to influence electromagnetic waves, for example a synthetic material reinforced with fiber glass are embedded in certain elements (4c). To those anchoring parts (5) load supports (6, 7) may be attached which, as with travelling bridges (8), are also made of a synthetic material influencing only a little the transmitted waves. Although they are fixed only in the alveolar material of the elements (4c), the anchoring parts (5) may support considerably high loads.

Description

Cladding to protect radio systems, especially antennas

The invention relates to a cladding consisting of at least one facade element for protecting radio technical systems, according to the preamble of claim 1.

Such claddings, which are generally constructed from a large number of facade elements, are fundamentally known from DE-PS 12 73 023. For further details, reference is made to the older German patent applications P 29 51 590.0 and P 30 24 505.7. The main advantage of such claddings made of rigid foam is that the cladding fertilizer has a very low high-frequency insertion loss, usually below 1 dB, but nevertheless has such a mechanical strength that a self-supporting construction of the cladding is possible, the high-frequency losses Avoid steel reinforcements, for example. Larger cladding can be built from prefabricated facade elements of high homogeneity. In this way, in addition to outer wall-like claddings, tower-like claddings in the form of cylinders surrounding slim antenna masts or of self-supporting domes can also be created.

Particularly in the case of tower-like cladding, for example in the form of domes, however, there is often the need to use the cladding as a supporting wall for antenna holders, crane mounts and other auxiliary devices, since other structures for supporting are not next to or above the antenna due to the cantilevered design of the cladding be available. As far as places in the radio shadow of the

Acting antennas, such a support on support structures made of steel or the like. without any problems, but this would be too significant in the area of radiation High frequency losses and interference. Where this was necessary, therefore, such metal support structures have been installed so that they can be moved to support a crane shark during repair work in the desired work area, but during the operation of the antenna it can be placed in the radiation shadow. However, this is not always possible, since, for example, all-round antennas do not allow such a place for trouble-free parking, and in addition, such movable support structures are expensive, prone to failure and prone to malfunction and relatively cumbersome and time-consuming to operate.

In contrast, the invention has for its object to provide a cladding of the type outlined in the preamble of claim 1, on which heavy components or constructions such as lifting equipment can also be supported in the radiation area of the antenna, without this leading to a disturbing increase in high-frequency losses .

This object is achieved by the characterizing features of claim 1.

The fact that support parts are foamed from low-damping material results in only a slight change in the dielectric properties at the location of the support reinforcements, which, particularly as a result of the local limitation, does not noticeably disrupt the radiation entering or leaving through the cladding. Loads can be permanently or temporarily attached to such support parts. Glass fiber reinforced plastic or hard rubber is particularly suitable as the material for the support parts. In the case of permanent attachment of loads such as crane rails in the radiation area of the antenna, these loads can also be attenuated against electromagnetic waves poor material are executed so that they also do not noticeably interfere with the incoming and outgoing radiation.

If the support parts do not protrude beyond the surfaces of the facade elements, i.e. are covered on both sides by the undisturbed cladding surface or are flush with it, there is no additional effort in production, since then facade elements can be sprayed with support parts in the same shape as facade elements of the same shape without Support parts, only in the former case the support parts being arranged in the form of cores in the molding space and then foamed. It is also possible to use facade elements of a certain design throughout

To provide support parts, which can then be provided on the structure selectively, for example by making a hole with fittings for fastening the load or the like.

Further details, features and advantages of the invention result from the following description of an embodiment with reference to the drawing.

It shows

Fig. 1 is a vertical section through a dome-shaped panel together with an extracted, enlarged detail, and Fig. 2 shows the detail from circle II in Fig. 1 in a larger view.

As the drawing illustrates, the overall designation 1 is supported on a floor-side structure 2, for example in the form of a steel substructure. In the example, the cladding I consists of three rows 3a, 3b and 3c of facade elements 4a, 4b and 4c which are placed next to one another and connected to one another at the butt joints and which are in each of the layers in Ebe NEN superimposed rows 3a, 3b and 3c have different, adapted to the respective height of the spherical dome.

The facade elements 4c hit by the cut in the upper part of the dome, in the upper row 3c, have foamed-in support parts 5 made of material which is low in damping against electromagnetic waves, but which has relatively high mechanical strength. The support parts 5 can be designed, for example, as GRP profiles or hard rubber parts which, although they have a lower permeability to electromagnetic waves than the rigid foam, in particular PUR rigid foam of the cladding 1, have little or no radiation compared to steel parts or the like then only interfere locally.

The facade elements 4a, 4b and 4c are prefabricated in the injection molds and assembled at the construction site. If, as can be seen in particular from FIG. 2, the support parts 5 lie within the undisturbed outline of the respective facade element, they can simply be introduced into the mold and overmolded, so that there is practically no complication of the manufacturing process and compared to conventional ones

Façade elements 4a, 4b and 4c without support parts 5 no disturbances in stacking, assembly, etc. occur.

In the example, a fitting 6 for fastening a running rail for an outer conductor is fastened to the outside of the supporting parts 5, while fittings 7 are fastened to the inside of the dome on the supporting parts 5, to which a running rail 8 for the trolley 9 of a crane is attached. The running rail 8 can be made of glass fiber reinforced plastic and so also only interfere with the radiation very slightly. The trolley 9 can during operation of the antenna, not shown, working in the interior of the dome be moved to a location where there is minimal or no interference with the electromagnetic waves. In the example, the trolley 9 can be moved under a ventilation hood 10 arranged in the apex of the dome, which lies in the radio shadow or results in an accentuated fault location anyway.

Alternatively, the trolley 9 or another load on the support parts 5 can be removed during operation of the antenna, if there is otherwise an unacceptable one

Radio wave interference would result. Likewise, all or a greater number of facade elements 4a, 4b, 4c in all rows 3a, 3b and 3c or selectively only in rows that are suitable for attaching loads can be provided with support parts 5 as standard, which then also for retrofitting or the like. are always available and can be provided with a hole for fittings 6 or 7 also made of glass fiber reinforced plastic or a similar, low-damping material.

The support part 5 shown has a cable part 13 and flange parts 11, which have openings 12 to improve the positive locking, which are penetrated by the rigid foam. The hub part 13 is thickened and has a threaded bore 14 for screwing in threaded attachments 15 and 16 of the fittings 6 and 7. These in turn have screw holes 17 and 18 for fixing the running rail 8 and the outer conductor. or the like. Washers 19 and 20 of adjusted thickness ensure that the fittings 5 and 7 are screwed in at an angle.

It has surprisingly been found that the load-bearing capacity of such support parts 5, for example in the form of GRP profiles, is extraordinarily high, although they are only supported in the rigid foam, which has a density of more than 200 kp / m ³ . The in Fig. 1st illustrated guide rail 8 tem from glasfaserverstärk _¬ plastic, for example, has a speed of 2.5 Viable _¬ t.

Claims

1. From at least one facade element existing cladding for the protection of radio systems, in particular antennas, against weather conditions, the shell-forming facade elements being supported against a supporting structure and made of rigid foam, in particular based on polyurethane, characterized in that in at least one the facade elements (4c) support parts (5) are foamed from a low-damping material against electromagnetic waves.

2. Cladding according to claim 1, characterized in that the supporting parts (5) consist of glass-glass reinforced plastic or hard rubber.

3. Cladding according to claim 1 or 2, characterized in that the support parts (5) do not protrude beyond the undisturbed outline of the facade element (4c).

4. Cladding according to one of claims 1 to 3, characterized in that the payload supported on the support parts (5) (running rail 8) consists of a low-damping material against electromagnetic waves, such as glass fiber reinforced plastic.

5. Cladding according to one of claims 1 to 4, characterized in that on the support parts (5) attached fittings (6, 7) for storing the payload (track 8) made of a low-damping material against electromagnetic waves, in particular glass fiber reinforced plastic.