DE20311442U1 - Radio antenna installation radome has individual unidirectional fibreglass curved panels with matching edges - Google Patents

Abstract

A radio antenna installation radome covering has individual panels (4) in unidirectional glass fibre reinforce plastic with edges at a common level and protruding double paraboloidal curvature arranged with matching corner pieces mounted to unidirectional fibreglass supports (1) with metal feet in mounting shoes (3).

Description

Dr. Horn Patent Attorney European Patent Attorney European Trademark Attorney

Gbm 37/03 ·) · ; . · · .·* . · · ·[ July 24, 2003

Description

Cladding element with improved electromagnetic properties for cladding of antennas and antenna systems

The present invention relates to the technical field of antenna cladding in connection with that of materials for components of antenna claddings which are not directly mechanically combined with the radiating elements and in this respect relates to a cladding made of a plastic material with special properties suitable for radio and high-frequency technology for an antenna or a collection of antennas (antenna system or antenna location).

DE 201 11 727.4 discloses small-volume cladding for radio relay and mobile radio antenna systems made of plastics with fiber reinforcement and a predominantly non-directional fiber structure. No optimization was made in terms of shape and material thickness. In some cases, these claddings are also used as advertising media.
DE 203 01 609.2 has made known a material which, due to its good electromagnetic properties, makes it possible to use it as a cladding material in combination with structural systems, in particular parts of buildings.

Both disclosures cannot offer a solution for optimized attenuation at high penetration angles.
Such a finding has not been reported in the relevant literature either.

However, it is known that the cladding of antenna sites for HF applications, e.g. for mobile communications, is often made of fiber-reinforced plastics. In the construction of sites, the fiber-reinforced plastic components are sometimes made as large-area plates, which are made as thick compact material or as a sandwich arrangement in order to achieve the necessary strength and rigidity. However, this has significant adverse effects on the electromagnetic

·

D:\Kanzlei Z\MUGLER\GJm 0J75)3\Gbm 037ip5B.(tjc J . ··· ···· ···· ·· ■

Dr. Horn Patent Attorney European Patent Attorney European Trademark Attorney

Gbm 37/03 ·" · ·.···* · · ·* July 24, 2003

Properties of the component to be irradiated, including the material. A key property for mobile communications is the attenuation of electromagnetic waves. This is caused by absorption in the material and reflection on the surface of the component. Absorption depends on the thickness of the material and is therefore high for the thick fiber-reinforced plastic components used. The proportion of reflection in the attenuation is strongly influenced by the angle of penetration α, i.e. the angle between the material surface normal (= surface normal) and the main beam direction of the electromagnetic waves, and their wavelength. With the materials and components used to date, a strong increase in attenuation can be seen at larger angles of penetration. Interference of the reflection components, especially when using sandwich components, causes a strong change in attenuation as a function of the angle of penetration and the wavelength. The most suitable shape of a component can therefore only be achieved for a certain angle of penetration with a certain associated wavelength. The use of antennas with a large opening angle is only possible to a limited extent.

Based on this state of the art and its deficiencies, the invention is based on the further development of the above-mentioned DE 201 11 727.4 and DE 203 01 609.2 and is based on the task of creating plate-shaped cladding elements made of fiber-reinforced plastic for an antenna cladding consisting essentially of these cladding elements. These cladding elements should have such good radio properties, such as particularly low attenuation, that they can be used without restrictions or defects in a wide frequency range, namely for mobile radio frequencies as well as for radio frequency directional frequencies. These cladding elements should be usable without restrictions due to their shape and the structure of the laminate. The aim of the invention is therefore to meet the radio technical requirements of the cladding (from the point of view of radio technology) and the structural requirements from the point of view of the

D:\Law firm 2\MUGLER\GQm O57jp3\Gbm

Dr, Horn Patent Attorney European Patent Attorney European Trademark Attorney

Gbm 37/03 ·\ · · , · · .·' . · · ·| July 24, 2003

Structural statics (e.g. wind and dead load) and the design requirements in appearance (optics and structure).

According to the invention, this task and objective is achieved by the characterizing parts of claim 1. Further advantageous technical solutions emerge from claims 2 to 8.
The advantageous effects of this technical solution according to the invention arise in particular from the fact that the fiber-reinforced plastic cladding components, in particular TECRYL® cladding components, are thinner due to the shape and have improved mechanical strength than the cladding components previously possible with the state of the art, whereby the absorption component of the attenuation (transmission attenuation) is significantly reduced and the radio performance of the entire system is thereby significantly improved. The curved shape of the individual components enables a small transmission angle α [angle between the material surface normal (= surface normal) and the main beam direction of the electromagnetic waves] at every single point, i.e. at every single location of any antenna in the overall location, whereby the reflection attenuation of the electromagnetic waves associated with this angle is greatly reduced, e.g. by 50%. The smaller range of the transmission angle also means that the frequency dependence of the attenuation can be kept low. Likewise, the arrangement according to the invention keeps the scattered radiation in the rear space small or of a defined size and shape.

The invention will be explained in more detail in its spatial form using the following exemplary embodiment.

Figures 1 to 6 as well as 10 and 11 represent parts of the essential elements of the invention.

D:\Kanztei2\MUGLER\Gpm0f7i03\Gbm037jd5B.iJoo J . &Idigr; ! · · · · *..* .J,

Dr. Horn Patent Attorney European Patent Attorney European Trademark Attorney

Gbm 37/03 ·|· ;,; | ,·' , | · ·' July 24, 2003

Fig. 1 shows the overall arrangement of a large-scale arrangement according to the invention for covering antennas

Fig. 1a shows a single cladding panel in barrel-shell shape with cut on both sides (mirror)

Fig. 1aa shows a single cladding panel in barrel-shell shape with two-sided cut (mirror) with further design details

Fig. 1 b shows a single cladding panel in hipped roof-like design

Fig. 1c shows a single cladding panel with paraboloid arching in 2 planes

Fig. 2 shows a cladding panel with change in material thickness

Fig. 3 shows a cladding panel with different curvature radii

Fig. 4 a and 4 b show possible corner connections 20

Fig. 5 shows a possible connection of the individual plates

Fig. 6 shows the height difference compensation on the flanges

Fig. 10 shows the angle relationships on a possible flat plate and on a single plate according to the invention

Fig. 11 shows an arched design of the arrangement of the

individual elements.
30

D:\Office 2\MUGLER\Gj)mQp7503\Gbm 037^8.^00 J. J II · ·· ***,

Dr. Horn Patent Attorney European Patent Attorney European Trademark Attorney

Gbm 37/03 \ · · , J ·,·".· \ \ July 24, 2003

Example:

The invention is described as a typical variant from a number of possible alternatives.

The 3-dimensionally formed panel 4 is curved outwards and designed like a barrel shell with a side cut (mirror). The curvature of the panel 4 is designed with two different radii, a slightly smaller one for the inner surface and a slightly larger one for the outer surface, which creates different panel thicknesses as shown in Fig. 2, for example designated ä^ and d ₂ in Fig. 2. The curvature of the panel 4 is 10% of its width. This guarantees that the panel 4 causes a reduced reflection, and thus the reflection attenuation, of the radio waves by 50%. The arching is guided from the edges to a level that is the same for all panels 4, with a height offset of the thickness of a plate being provided at the edges that represent the connecting flange for joining or panel construction at the same level, Fig. 6. Furthermore, the panel 4 is provided to overlap, in that the upper panel side in each case has a projecting surface 5. Another alternative would be for the panels 4 to be designed in an arc shape according to Fig. 11, preferably running between the horizontal and the vertical, with the connecting flanges describing a curve, preferably forming a quarter circle, and thereby fulfilling the purpose of a self-supporting cladding consisting of several panels that functions without a support structure. The corner panel 6 is preferably designed with a radius as shown in Fig. 4 b, but can alternatively be designed so that, as shown in Fig. 4 a, both curved curves running into the corner are joined together in the corner (the penetration line) and connected seamlessly. Furthermore, the panels 4 can be designed so that they form permeable areas for radio fields. The fastening flanges as shown in Fig. 5 can be used to limit the radiation area.

D:\Law firm 2\MUGLER\G$m 0$7«03\Gbm 037 _Ä CßB.ioc J .

Claims (8)

1. Cladding element with improved electromagnetic properties for cladding of antennas and antenna systems, in particular for mobile radio and at the same time for directional radio antenna systems, characterized in that it is designed as a 3-dimensionally curved cladding plate in the form of panels ( 4 ) with a special shape, consisting of fiber-reinforced plastics. 2. Arrangement according to claim 1, characterized in that the 3-dimensionally shaped panels ( 4 ) are curved outwards and are designed in particular in the shape of a hipped roof, a barrel shell with a lateral cut (mirror), paraboloidally curved in 2 planes or in a combination of these shapes. 3. Arrangement according to claim 1, characterized in that for the purpose of reduced reflection of the radio waves, the panels ( 4 ) are curved so that a small angle of transmission α is thereby provided. 4. Arrangement according to claim 1, characterized in that the arching of the panels ( 4 ) amounts to 5 to 15% of their width and that the arching in the joint arrangement of the panels ( 4 ), starting from the edges, is guided to a level which is the same for all panels ( 4 ), wherein at the edges which represent the connecting flange, a height offset by the thickness of a plate is provided for level joining or panel construction. 5. Arrangement according to claim 1, characterized in that corner panels ( 6 ) are designed such that both curved curves running into the corner are joined together in the corner (the penetration line) and connected seamlessly or, alternatively, are designed such that they have a curvature with a defined radius. 6. Arrangement according to claim 1, characterized in that the curvatures of the inner and outer sides of the panels ( 4 ) are designed such that they each have a different radius, the radii of the curvatures to the edges of the panel ( 4 ) are changed in their courses or the panels ( 4 ) otherwise have different thicknesses d ₁ and d ₂ . 7. Arrangement according to claim 1, characterized in that the lateral regions of the panel ( 4 ) are designed such that they have a high attenuation and thus limit the propagation of the electromagnetic waves. 8. Arrangement according to claim 1, characterized in that the panels ( 4 ) are alternatively designed in an arc shape, preferably running between the horizontal and the vertical, wherein the connecting flanges describe a curve, preferably forming a quarter circle, and that the purpose of a self-supporting cladding consisting of several panels functioning without a support structure is thereby fulfilled.